A mop cleaning device for cigarette manufacturing workshops

By designing a rotating rod and blade cleaning device and a cylindrical extrusion structure inside the cylinder, the problems of high labor intensity, high water consumption and safety hazards in the cleaning of the yarn making workshop were solved, achieving efficient cleaning and safe mop treatment.

CN224420945UActive Publication Date: 2026-06-30HONGYUN HONGHE TOBACCO (GRP) CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
HONGYUN HONGHE TOBACCO (GRP) CO LTD
Filing Date
2025-06-10
Publication Date
2026-06-30

AI Technical Summary

Technical Problem

The existing cleaning methods in cigarette production workshops are labor-intensive, consume a lot of water, pose many safety hazards and health risks to employees. Traditional long strip mops are inefficient and difficult to dehydrate effectively.

Method used

Design a mop cleaning device that includes a cylinder, a rotating rod, blades, and a dewatering mechanism. The device uses a motor to drive the rotating rod to generate vortex cleaning of the mop, and uses a cylinder to drive the cylinder to squeeze and achieve efficient cleaning and dewatering of the mop.

Benefits of technology

It achieves efficient cleaning, saves water, reduces labor intensity and safety risks, improves cleaning efficiency, and protects employee health and production safety.

✦ Generated by Eureka AI based on patent content.

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Abstract

This utility model relates to the technical field of tobacco processing equipment, specifically to a mop cleaning device for cigarette manufacturing workshops. The device includes a cylindrical body with an interference-fitted connecting seat on its outer wall. Multiple support legs are located on the side wall of the connecting seat. A bottom plate is located at the bottom of the cylindrical body, with a drain pipe at the bottom of the bottom plate. A rotating rod is rotatably connected to the top center via a bearing, and a motor is installed at the bottom center. The motor output is fixedly connected to the lower end of the rotating rod via a coupling. A circular plate is located at the upper end of the rotating rod. The device drives the rotating rod with the motor, causing the circular plate to rotate. This, combined with water flow, forms a cleaning vortex, achieving automatic cleaning of the mop. Simultaneously, a dewatering mechanism centrifuges and dehydrates the mop. Compared to traditional manual cleaning methods, this device has a simple structure and is easy to operate. It effectively improves cleaning efficiency, enhances hygiene conditions, meets the actual needs of cigarette manufacturing workshops for auxiliary cleaning equipment, and ensures the cleanliness of the workshop and the normal operation of equipment.
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Description

Technical Field

[0001] This utility model relates to the field of tobacco processing equipment technology, specifically to a mop cleaning device for cigarette production workshops. Background Technology

[0002] In the tobacco processing workshops of cigarette manufacturing enterprises, the dust concentration is generally high due to various factors such as production processes and operating environment. To ensure the cleanliness and normal operation of auxiliary equipment and maintain a good production environment, a comprehensive cleaning operation must be carried out on equipment platforms, workshop floors, vibrating conveyors, belt conveyors, and other auxiliary facilities after each shift.

[0003] Currently, long strip mops are commonly used as the main tool for workshop cleaning. Compared with traditional small cleaning tools, long strip mops have advantages such as wide cleaning coverage and high operating efficiency, making them well-suited for cleaning large areas of equipment and environments. They improve cleaning efficiency to a certain extent and meet the timeliness requirements of daily operations.

[0004] However, this cleaning method still has many shortcomings in practical applications. Long mops easily absorb large amounts of dust and stains during cleaning, requiring frequent washing and wringing. Currently, the cleaning method mainly relies on manual operation, involving rinsing and wringing under running water, which is not only labor-intensive and inefficient but also wastes a significant amount of water resources, contradicting the current development direction of energy conservation, emission reduction, and green production.

[0005] Furthermore, the low water temperature during winter cleaning operations can easily lead to occupational health risks such as frostbite and joint discomfort for employees due to prolonged hand washing, affecting their health and work safety. On the other hand, due to the limitations of the mop's structure and manual operation, the long mop strips are difficult to fully dehydrate after washing, and residual moisture can easily accumulate on the floor or equipment surface during reuse. This residual moisture does not evaporate easily in the workshop environment, making the work area slippery and increasing the risk of slips and falls, posing a significant safety hazard. It may also disrupt normal production in the workshop and increase management and operating costs.

[0006] In summary, while the existing method of cleaning the silk-making workshop using long strip mops has certain advantages in terms of work efficiency, it still has significant shortcomings in terms of cleaning convenience, water consumption, operational safety, and employee health protection. There is an urgent need to propose a new type of cleaning device with a reasonable structure and convenient operation to more effectively meet the comprehensive requirements of the silk-making workshop for cleaning operations. Utility Model Content

[0007] In view of the shortcomings of the existing technology, the purpose of this utility model is to provide a mop cleaning device for cigarette production workshops. The device has a simple structure and is easy to operate. It can achieve efficient cleaning and dehydration of mops, reduce water consumption during the cleaning process, improve cleaning efficiency, and effectively reduce manual labor intensity and safety risks.

[0008] The technical solution adopted in this utility model is as follows:

[0009] A mop cleaning device for a cigarette manufacturing workshop is provided. The device includes a cylinder 1 for containing cleaning liquid and cleaning the mop therein. A connecting seat 2 is fixedly installed on the outer peripheral wall of the cylinder 1 by interference fit. Multiple supporting legs 3 are evenly distributed along the circumference of the cylinder 1 on the side wall of the connecting seat 2 to support the cylinder 1 and ensure that the device is placed stably.

[0010] The bottom end of the cylinder 1 is connected to a bottom plate 4, and the bottom plate 4 is provided with a drain pipe 5 for discharging cleaning waste liquid. One end of the drain pipe 5 is inserted through the bottom plate 4 for discharging cleaning waste liquid.

[0011] A rotating rod 7 is rotatably connected to the center of the top surface of the base plate 4 via a first bearing 6. A motor 8 is fixedly installed in the center of the bottom surface of the base plate 4. The output shaft of the motor 8 is connected to the lower end of the rotating rod 7 via a coupling to drive the rotating rod 7 to rotate.

[0012] A circular plate 9 is fixedly connected to the upper end of the rotating rod 7. Multiple blades 10 are evenly arranged radially on the upper surface of the circular plate 9 with its central axis as the center of symmetry. The blades 10 are used to stir the water flow as the rotating rod 7 rotates and generate centrifugal force on the mop, thereby achieving cleaning or preliminary dehydration.

[0013] The top of the cylinder 1 is equipped with a dehydration mechanism for further dehydrating the washed mop to improve cleaning efficiency and reduce moisture residue.

[0014] Preferably, the dehydration mechanism includes a top seat 11 disposed at the top of the cylinder 1, and connecting plates 12 are fixedly connected to the inner walls of the front and rear sides of the top seat 11, and each connecting plate 12 is provided with a sliding groove 13 on its inner side wall.

[0015] Cylinders 14 are fixedly installed on the inner walls of the left and right sides of the top seat 11, and a support seat 15 is fixedly connected to the output end of each cylinder 14. Sliders 16 are provided on the outer walls of the front and rear sides of the support seat 15, and the sliders 16 are slidably connected to the slide groove 13.

[0016] The inner walls of the front and rear sides of the support base 15 are respectively connected to round rods 18 by second bearings 17. The two round rods 18 are arranged in parallel to each other, and a cylinder 19 is fixedly sleeved on the outer peripheral wall of each round rod 18.

[0017] The two cylinders 19 are arranged opposite each other, forming a pressing channel between them for clamping the mop. The cylinders 19 and the rod 18 rotate together and can move towards each other under the drive of the cylinder 14, so that when the mop is subjected to external force and passes through the pressing channel, it is squeezed and dehydrated by the combination of clamping and following rolling.

[0018] Preferably, the outer peripheral wall of the cylinder 19 is provided with a number of protruding structures to enhance the gripping and squeezing effect of the mop.

[0019] Preferably, the outer ring of the second bearing 17 is fixedly connected to the inner wall of the support base 15 through a bearing seat, and the inner ring of the second bearing 17 is connected to the outer peripheral wall of the round rod 18 by an interference fit.

[0020] Preferably, the two cylinders 19 are symmetrically arranged above the inner cavity of the cylinder body 1.

[0021] Preferably, the plurality of blades 10 are evenly arranged along the circumferential direction of the top wall of the circular plate 9, and gaps are left between adjacent blades.

[0022] Preferably, there are three support legs 3, which are equally spaced along the outer periphery of the cylinder 1, forming a triangular layout on the plane.

[0023] Compared with the prior art, the present invention has the following beneficial effects:

[0024] 1. Cleaning water is injected into the closed drum. The motor drives the rotating rod, which in turn rotates the circular plate and blades at high speed, generating vortices. This causes the mop strips to rub against each other in the cleaning water, achieving efficient cleaning. This structure enables the recycling of cleaning water, effectively reducing water consumption and meeting the requirements of energy conservation, environmental protection, and sustainable development. After cleaning, wastewater can be discharged through the bottom drain pipe. Subsequently, the motor continues to drive the rotating rod and blades to rotate, using centrifugal force to perform preliminary dehydration of the mop. After the drain pipe is discharged, the motor-driven rotating rod rotates the circular plate and blades to generate centrifugal force, performing preliminary dehydration of the mop.

[0025] 2. This utility model changes the traditional manual cleaning method. Employees only need to place the mop in the drum and start the device to complete the cleaning operation, avoiding direct contact with low temperature water, significantly reducing the impact of cold environment on the health of employees' hands, and effectively protecting the health and safety of employees at work.

[0026] 3. This utility model uses a cylinder to drive the support base, slider, and cylinder to move inward, achieving contact and compression of the mop strip by the two cylinders. The user only needs to lift the mop upward to effectively squeeze out the cleaning water inside. Compared to the traditional manual wringing method, it is simpler and less strenuous to operate, significantly shortening the mop cleaning and dehydration time, improving the overall efficiency of cleaning work, and promoting the efficient completion of cleaning operations for workshop auxiliary equipment.

[0027] 4. This utility model can effectively wring out the mop, reduce the impact of water from the mop on the workshop floor, reduce the risk of slippery conditions in the workshop, help eliminate safety hazards, create a safer working environment for employees, promote the normal operation of workshop production, and help reduce related costs caused by work-related injuries. Attached Figure Description

[0028] To more clearly illustrate the technical solutions of the embodiments of this utility model, the accompanying drawings used in the description of the embodiments will be briefly introduced below. Obviously, the drawings described below are only some embodiments of this utility model. For those skilled in the art, other drawings can be obtained based on these drawings without creative effort.

[0029] Figure 1 This is a schematic diagram of the structure of this utility model;

[0030] Figure 2 This is a schematic diagram of the base plate structure of this utility model;

[0031] Figure 3 This is a schematic diagram of the top seat structure of this utility model;

[0032] Figure 4 This is a schematic diagram of the cylindrical structure of this utility model.

[0033] Figure label:

[0034] 1. Cylinder body, 2. Connecting seat, 3. Support leg, 4. Base plate, 5. Drain pipe, 6. First bearing, 7. Rotating rod, 8. Motor, 9. Circular plate, 10. Blade, 11. Top seat, 12. Connecting plate, 13. Slide groove, 14. Cylinder, 15. Support seat, 16. Sliding block, 17. Second bearing, 18. Circular rod, 19. Cylinder. Detailed Implementation

[0035] 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 skilled in the art without creative effort are within the protection scope of the present utility model.

[0036] Example 1

[0037] See Figure 1-4 As shown, a mop cleaning device for a cigarette manufacturing workshop includes a cylinder 1. A connecting seat 2 is interference-fitted to the outer wall of the cylinder 1. Multiple support legs 3 are provided on the side wall of the connecting seat 2. A bottom plate 4 is provided on the bottom wall of the cylinder 1. One end of a drain pipe 5 is provided on one side of the bottom wall of the bottom plate 4. A rotating rod 7 is rotatably connected to the middle of the top wall of the bottom plate 4 through a first bearing 6. A motor 8 is provided in the middle of the bottom wall of the bottom plate 4. The output end of the motor 8 is fixedly connected to the bottom end of the rotating rod 7 through a coupling. A circular plate 9 is provided on the top wall of the rotating rod 7. Multiple blades 10 are provided on the top wall of the circular plate 9.

[0038] A dehydration mechanism is provided on the top wall of cylinder 1.

[0039] Furthermore, the dehydration mechanism includes a top seat 11, with connecting plates 12 on the inner walls of both the front and rear sides of the top seat 11. The inner wall of the connecting plates 12 is provided with a sliding groove 13. The inner walls of both the left and right sides of the top seat 11 are provided with cylinders 14. The inner drive end of the cylinders 14 is provided with a support seat 15. The outer walls of both the front and rear sides of the support seat 15 are provided with sliders 16, and the sliders 16 are slidably connected in the sliding groove 13. The inner walls of both the front and rear sides of the support seat 15 are rotatably connected with round rods 18 through second bearings 17. The inner ends of the round rods 18 are provided with cylinders 19.

[0040] Furthermore, the outer ring of the second bearing 17 is fixedly connected to the inner wall of the support seat 15 through the bearing housing, and the inner ring of the second bearing 17 is interference-fitted with the outer wall of the round rod 18.

[0041] Furthermore, two cylinders 19 are symmetrically arranged above the inner cavity of the cylinder body 1.

[0042] Furthermore, multiple blades 10 are arranged in a circular pattern on the top wall of the circular plate 9.

[0043] Furthermore, the multiple support legs 3 are arranged in a triangular configuration.

[0044] For those skilled in the art, all electrical components and parts in this case are general standard parts or parts known to those skilled in the art. Their structures and principles can be known to those skilled in the art through technical manuals or conventional experimental methods. All models are compatible with this solution and can operate normally. All electrical components in this case are connected to their compatible power supplies through wires. According to the actual situation, a suitable controller is selected to meet the control requirements. The specific connection and control sequence should refer to the working principle below, and the electrical connection is completed by the sequential operation of each electrical component. The detailed connection method is a well-known technology in the art, and the electrical control will not be described further.

[0045] One specific application of this embodiment is:

[0046] In use, pour cleaning water into the inlet cylinder 1, place the mop inside, and the motor 8 drives the rotating rod 7 to rotate the circular plate 9 and blades 10 alternately in both directions. The rotation of the blades 10 creates a vortex in the cleaning water inside the cylinder 1. Place the mop in the cleaning water, and the rotating vortex causes friction between the mop strips to clean the mop. After cleaning, move the mop upwards between the cylinders 19. The cylinder 14 pushes the support base 15, slider 16, and cylinders 19 inwards, so that the two cylinders 19 contact and squeeze the mop strips. The user lifts the mop upwards, and the squeezing action between the cylinders 19 squeezes out the cleaning water inside the mop, completing the cleaning and dehydration of the mop.

[0047] Of course, the above description is not intended to limit the present utility model, nor is the present utility model limited to the examples given above. Any changes, alterations, additions or substitutions made by those skilled in the art within the scope of the present utility model should be protected by the present utility model.

Claims

1. A mop cleaning device for a cigarette production primary processing plant, characterized by, The device includes a cylinder (1) for containing cleaning fluid and cleaning the mop therein. A connecting seat (2) is fixedly installed on the outer peripheral wall of the cylinder (1) by interference fit. Multiple supporting legs (3) are evenly distributed along the circumference of the cylinder (1) to support the cylinder (1) and ensure that the device is placed stably. The bottom end of the cylinder (1) is connected to a bottom plate (4), and the bottom plate (4) is provided with a drain pipe (5) for discharging cleaning waste liquid. One end of the drain pipe (5) is inserted through the bottom plate (4) for discharging cleaning waste liquid. A rotating rod (7) is rotatably connected to the center of the top surface of the base plate (4) via a first bearing (6). A motor (8) is fixedly installed in the center of the bottom surface of the base plate (4). The output shaft of the motor (8) is connected to the lower end of the rotating rod (7) via a coupling to drive the rotating rod (7) to rotate. The upper end of the rotating rod (7) is fixedly connected to a circular plate (9). The upper surface of the circular plate (9) is evenly provided with multiple blades (10) radially around its central axis. The blades (10) are used to rotate with the rotating rod (7) to agitate the water flow and generate centrifugal force on the mop, thereby achieving cleaning or preliminary dehydration. The top of the cylinder (1) is provided with a dehydration mechanism for further dehydrating the cleaned mop to improve cleaning efficiency and reduce moisture residue.

2. The mop cleaning device of claim 1, wherein, The dehydration mechanism includes a top seat (11) disposed at the top of the cylinder (1), and connecting plates (12) are fixedly connected to the inner walls of the front and rear sides of the top seat (11), and a sliding groove (13) is provided on the inner wall of each connecting plate (12). Cylinders (14) are fixedly installed on the inner walls of the left and right sides of the top seat (11). Each cylinder (14) is fixedly connected to a support seat (15) at its output end. Sliders (16) are provided on the outer walls of the front and rear sides of the support seat (15). The sliders (16) are slidably connected to the slide groove (13). The inner walls of the front and rear sides of the support base (15) are respectively connected to round rods (18) by second bearings (17). The two round rods (18) are arranged in parallel to each other, and a cylinder (19) is fixedly sleeved on the outer peripheral wall of each round rod (18). The two cylinders (19) are arranged opposite each other, forming a pressing channel between them for clamping the mop. The cylinders (19) and the rod (18) rotate together and can move towards each other under the drive of the cylinder (14) so ​​that when the mop is subjected to external force and passes through the pressing channel, it is squeezed and dehydrated by the combination of clamping and following rolling.

3. The mop cleaning device of claim 2, wherein, The outer peripheral wall of the cylinder (19) is provided with several protruding structures to enhance the gripping and squeezing effect of the mop.

4. The mop cleaning device of claim 2, wherein, The outer ring of the second bearing (17) is fixedly connected to the inner wall of the support (15) through the bearing seat, and the inner ring of the second bearing (17) is connected to the outer peripheral wall of the round rod (18) by interference fit.

5. The mop cleaning device of claim 2, wherein, The two cylinders (19) are symmetrically arranged above the inner cavity of the cylinder (1).

6. The mop cleaning device according to claim 1, characterized in that, Multiple blades (10) are evenly arranged along the circumferential direction of the top wall of the circular plate (9), with gaps between adjacent blades.

7. The mop cleaning device according to claim 1, characterized in that, The support legs (3) are three in number and are equally spaced along the outer periphery of the cylinder (1), forming a triangular layout on the plane.