Sodium dichloroisocyanurate powder production discharging device
By designing a feeding device for sodium dichloroisocyanurate powder production that includes a storage bin, a feeding bin, a receiving bin, and a screw conveyor, combined with a dispersing mechanism and an inclined chute, the problem of raw material bridging in powder production was solved, achieving continuous and accurate feeding, and improving production efficiency and product quality.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- XINXIANG KANGDA DISINFECTION JI CO LTD
- Filing Date
- 2025-07-21
- Publication Date
- 2026-07-03
Smart Images

Figure CN224449559U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the technical field of sodium dichloroisocyanurate powder production equipment, specifically to a feeding device for sodium dichloroisocyanurate powder production. Background Technology
[0002] Sodium dichloroisocyanurate powder is a white, crystalline organic compound with strong bactericidal properties. It is commonly used in water treatment, swimming pool disinfection, and industrial equipment disinfection. The raw materials required for the production of sodium dichloroisocyanurate mainly include cyanuric acid, hydrochloric acid, and sodium hydroxide. To facilitate production, a feeding device is used when feeding the powder raw materials to ensure that the amount of material fed each time is uniform and meets the requirements, thereby improving production efficiency.
[0003] During the storage of powder raw materials, mechanical compression caused by internal friction and the tendency of the powder to bulge due to its own viscosity can lead to discontinuous feeding. This not only affects production efficiency but also product quality. Utility Model Content
[0004] To address the shortcomings of existing technologies, this utility model provides a feeding device for sodium dichloroisocyanurate powder production, which solves the problem of easy material bridging during the feeding process of the powder used in the production of sodium dichloroisocyanurate powder.
[0005] To achieve the above objectives, this utility model provides the following technical solution: a feeding device for producing sodium dichloroisocyanurate powder, comprising a shell and a feeding mechanism. The shell has an interconnected storage bin, a feeding bin, and a receiving bin. A dispersing mechanism is provided at the bottom of the storage bin. A feeding bin, connected to the storage bin and the feeding bin, is provided between the storage bin and the feeding bin. A screw conveyor is provided in the feeding bin to transport the material to the inside of the feeding bin. The bottom of the receiving bin is connected to the discharge port. The feeding mechanism is located inside the receiving bin.
[0006] Furthermore, a chute inclined toward the feed inlet at the bottom of the storage bin is provided.
[0007] Furthermore, the dispersing mechanism includes a dispersing motor and a dispersing rod. The dispersing motor is installed on one side of the housing and its output shaft penetrates into the interior of the storage hopper. The dispersing rod is fixedly connected to the output shaft of the dispersing motor and is inclined to the axis of the dispersing motor.
[0008] In the above technical solution, the output shaft of the disintegrating motor is connected to the disintegrating rod via a mounting plate, the mounting plate is connected to the output shaft of the disintegrating motor, and the disintegrating rod is fixed to the mounting plate.
[0009] Furthermore, a drive motor is installed on the top of the housing, and the output shaft of the drive motor is connected to a drive shaft via a coupling. The end of the drive shaft away from the drive motor is fixedly connected to the upper surface of the rotating disk.
[0010] Furthermore, the drive shaft is provided with a drive wheel, and the top of the screw conveyor is provided with a driven wheel. The drive wheel is connected to the driven wheel via a synchronous belt.
[0011] Furthermore, the rotating disk is provided with mounting holes, and the receiving hopper is detachably installed inside the mounting holes, with the upper surface of the rotating disk fitting against the bottom of the unloading hopper.
[0012] Furthermore, the inner wall of the receiving bin is provided with a protrusion, which is used to lift the baffle at the bottom of the receiving bin.
[0013] Furthermore, a maintenance door is detachably provided on one side of the housing, and the back of the maintenance door communicates with the interior of the receiving hopper.
[0014] This utility model provides a feeding device for the production of sodium dichloroisocyanurate powder, which has the following beneficial effects:
[0015] 1. This utility model uses a dispersing mechanism to disperse the material in the storage bin, preventing material bridging during the production of sodium dichloroisocyanurate powder and avoiding the problem of discontinuous powder feeding caused by material bridging.
[0016] 2. The inclined chute at the bottom of the storage bin not only causes the material to flow toward the feed inlet of the feeding bin, but also causes the inclination angles on both sides of the bottom of the storage bin to be different, resulting in different material descent speeds on both sides. Due to the unbalanced forces, the material in the storage bin is less likely to accumulate and the phenomenon of material bridging is less likely to occur.
[0017] 3. This utility model, through the coordinated arrangement of a feeding hopper, a receiving hopper, and a screw conveyor, lifts the material into the feeding hopper during feeding. During the lifting process, the squeezing action of the screw conveyor and the feeding hopper disperses any materials that have clumped or agglomerated due to self-absorption, making the powder in the feeding hopper easier to feed, more accurate in quantitative feeding, reducing the content of clumps or agglomerated materials, and improving product quality. Attached Figure Description
[0018] Figure 1 This is a schematic diagram of the feeding device for producing sodium dichloroisocyanurate powder according to this utility model;
[0019] Figure 2 This is a schematic diagram of the rotating disc of the sodium dichloroisocyanurate powder production feeding device of this utility model.
[0020] In the diagram: 1. Shell; 2. Storage bin; 3. Discharge bin; 4. Receiving bin; 5. Screw conveyor; 6. Rotary disc; 7. Receiving bucket; 8. Baffle; 9. Discharge port; 10. Dispersing motor; 11. Dispersing rod; 14. Drive motor; 15. Drive shaft; 16. Drive wheel; 17. Driven wheel; 18. Mounting hole; 19. Protrusion; 20. Inspection door; 21. Feeding bin; 22. Mounting disc; 23. Conveyor plate. Detailed Implementation
[0021] The technical solutions of the present utility model will be clearly and completely described below with reference to the accompanying drawings of the embodiments. All other embodiments obtained by those skilled in the art based on the embodiments of the present utility model without creative effort are within the scope of protection of the present utility model.
[0022] Example: Figure 1 As shown, this utility model provides a feeding device for the production of sodium dichloroisocyanurate powder, including a shell 1 and a feeding mechanism. The shell 1 has a storage bin 2, a feeding bin 3, and a receiving bin 4 inside, which are interconnected. A feeding bin 21 is provided between the storage bin 2 and the feeding bin 3. The feeding bin 21 is vertically arranged with an inlet at its bottom and an outlet at its top, allowing it to communicate with both the storage bin and the feeding bin 3. The feeding bin 21 is equipped with a screw conveyor 5, which conveys the material to the interior of the feeding bin 3. The bottom of the feeding bin 3 communicates with the interior of the receiving bin 4, and the bottom of the receiving bin 4 communicates with the outlet 9. The outlet 9 is connected to the inlet of the reaction tank via a pipe. The feeding mechanism is located inside the receiving bin 4. In this embodiment, a dispersing mechanism disperses the material in the storage bin to prevent bridging, avoiding discontinuous feeding caused by bridging, improving production efficiency, and ensuring product quality.
[0023] In this embodiment, a chute 23 inclined toward the feed inlet of the bottom of the storage bin 2 is provided at the bottom of the storage bin 2. The chute 23 not only makes the material flow toward the feed inlet of the feed bin, but also makes the inclination angles of the two sides of the bottom of the storage bin different, so that the material on the two sides falls at different speeds. The material in the storage bin is not easy to accumulate due to the unbalanced force, and the phenomenon of material bridging is not easy to occur.
[0024] In this embodiment, the dispersing mechanism includes a dispersing motor 10 and a dispersing rod 11. The dispersing motor 10 is fixedly connected to one side of the housing 1, and its output shaft penetrates into the interior of the storage hopper 2. The dispersing rod 11 is fixedly connected to the output shaft of the dispersing motor 10, and the axis of the dispersing rod 11 is inclined to the axis of the dispersing motor 10. During operation, the dispersing motor 10 is turned on intermittently at regular intervals, causing the dispersing motor 10 to drive the dispersing rod 11 to agitate the material, preventing the material from accumulating. In this embodiment, the output shaft of the dispersing motor 10 is connected to the dispersing rod 11 through a mounting plate 22. The mounting plate 22 is keyed to the output shaft of the dispersing motor 10, and the dispersing rod 11 is fixed to the mounting plate 22. A bearing is provided between the output shaft of the dispersing motor 10 and the housing 1 to ensure the normal rotation of the output shaft of the dispersing motor 10.
[0025] The structure of the feeding mechanism in this embodiment is as follows: The feeding mechanism includes a rotating disk 6 and a receiving bin 7. The rotating disk 6 is located inside the receiving bin 4. The receiving bin 7 is detachably mounted on the rotating disk 6. A baffle 8 is hinged at the bottom opening of the receiving bin 7. A discharge port 9 is provided on one side of the housing 1. The discharge port 9 communicates with the interior of the receiving bin 4.
[0026] In use, the powder is added to the storage silo 2 and conveyed to the discharge silo 3 by the screw conveyor 5. From the discharge silo 3, it enters the receiving hopper 7 in the receiving silo 4. The rotating disc 6 drives the receiving hopper 7 to rotate together. When the receiving hopper 7 moves to the bottom of the discharge silo 3, the opening at the top of the receiving hopper 7 connects with the opening at the bottom of the discharge silo 3, and the material in the discharge silo 3 falls into the receiving hopper 7. The receiving disc continues to rotate. When the receiving hopper 7 moves to the top of the discharge port 9, the baffle 8 at the bottom of the receiving hopper 7 opens downward, allowing the powdery material in the receiving hopper 7 to be discharged from the discharge port 9. The receiving disc continues to rotate. When the receiving hopper 7 leaves the discharge port 9, the baffle 8 is pushed back into the receiving hopper 7 by the bottom wall of the receiving silo 4, sealing the bottom opening of the receiving hopper 7 to facilitate the next loading.
[0027] In this embodiment, a drive motor 14 is installed on the top of the housing 1. The output shaft of the drive motor 14 is connected to a drive shaft 15 via a coupling. The end of the drive shaft 15 away from the drive motor 14 is fixedly connected to the upper surface of the rotating disk 6. A drive wheel 16 is provided on the outer circular surface of the drive shaft 15. A driven wheel 17 is provided on the top of the screw conveyor 5. The drive wheel 16 is connected to the driven wheel 17 via a synchronous belt.
[0028] The drive motor 14 is connected to the drive shaft 15, which drives the rotating disk 6 to rotate. While the rotating disk 6 is rotating, the drive wheel 16 and the driven wheel 17 drive the screw conveyor 5 to rotate, lifting the material into the discharge bin 3.
[0029] In this embodiment, as Figure 2As shown, the rotating disk 6 has a mounting hole 18, and the receiving bucket 7 is detachably installed inside the mounting hole 18. The upper surface of the mounting hole 18 fits against the bottom of the unloading bin 3. The inner wall of the receiving bin 4 has a protrusion 19, which is used to lift the baffle 8 at the bottom of the receiving bucket 7. A maintenance door 20 is detachably installed on one side of the housing 1, and the back of the maintenance door 20 communicates with the interior of the receiving bin 4. Preferably, as a gas embodiment of the present invention (not shown), a spherical surface or roller is provided on the top surface of the protrusion 19 corresponding to the trajectory of the receiving bucket 7, thereby reducing the friction between it and the baffle 8.
[0030] The mounting hole 18 is countersunk, with the top of the receiving hopper 7 located inside the countersunk hole. The top of the receiving hopper 7 is flush with the top of the rotating disk 6, allowing materials to fall into the receiving hopper 7. After receiving the materials, the rotating disk 6 can seal the bottom of the discharge bin 3 during its rotation, preventing materials from falling further. When the receiving hopper 7 moves to the discharge port 9, the bottom baffle 8 opens due to gravity. After the discharge is complete, the receiving hopper 7 continues to rotate, and the baffle 8 pushes the baffle 8 back, sealing the bottom of the receiving hopper 7. After opening the inspection door 20, the components inside the receiving bin 4 can be repaired, and the receiving hopper 7 and rotating disk 6 can be replaced to adapt to different working conditions.
[0031] In other embodiments not shown in this utility model, multiple agitators are provided on the spiral blades of the spiral conveyor 5 to better break up clumps or agglomerates of materials, thereby improving product quality.
[0032] This invention uses a dispersing mechanism to agitate the material in the storage bin, preventing material clogging, ensuring continuous feeding, and improving production efficiency. Furthermore, the screw conveyor has a squeezing effect on the material in the feeding bin, which can disperse clumps of material and ensure product weight.
[0033] The specific embodiments provided by this utility model have been described in detail above. Specific examples have been used to illustrate the principles and implementation methods of this utility model. The description of the above embodiments is only for the purpose of helping to understand the method and core ideas of this utility model. At the same time, for those skilled in the art, there will be changes in the specific implementation methods and application scope based on the ideas of this utility model. Therefore, the content of this specification should not be construed as a limitation of this utility model.
Claims
1. A sodium dichloroisocyanurate powder production discharging device, comprising a shell (1) and a discharging mechanism, characterized in that: The shell (1) is provided with a storage bin (2), a discharge bin (3) and a receiving bin (4) that are interconnected. A dispersing mechanism is provided at the bottom of the storage bin (2). A feeding bin (21) is provided between the storage bin (2) and the discharge bin (3) and is connected to the storage bin (2) and the discharge bin (3). A screw conveyor (5) is provided in the feeding bin (21) to transport the material to the interior of the discharge bin (3). The bottom of the receiving bin (4) is connected to the discharge port (9). The discharge mechanism is located in the receiving bin (4).
2. The sodium dichloroisocyanurate powder discharging device according to claim 1, characterized in that: A chute (22) inclined toward the feed inlet at the bottom of the storage bin (2) is provided.
3. The sodium dichloroisocyanurate powder discharging device according to claim 1, characterized in that: The dispersing mechanism includes a dispersing motor (10) and a dispersing rod (11). The dispersing motor (10) is installed on the outside of the housing (1) and its output shaft passes through the inside of the storage bin (2) and is connected to the dispersing rod (11). The dispersing rod (11) is inclined to the axis of the dispersing motor (10).
4. The sodium dichloroisocyanurate powder discharging device according to claim 2, characterized in that: The output shaft of the dispersing motor (10) is connected to the dispersing rod (11) via the mounting plate (20). The mounting plate (20) is connected to the output shaft of the dispersing motor (10), and the dispersing rod (11) is fixed to the mounting plate (22).
5. The feeding device for producing sodium dichloroisocyanurate powder according to claim 1, characterized in that: The feeding mechanism includes a rotating disk (6) and a receiving bin (7). The receiving bin (7) is detachably mounted on the rotating disk (6). The upper surface of the rotating disk (6) is attached to the feeding bin (3) to block the outlet of the feeding bin (3). The bottom of the receiving bin (7) is provided with an opening, and a baffle (8) is hinged to its bottom to block the opening at the bottom of the receiving bin (7).
6. The sodium dichloroisocyanurate powder production feeding device according to claim 5, characterized in that: A drive motor (14) is installed on the top of the housing (1). The output shaft of the drive motor (14) is connected to a drive shaft (15). One end of the drive shaft (15) away from the drive motor (14) is fixedly connected to the rotating disk (6).
7. The sodium dichloroisocyanurate powder discharging device according to claim 6, characterized in that: The drive shaft (15) is provided with a drive wheel (16), and the top of the spiral conveyor (5) is provided with a driven wheel (17). The drive wheel (16) is connected to the driven wheel (17) by a synchronous belt.
8. The sodium dichloroisocyanurate powder discharging device according to claim 5, characterized in that: The rotating disk (6) is provided with a number of mounting holes (18) arranged around the circumference of the rotating disk, and the receiving bucket (7) is detachably installed inside the mounting holes (18).
9. The sodium dichloroisocyanurate powder discharging device according to claim 5, characterized in that: The receiving bin (4) is provided with a protrusion (19) so that when the receiving bin (7) rotates to the protrusion (19) driven by the rotating disk (6), the protrusion (19) pushes up the baffle (8) at the bottom of the receiving bin (7).
10. The sodium dichloroisocyanurate powder discharging device according to claim 1, characterized in that: A maintenance door (20) is provided on one side of the housing (1), and the maintenance door (20) is located at the corresponding position of the receiving bin (4).