Double-head quantitative filling device for toilet cleaner
By using a dual-head quantitative filling device for toilet cleaner with good synchronization, and driving the dual-head filling components with a single power source, the problems of low filling efficiency and filling volume deviation in traditional devices are solved, realizing batch and accurate filling of toilet cleaner and improving product consistency.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- HAINAN QIONGYANG DAILY CHEM CO LTD
- Filing Date
- 2025-12-08
- Publication Date
- 2026-06-19
AI Technical Summary
Traditional dual-head quantitative filling devices for toilet cleaners have low efficiency in single-head filling mode, and the dual-head filling heads are mostly driven independently, resulting in large deviations in filling volume and affecting product consistency.
The toilet cleaner uses a dual-head quantitative filling device with good synchronization. The dual-head filling components are driven by a single power source, and the screw and belt transmission system is used to realize the synchronous operation of the two filling heads to ensure consistent filling volume. A uniform feeding tank is used to avoid differences in feeding pressure.
It enables batch and precise filling of toilet cleaner, improving filling efficiency and product consistency, and meeting the needs of large-scale production.
Smart Images

Figure CN224377649U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of dual-head quantitative filling technology for toilet cleaner, specifically a dual-head quantitative filling device for toilet cleaner. Background Technology
[0002] As is well known, in industrial production, many factories use corresponding quantitative filling equipment for packaging to facilitate packaging work. This not only has high work efficiency, but also effectively reduces the burden on workers.
[0003] Traditional single-head filling devices are inefficient and cannot meet the needs of mass production. Existing dual-head devices often have two independently driven filling heads that lack a synchronization structure, resulting in a large deviation in the filling volume between the two filling heads and affecting product consistency. Utility Model Content
[0004] In order to overcome the problems of low efficiency in the single-head filling mode and the fact that the filling heads are mostly independently driven in the existing dual-head quantitative filling devices for toilet cleaner, this utility model provides a dual-head quantitative filling device for toilet cleaner with good synchronization and accurate quantitative filling.
[0005] To achieve the above objectives, this utility model provides the following technical solution: a dual-head quantitative filling device for toilet cleaner, comprising:
[0006] Base plate;
[0007] Support legs, which are fixedly installed around the bottom of the base plate;
[0008] A conveying assembly, the conveying assembly being mounted on top of the base plate; and
[0009] A dual-head filling assembly is installed on the top of the base plate. The dual-head filling assembly includes a bracket, which is fixedly disposed on both sides of the top of the base plate. A horizontal plate is fixedly disposed between the top of the bracket, and a carrying bucket is fixedly disposed on the top of the horizontal plate. Fillers are installed on both sides of the bottom of the carrying bucket.
[0010] Preferably, the top of the carrying bucket is provided with an inlet, and the bottom two sides of the carrying bucket are provided with outlets. An outlet pipe is fixedly provided on the outlet, and the outlet pipe is fixedly provided with the filling device.
[0011] Furthermore, the filling device includes a vertical tube, an input tube fixedly disposed on the side of the vertical tube, the other end of the input tube being fixedly disposed with the output tube, a circular plate fixedly disposed on the top of the vertical tube, a movable column fixedly disposed on the top of the circular plate, and the other end of the movable column passing through the top end of the vertical tube.
[0012] Furthermore, a connecting block is fixedly installed on the top of the movable column, a rotating rod is rotatably installed on the connecting block, a connecting column is fixedly installed between the rotating rods, and a rotating block is rotatably installed at the center of the connecting column.
[0013] In a further embodiment, a screw is rotatably mounted on the side of the horizontal plate, and a movable plate is threaded onto the screw. The bottom of the movable plate is fixedly mounted to the top of the rotating block.
[0014] Based on the aforementioned scheme, a first mounting plate is fixedly installed on the side of the bracket, a first motor is fixedly installed on the first mounting plate, a first pulley is fixedly installed on the output shaft of the first motor and one end of the screw, and a first transmission belt is provided between the first pulleys.
[0015] Furthermore, based on the aforementioned solution, the conveying assembly includes a mounting hole, which is opened on the top of the base plate. Rotating shafts are rotatably arranged on both sides of the mounting hole, and a conveyor belt is sleeved between the rotating shafts.
[0016] Furthermore, based on the aforementioned solution, a second mounting plate is fixedly installed on the side of the support leg, a second motor is fixedly installed on the second mounting plate, a second pulley is fixedly installed on the output shaft of the second motor and the rotating shaft on one side, and a second transmission belt is provided between the second pulleys for transmission.
[0017] Beneficial effects: This dual-head quantitative filling device for toilet cleaner uses a first motor on the side of the horizontal plate to drive a screw to rotate via a first pulley and a first transmission belt. The moving plate on the screw moves laterally with the thread, and a rotating block is connected to the bottom of the moving plate. The rotating block is linked with the connecting column, ultimately driving the moving columns of the two filling heads to rise and fall synchronously. It eliminates the need for two independent motors; a single power source can drive the synchronous movement of both heads, ensuring that the filling rhythm and dosage of the two filling heads are completely consistent. This solves the problems of inconsistent filling speed and dosage in traditional dual-head filling devices. The toilet cleaner raw material is connected to the input port at the top of the carrying tank, and the output ports on both sides at the bottom are connected to the input pipes of the two filling heads via output pipes. The raw material is diverted from the same carrying tank to both heads, avoiding dosage deviations caused by differences in supply pressure and further improving synchronization. Attached Figure Description
[0018] Figure 1 This is a side view of the structure of this utility model;
[0019] Figure 2 This is a schematic diagram of the structure of the dual-head filling assembly of this utility model;
[0020] Figure 3 This is a schematic diagram of the structure of the bearing bucket of this utility model;
[0021] Figure 4This is a schematic diagram of the filling device of this utility model;
[0022] Figure 5 This utility model Figure 2 A magnified schematic diagram of the structure at point A in the middle.
[0023] In the diagram: 1. Base plate; 2. Support leg; 3. Conveying assembly; 4. Double-headed filling assembly; 5. Bracket; 6. Horizontal plate; 7. Carrying bucket; 8. Filler; 9. Inlet; 10. Outlet; 11. Outlet pipe; 12. Vertical pipe; 13. Inlet pipe; 14. Circular plate; 15. Moving column; 16. Connecting block; 17. Rotating rod; 18. Connecting column; 19. Rotating block; 20. Screw; 21. Moving plate; 22. First mounting plate; 23. First motor; 24. First pulley; 25. First transmission belt; 26. Mounting hole; 27. Rotating shaft; 28. Conveyor belt; 29. Second mounting plate; 30. Second motor; 31. Second pulley; 32. Second transmission belt. Detailed Implementation
[0024] The technical solutions of the present utility model will be clearly and completely described below with reference to the accompanying drawings of the embodiments. Obviously, the described embodiments are only some embodiments of the present utility model, and not all embodiments. Based on the embodiments of the present utility model, all other embodiments obtained by those of ordinary skill in the art without creative effort are within the protection scope of the present utility model.
[0025] See Figures 1-5 A dual-head quantitative filling device for toilet cleaner is disclosed. A base plate 1 has fixed support legs 2 around its bottom for stability. A conveying component 3 and a dual-head filling component 4 are installed on the top. The conveying component 3 moves the bottles to be filled, working in conjunction with the dual-head filling component 4 to complete continuous filling. The dual-head filling component 4 is framed by a bracket 5 and a horizontal plate 6. A carrying tank 7 is fixed to the top of the horizontal plate 6, and filling devices 8 are installed on both sides of the bottom. The carrying tank 7 supplies material to both filling devices 8 uniformly, avoiding material discrepancies. A drive component drives a screw 20 to rotate via a single power source. The linkage structure allows the two filling devices 8 to operate synchronously, ensuring consistent filling dosage. Through synchronous filling and continuous conveying, the components work closely together to solve the problems of low efficiency in single-head and asynchronous operation in traditional devices, achieving batch and precise filling of toilet cleaner, ensuring product consistency, and meeting the needs of large-scale production.
[0026] First, refer to Figure 1In this embodiment, the base plate 1 is a horizontal plate structure, which is the installation base for the conveying component 3 and the double-headed filling component 4. The upper surface is flat to ensure that the position of each component is accurate after installation without tilting deviation. The top of the base plate 1 has a mounting hole 26 to provide installation space for the rotating shaft 27 of the conveying component 3. The side has a reserved bracket 5 fixing position so that the double-headed filling component 4 can be stably fixed above the base plate 1.
[0027] The support legs 2 are fixed around the bottom of the base plate 1, and are evenly distributed to support the base plate 1 off the ground. This not only prevents ground moisture or debris from affecting the bottom components of the device, but also reserves operating space for the transmission structure of the conveying component 3, preventing friction with the ground during transmission. The support legs 2 themselves are structurally stable, so even if the conveying component 3 and the filling component are running at the same time, the base plate 1 can remain stable, providing a stable foundation for subsequent synchronous filling and conveying.
[0028] Then, refer to Figure 3 In this embodiment, the conveying assembly 3 is installed on the top of the base plate 1 and is responsible for continuously conveying the bottles to be filled to the filling position. After filling, the bottles are conveyed to the next process. The assembly includes a rotating shaft 27, a conveyor belt 28 and a drive structure. The rotating shaft 27 is rotatably installed on both sides of the mounting hole 26 on the base plate 1. The conveyor belt 28 is fitted between the two rotating shafts 27 to form a circulating conveying channel. The bottles are placed on the conveyor belt 28 and move with the conveyor belt 28, passing under the two filling machines 8 in sequence to complete synchronous filling. There is no need for manual handling of the bottles, which improves the filling efficiency.
[0029] The second mounting plate 29 is fixed to the side of the support leg 2. The second motor 30 is mounted on the second mounting plate 29. The second pulley 31 is fixed on both the output shaft of the motor and the rotating shaft 27 on one side. A second transmission belt is sleeved between the two pulleys. When the second motor 30 is started, the motor drives the second pulley 31 on the output shaft to rotate. The second transmission belt drives the rotating shaft 27 to rotate, thereby driving the conveyor belt 28 to run in a cycle. The speed of the conveyor belt 28 can be controlled by adjusting the motor parameters to ensure that it matches the filling rhythm and avoids leakage or overflow caused by the bottles being conveyed too fast or too slow.
[0030] Secondly, see Figure 2 In this embodiment, the dual-head filling assembly 4 is installed on the top of the base plate 1 and includes a bracket 5, a horizontal plate 6, a carrying tank 7, a filling device 8, and a drive assembly. The components work together to achieve synchronous dual-head operation and quantitative filling. The bracket 5 is fixed on both sides of the top of the base plate 1 and is symmetrically distributed. The horizontal plate 6 is fixed between the tops to form a stable frame structure. The horizontal plate 6 provides an installation platform for the carrying tank 7 and also provides support for the drive assembly of the filling device 8, ensuring that the filling device 8 and the drive structure are accurately positioned and without deviation during linkage.
[0031] The carrying tank 7 is fixed to the top of the horizontal plate 6. An inlet 9 is opened at the top for receiving toilet cleaner raw materials. Outlet 10 is opened on both sides of the bottom. The outlet 10 is connected to the outlet pipe 11. The other end of the outlet pipe 11 is fixed to the inlet pipe 13 of the filling device 8. After the raw materials enter the carrying tank 7 from the inlet 9, they are evenly distributed to the two filling devices 8 through the outlet pipes 11 on both sides, so as to achieve the same source of material supply and avoid the pressure difference caused by two independent material supply sources. This ensures that the material supply of the two filling devices 8 is consistent from the source, laying the foundation for synchronous quantitative filling.
[0032] The filling device 8 includes a vertical tube 12, an input tube 13, a movable column 15, and a circular plate 14. The vertical tube 12 is fixed to the bottom of the horizontal plate 6. The input tube 13 on the side is connected to the output tube 11. The raw material enters the vertical tube 12 through the input tube 13. The circular plate 14 is slidably disposed inside the vertical tube 12. The movable column 15 is fixed at the top. The top of the movable column 15 passes through the top of the vertical tube 12. When the movable column 15 rises and falls, it drives the circular plate 14 to move up and down inside the vertical tube 12. When the circular plate 14 rises, the space inside the vertical tube 12 increases, and the raw material enters from the input tube 13. When the circular plate 14 falls, it squeezes the raw material inside the vertical tube 12 and pushes the raw material out from the bottom of the vertical tube 12 and fills the bottle below. By controlling the lifting distance of the circular plate 14, the single filling volume can be controlled to achieve quantitative filling.
[0033] A screw 20 is rotatably mounted on the side of the horizontal plate 6. A movable plate 21 is threaded onto the screw 20. A rotating block 19 is fixed to the bottom of the movable plate 21, and a connecting block 16 is fixed to the top of the movable column 15. A rotating rod 17 is rotatably mounted on the connecting block 16. A connecting column 18 is fixed between the two rotating rods 17. The rotating block 19 is rotatably sleeved at the center of the connecting column 18. When the screw 20 rotates, the movable plate 21 moves laterally along the screw 20, causing the rotating block 19 to move synchronously. The rotating block 19 pushes the two rotating rods 17 through the connecting column 18, thereby causing the two movable columns 15 to rise and fall synchronously. This achieves synchronous movement of the circular plates 14 of the two filling devices 8, ensuring that the single filling dose of the two filling devices 8 is completely consistent, and solving the dose deviation problem caused by traditional dual-head independent drive.
[0034] Finally, see Figure 5 In this embodiment, the filling drive assembly provides power for the rotation of the screw 20 to ensure that the two filling devices 8 operate synchronously. It includes a first motor 23, a first pulley 24 and a first transmission belt 25. A first mounting plate 22 is fixed to the side of the bracket 5. The first motor 23 is mounted on the first mounting plate 22. The first pulley 24 is fixed to both the motor output shaft and one end of the screw 20. The first transmission belt 25 is sleeved between the two pulleys.
[0035] When the first motor 23 is started, the motor drives the first pulley 24 on the output shaft to rotate, which in turn drives the first pulley 24 on the screw 20 to rotate via the first transmission belt 25, thereby driving the screw 20 to rotate. The entire driving process only requires one motor to drive the two filling units 8 to move synchronously, without the need for two independent motors to control them separately. This simplifies the structure and avoids asynchronous filling caused by differences in motor speed, further ensuring that the filling volume of the two filling units 8 is consistent and improving product consistency.
[0036] Working principle: In use, the toilet cleaner dual-head quantitative filling device first injects the toilet cleaner raw material through the input port 9 at the top of the carrying tank 7. The raw material is then diverted through the output pipe 11 at the bottom of the carrying tank 7 to the vertical pipes 12 of the two filling devices 8. The quantitative parameters of the filling devices 8 are adjusted according to the capacity of the bottles to be filled. The movement distance of the moving plate 21 is determined by controlling the rotation amplitude of the screw 20 driven by the first motor 23, thereby controlling the lifting height of the moving column 15 and the circular plate 14, and setting the single filling dosage to ensure that the filling dosage meets the production requirements.
[0037] The second motor 30 is started, and the motor drives the rotating shaft 27 to rotate through the second pulley 31 and the second transmission belt. The conveyor belt 28 starts to run in a cycle, and the bottles to be filled are placed one by one at the feed end of the conveyor belt 28. The bottles move with the conveyor belt 28. When they move directly under the two filling machines 8, the conveyor belt 28 stops (or keeps moving slowly to match the filling rhythm). At the same time, the first motor 23 is started, and the motor drives the screw 20 to rotate. The moving plate 21 moves along the screw 20. Through the rotating block 19, the connecting column 18 and the rotating rod 17, the two moving columns 15 are driven to descend synchronously. The circular plate 14 squeezes the raw material in the vertical tube 12. The raw material flows out from the bottom of the vertical tube 12 and is simultaneously filled into the two bottles below.
[0038] The filled bottles continue to move with the conveyor belt 28, leaving the filling area and being transported to subsequent processes (such as capping and labeling). At the same time, the first motor 23 rotates in the opposite direction, driving the moving column 15 and the circular plate 14 to rise, and the raw material is sucked back into the vertical pipe 12 to prepare for the next filling. Subsequent bottles continue to move with the conveyor belt 28 to the filling position, repeating the above filling action to achieve continuous and batch filling of toilet cleaner.
[0039] After production is completed, first turn off the first motor 23 and the second motor 30 to stop filling and conveying. Then, drain the remaining raw materials from the carrying tank 7 and inject clean water through the inlet 9. Start the first motor 23 to drive the filling machine 8 to operate. Rinse the vertical pipe 12 and the output pipe 11 with clean water to avoid raw material residue causing contamination during the next filling. Clean the stains on the surface of the conveyor belt 28 to ensure that the device is clean and ready for the next use.
[0040] Although embodiments of the present invention have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made to these embodiments without departing from the principles and spirit of the present invention, the scope of which is defined by the appended claims and their equivalents.
Claims
1. A dual-head quantitative filling device for toilet cleaner, characterized in that, include: Base plate (1); Support legs (2) are fixedly arranged around the bottom of the base plate (1); A conveying assembly (3) is mounted on top of the base plate (1); A dual-head filling assembly (4) is installed on the top of the base plate (1). The dual-head filling assembly (4) includes a bracket (5), which is fixedly arranged on both sides of the top of the base plate (1). A horizontal plate (6) is fixedly arranged between the tops of the bracket (5). A carrying tank (7) is fixedly arranged on the top of the horizontal plate (6). Fillers (8) are installed on both sides of the bottom of the carrying tank (7). The filler (8) includes a vertical tube (12). An input tube (13) is fixedly arranged on the side of the vertical tube (12). The other end of the input tube (13) is fixedly arranged with an output tube (11). A circular plate (14) is fixedly arranged on the top of the vertical tube (12). A moving column (15) is fixedly arranged on the top of the circular plate (14). The other end of the moving column (15) passes through the top of the vertical tube (12). A connecting block (16) is fixedly provided on the top of the movable column (15), a rotating rod (17) is rotatably provided on the connecting block (16), a connecting column (18) is fixedly provided between the rotating rods (17), and a rotating block (19) is rotatably provided at the center of the connecting column (18).
2. The toilet cleaner dual-head quantitative filling device according to claim 1, characterized in that, The top of the carrying tank (7) is provided with an inlet (9), and the bottom sides of the carrying tank (7) are provided with outlets (10). An outlet pipe (11) is fixedly installed on the outlet (10), and the outlet pipe (11) is fixedly installed with the filling device (8).
3. The toilet cleaner dual-head quantitative filling device according to claim 1, characterized in that, A screw (20) is rotatably provided on the side of the horizontal plate (6), and a movable plate (21) is provided on the screw (20) by means of a thread. The bottom of the movable plate (21) is fixedly provided with the top of the rotating block (19).
4. The toilet cleaner dual-head quantitative filling device according to claim 3, characterized in that, A first mounting plate (22) is fixedly installed on the side of the bracket (5). A first motor (23) is fixedly installed on the first mounting plate (22). A first pulley (24) is fixedly installed on the output shaft of the first motor (23) and one end of the screw (20). A first transmission belt (25) is provided between the first pulley (24).
5. The toilet cleaner dual-head quantitative filling device according to claim 1, characterized in that, The conveying assembly (3) includes a mounting hole (26), which is opened on the top of the base plate (1). Rotating shafts (27) are rotatably arranged on both sides of the mounting hole (26), and a conveyor belt (28) is sleeved between the rotating shafts (27).
6. The toilet cleaner dual-head quantitative filling device according to claim 5, characterized in that, A second mounting plate (29) is fixedly provided on the side of the support leg (2), and a second motor (30) is fixedly provided on the second mounting plate (29). A second pulley (31) is fixedly provided on the output shaft of the second motor (30) and on the rotating shaft (27) on one side. A second transmission belt (32) is provided between the second pulley (31) and the second pulley (31).