A sole cleaning and static elimination device
By designing a shoe sole cleaning and static elimination device, which combines roller brush cleaning, negative pressure air drying, and ion blowing static elimination, the problem of dirty shoe soles and static electricity elimination in electronics factory workshops has been solved, improving the 5S environment and the lifespan of components, and meeting mobile needs.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- GREE ELECTRIC APPLIANCES ZHENGZHOU
- Filing Date
- 2025-06-23
- Publication Date
- 2026-06-26
AI Technical Summary
In existing electronics factory workshops, dirt on the soles of workers' shoes cannot be effectively removed, resulting in the workshop failing to meet 5S environmental standards. At the same time, traditional air showers occupy a large area, are difficult to move, and cannot meet the needs of different environments. Furthermore, static electricity is not completely eliminated, affecting the lifespan of electronic components.
Design a shoe sole cleaning and static electricity elimination device, including a shoe sole cleaning mechanism, a drying mechanism and a static electricity elimination mechanism. The device uses a roller brush to clean the shoe sole, a negative pressure fan to dry it, and an ion blowing component and a static electricity elimination chain to automatically eliminate static electricity from personnel.
It effectively cleans and dries shoe soles, eliminates static electricity on personnel, improves the 5S environment in the workshop, reduces damage to electronic components caused by static electricity, and the device can be quickly moved to meet the needs of different sites.
Smart Images

Figure CN224404185U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of shoe sole cleaning technology, and in particular to a shoe sole cleaning and static electricity elimination device. Background Technology
[0002] The electrical box is a core electronic component of an air conditioner and is part of its control system. The production of the electrical box requires a high-quality production environment, including the elimination of static electricity. Similarly, the production of most electronic products faces stringent requirements regarding the production environment and static electricity elimination.
[0003] Currently, production workers in electronics factories need to pass through air showers to remove static electricity before entering the workshop. However, this process cannot remove dirt from the soles of their shoes, causing the workshop environment to fail to meet 5S standards. Furthermore, traditional air showers are large in size and difficult to move, failing to meet the needs of different environments.
[0004] Therefore, it is necessary to design a better shoe sole cleaning and static electricity elimination device. Utility Model Content
[0005] This utility model provides a shoe sole cleaning and static electricity elimination device, which can automatically clean shoe soles, remove dirt from the soles of production workers' shoes, improve the 5S environment in the workshop, and simultaneously eliminate static electricity from the human body.
[0006] This utility model provides a shoe sole cleaning and static electricity elimination device, including a shoe sole cleaning mechanism; a drying mechanism disposed at the rear end of the shoe sole cleaning mechanism; and a static electricity elimination mechanism, the static electricity elimination mechanism including an ion blowing component and a static electricity elimination chain, the ion blowing component being disposed on at least one side of the drying mechanism to blow away static electricity from the human body, and the static electricity elimination chain being disposed above the drying mechanism for contact with the human body to eliminate static electricity from the human body.
[0007] In one embodiment, the ion blowing assembly includes: a side frame located on one side of the drying mechanism; and a plurality of ion blowers disposed within the side frame; wherein the air outlets of the ion blowers face the drying area where the drying mechanism is located.
[0008] In one embodiment, the side frames are disposed on opposite sides of the drying mechanism, and the air outlets of the ion fans in the side frames are arranged facing each other to blow on the human body located in the drying area.
[0009] In one embodiment, the side frame has multiple slots facing the drying area, and the air outlet of the ion fan is located in the slots.
[0010] In one embodiment, a first sensor is provided at the front edge of the side frame, and a second sensor is provided at the rear edge of the side frame. The first sensor and the second sensor are respectively used to detect whether a human body enters or leaves the drying area. Both the first sensor and the second sensor are electrically connected to the static electricity elimination mechanism.
[0011] In one embodiment, the static electricity elimination link is used to discharge static electricity from the human body to the ground.
[0012] In one embodiment, the shoe sole cleaning and static electricity elimination device further includes a base, and the shoe sole cleaning mechanism includes: a first water storage chamber disposed in the base; and a roller brush rotatably mounted on the base, the roller brush being located above the first water storage chamber; wherein, when the roller brush rotates, the roller brush drives the water in the first water storage chamber to rotate accordingly, so as to clean the shoe sole.
[0013] In one embodiment, the base is provided with a frame, the front end of the frame is provided with a handrail, and the rear end of the frame extends above the static electricity elimination mechanism.
[0014] In one embodiment, the front end of the frame is provided with at least one inlet sensor, which detects a human body entering the shoe sole cleaning mechanism to automatically control the rotation of the roller brush.
[0015] In one embodiment, the first water storage chamber is provided with a clean water inlet and a first sewage outlet. The first water storage chamber is provided with a liquid level detection device, which detects the water level in the first water storage chamber to automatically control water replenishment or drainage.
[0016] In one embodiment, the drying mechanism includes: a drain plate mounted on the base; and a plurality of negative pressure fans disposed at the bottom of the drain plate, wherein the air from the negative pressure fans dries the soles of the shoes.
[0017] In one embodiment, the rear end of the base is provided with a second water storage cavity, which is located below the drain plate and is separated from the first water storage cavity.
[0018] In one embodiment, the base is provided with a drain button, which controls the discharge of sewage from the first water storage chamber and / or the second water storage chamber.
[0019] Compared with existing technologies, the advantages of this utility model are as follows: the shoe sole cleaning mechanism can clean the soles of personnel entering the cleaning area, and the drying mechanism can dry the soles, removing dirt and drying them, thus improving the 5S environment in the workshop; at the same time, the ion blowing component can blow away static electricity from the human body, and in conjunction with the static elimination chain, it can eliminate static electricity from the human body, effectively solving the problem of incomplete static electricity elimination for personnel entering the workshop in electronics factories, reducing damage to electronic components caused by static electricity, and extending the service life of electronic components. The entire device can be moved quickly to meet the needs of different sites and factories. Attached Figure Description
[0020] The present invention will be described in more detail below based on embodiments and with reference to the accompanying drawings.
[0021] Figure 1 This is a schematic diagram of the structure of the shoe sole cleaning and static electricity elimination device of this utility model;
[0022] Figure 2 yes Figure 1 A magnified view of a section at point A in the middle;
[0023] Figure 3 This is a schematic diagram of the structure of one side of the ion blowing component in the shoe sole cleaning and static electricity elimination device of this utility model;
[0024] Figure 4 yes Figure 1 A bottom view;
[0025] Figure label:
[0026] 1. Shoe sole cleaning mechanism; 10. Base; 11. Frame; 111. Column; 112. Crossbeam; 113. Connecting beam; 12. First water storage chamber; 121. Clean water inlet; 122. First wastewater outlet; 123. Liquid level detection device; 13. Roller brush; 14. Support plate; 15. Inlet sensor; 16. Motor;
[0027] 2. Air drying mechanism; 21. Draining plate; 22. Negative pressure fan; 23. Second water storage chamber; 24. Second sewage outlet; 25. Drain button;
[0028] 3. Static elimination mechanism; 31. Ion blowing assembly; 311. Side frame; 312. Ion fan; 313. Slotting; 32. First sensor; 33. Second sensor; 34. Static elimination chain. Detailed Implementation
[0029] 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.
[0030] It should be noted that all directional indicators (such as up, down, left, right, front, back, etc.) in this utility model embodiment are only used to explain the relative positional relationship and movement of each component in a certain specific posture (as shown in the figure). If the specific posture changes, the directional indicator will also change accordingly.
[0031] Furthermore, the use of terms such as "first" and "second" in this utility model is for descriptive purposes only and should not be construed as indicating or implying their relative importance or implicitly specifying the number of technical features indicated. Therefore, a feature defined as "first" or "second" may explicitly or implicitly include at least one of that feature. Additionally, the technical solutions of the various embodiments can be combined with each other, but only on the basis of being achievable by those skilled in the art. When the combination of technical solutions is contradictory or impossible to implement, such a combination of technical solutions should be considered non-existent and not within the scope of protection claimed by this utility model.
[0032] like Figure 1 As shown, this utility model provides a shoe sole cleaning and static electricity elimination device, including a shoe sole cleaning mechanism 1, a drying mechanism 2 disposed at the rear end of the shoe sole cleaning mechanism 1, and a static electricity elimination mechanism 3. The static electricity elimination mechanism 3 includes an ion blowing component 31 and a static electricity elimination chain 34. The ion blowing component 31 is disposed on at least one side of the drying mechanism 2 to blow away static electricity from the human body. The static electricity elimination chain 34 is disposed above the drying mechanism 2 for contact with the human body to eliminate static electricity from the human body.
[0033] The shoe sole cleaning mechanism 1 can clean the soles of the shoes of personnel entering the cleaning area. The drying mechanism 2 can dry the soles, removing dirt and drying them, thus improving the 5S environment of the workshop. At the same time, the ion blowing component 31 can blow away static electricity from the human body. In conjunction with the static elimination chain 34, static electricity can be eliminated from the human body, effectively solving the problem of incomplete static electricity elimination for personnel entering the workshop in electronics factories. This reduces the damage of static electricity to electronic components and extends the service life of electronic components. The entire device can be moved quickly to meet the needs of different sites and factories.
[0034] like Figure 1As shown, the shoe sole cleaning and static electricity elimination device includes a base 10 and a frame 11 mounted on the base 10. The shoe sole cleaning mechanism 1 and the drying mechanism 2 are sequentially arranged on the base 10. The frame 11 includes a column 111 mounted on the front end of the base 10. The top of the column 111 bends backward and extends to the rear end of the drying mechanism 2, and is mounted on the top of the static electricity elimination mechanism 3, forming a door shape. The height of the column 111 at the front end of the frame 11 is the same as the height of a human body, which is 1.5 meters to 1.8 meters. Therefore, the column 111 can be used as a handrail. When people enter, they can hold onto the handrail to enter the shoe sole cleaning mechanism 1.
[0035] It should be noted that multiple crossbeams 112 of different heights are connected between the front and rear columns 111. The crossbeams 112 extend from the front end of the shoe sole cleaning mechanism 1 to the rear end of the drying mechanism 2. When people walk on the shoe sole cleaning mechanism 1 and the drying mechanism 2, they can hold onto the crossbeams 112 to avoid falling.
[0036] In this embodiment, the base 10 has columns 111 and crossbeams 112 on both sides. Two crossbeams 112 are provided between the columns 111 on each side, and the height of the two crossbeams 112 is adapted to all passing personnel. The lower crossbeam 112 is used by shorter personnel, and the higher crossbeam 112 is used by taller personnel.
[0037] It should be noted that the tops of the two side columns 111 are also equipped with connecting beams 113, which are located above the drying mechanism 2 and near the rear end of the drying mechanism 2. The connecting beams 113 are used to suspend the static electricity eliminator chain 34. When a person walks out of the drying mechanism 2, the upper body of the person comes into contact with the static electricity eliminator chain 34, thereby eliminating static electricity from the person.
[0038] It should also be noted that the column 111, the crossbeam 112 and the connecting beam 113 are all made of metal pipes. The static electricity elimination chain 34 is suspended on the connecting beam 113. The static electricity of the human body is conducted to the base 10 through the static electricity elimination chain 34, the connecting beam 113 and the column 111, and finally to the ground, so as to achieve the grounding of the static electricity elimination chain 34, thereby conducting the static electricity of the human body to the ground and realizing the elimination of static electricity of the human body.
[0039] Example 1
[0040] like Figure 1 and Figure 3 As shown, the static electricity elimination mechanism 3 includes an ion blowing assembly 31 and a static electricity elimination chain 34. The ion blowing assembly 31 includes a side frame 311 located on one side of the drying mechanism 2; multiple ion blowers 312 are disposed within the side frame 311; wherein the air outlets of the ion blowers 312 face the drying area where the drying mechanism 2 is located. The static electricity elimination chain 34 is disposed above the drying mechanism 2 and is used to contact the human body to eliminate static electricity from the human body.
[0041] In this embodiment, the side frames 311 are arranged on opposite sides of the drying mechanism 2, and the air outlets of the ion fans 312 inside the side frames 311 are arranged facing each other to blow on the human body located in the drying area, thereby eliminating static electricity from the human body. The ion fans 312 are mainly used to blow away static electricity from the lower half of the human body.
[0042] It should be noted that the side frame 311 has multiple slots 313 in the front-to-back direction facing the drying area. The air outlet of the ion fan 312 is located in the slots 313. The multiple slots 313 are arranged along the height direction of the side frame 311. Therefore, the air from the ion fan 312 can be blown evenly to the lower body of the human body, thereby removing static electricity from the lower body and feet.
[0043] In some embodiments, a first sensor 32 is provided at the front edge of the side frame 311, and a second sensor 33 is provided at the rear edge of the side frame 311. The first sensor 32 and the second sensor 33 are respectively used to detect whether a person enters or leaves the drying area. Both the first sensor 32 and the second sensor 33 are electrically connected to the static elimination mechanism 3, thereby automatically controlling the opening or closing of the ion blower 312, and realizing the automatic opening or closing of the ion blowing assembly 31. When a person does not enter the drying area, the ion blower 312 is not turned on. When the first sensor 32 detects a person passing by, it controls the ion blower 312 to turn on, blowing on the person to eliminate static electricity. When the second sensor 33 detects a person passing by, it indicates that the person has walked out of the rear of the drying area, and at this time, it controls the ion blower 312 to turn off to save energy.
[0044] In some embodiments, the ion blowing assembly 31 needs to periodically detect the ion wind concentration to ensure the electrostatic blowing effect.
[0045] It should be noted that the static electricity eliminator chain 34 is grounded to conduct static electricity from the human body to the ground. When a person passes by and comes into contact with the static electricity eliminator chain 34, the static electricity on the person is eliminated, mainly eliminating static electricity from the upper body. In this embodiment, the static electricity eliminator chain 34 is grounded through the metal frame 11 and the base 10 connected to the ground. The static electricity from the human body is conducted to the base 10 through the static electricity eliminator chain 34, the connecting beam 113, and the column 111, and finally to the ground, thus achieving the grounding of the static electricity eliminator chain 34 and conducting the static electricity from the human body to the ground, thereby eliminating static electricity from the human body.
[0046] In this embodiment, a connecting beam 113 is provided at the top rear end of the frame 11, and an electrostatic eliminator chain 34 is suspended on the connecting beam 113. When a human body walks through the drying area, the upper body or head of the human body comes into contact with the electrostatic eliminator chain 34, thereby guiding the static electricity of the upper body to the connecting beam 113 and the frame 11, further grounding it and realizing the elimination of static electricity in the human body.
[0047] Example 2
[0048] like Figure 1 and Figure 3 As shown, the static electricity elimination mechanism 3 includes an ion blowing assembly 31 and a static electricity elimination chain 34. The ion blowing assembly 31 includes a side frame 311 located on one side of the drying mechanism 2; multiple ion blowers 312 are disposed within the side frame 311; wherein the air outlets of the ion blowers 312 face the drying area where the drying mechanism 2 is located. The static electricity elimination chain 34 is disposed above the drying mechanism 2 and is used to contact the human body to eliminate static electricity from the human body.
[0049] In this embodiment, the side frames 311 are arranged on opposite sides of the drying mechanism 2, and the air outlets of the ion fans 312 inside the side frames 311 are arranged facing each other to blow on the human body located in the drying area, thereby eliminating static electricity from the human body. The ion fans 312 are mainly used to blow away static electricity from the lower half of the human body.
[0050] It should be noted that the side frame 311 has multiple slots 313 in the front-to-back direction facing the drying area. The air outlet of the ion fan 312 is located in the slots 313. The multiple slots 313 are arranged along the height direction of the side frame 311. Therefore, the air from the ion fan 312 can be blown evenly to the lower body of the human body, thereby removing static electricity from the lower body and feet.
[0051] In some embodiments, a first sensor 32 is provided at the front edge of the side frame 311, and a second sensor 33 is provided at the rear edge of the side frame 311. The first sensor 32 and the second sensor 33 are respectively used to detect whether a person enters or leaves the drying area. Both the first sensor 32 and the second sensor 33 are electrically connected to the static elimination mechanism 3, thereby automatically controlling the opening or closing of the ion blower 312, and realizing the automatic opening or closing of the ion blowing assembly 31. When a person does not enter the drying area, the ion blower 312 is not turned on. When the first sensor 32 detects a person passing by, it controls the ion blower 312 to turn on, blowing on the person to eliminate static electricity. When the second sensor 33 detects a person passing by, it indicates that the person has walked out of the rear of the drying area, and at this time, it controls the ion blower 312 to turn off to save energy.
[0052] In some embodiments, the ion blowing assembly 31 needs to periodically detect the ion wind concentration to ensure the electrostatic blowing effect.
[0053] It should be noted that the static electricity eliminator chain 34 is grounded to conduct static electricity from the human body to the ground. When a person passes by and comes into contact with the static electricity eliminator chain 34, the static electricity on the person is eliminated, mainly eliminating static electricity from the upper body. In this embodiment, the static electricity eliminator chain 34 is grounded through the metal frame 11 and the base 10 connected to the ground. The static electricity from the human body is conducted to the base 10 through the static electricity eliminator chain 34, the connecting beam 113, and the column 111, and finally to the ground, thus achieving the grounding of the static electricity eliminator chain 34 and conducting the static electricity from the human body to the ground, thereby eliminating static electricity from the human body.
[0054] In this embodiment, a connecting beam 113 is provided at the top rear end of the frame 11, and an electrostatic eliminator chain 34 is suspended on the connecting beam 113. When a human body walks through the drying area, the upper body or head of the human body comes into contact with the electrostatic eliminator chain 34, thereby guiding the static electricity of the upper body to the connecting beam 113 and the frame 11, thus eliminating the static electricity of the human body.
[0055] like Figure 1 and Figure 2 As shown, the shoe sole cleaning mechanism 1 includes a first water storage chamber 12, which is disposed in the base 10; and a roller brush 13, which is rotatably mounted on the base 10 and is located above the first water storage chamber 12. When the roller brush 13 rotates, it drives the water in the first water storage chamber 12 to rotate, thereby cleaning the shoe sole.
[0056] It should be noted that multiple roller brushes 13 are installed side by side inside the base 10. Each roller brush 13 includes a roller and brushes installed on the outer periphery of the roller. The two ends of the roller are installed inside the base 10 through a pivot. The brushes are made of soft material, such as cloth strips, fur, or other materials. The brushes are arranged in rows around the outer periphery of the roller. When the roller rotates, it drives the brushes to rotate, thereby brushing the sole of the shoe.
[0057] A support plate 14 is mounted on the base 10. The support plate 14 is installed on the top of the first water storage chamber 12 in a grid pattern. The brush part of the roller brush 13 passes through the grid of the support plate 14, thereby contacting the sole of the shoe. When a person walks in the sole cleaning mechanism 1, their feet step on the support plate 14, which provides support for the person. At the same time, the open grid on the support plate 14 allows the brush to pass through and clean the sole of the shoe.
[0058] When it is necessary to clean the dirt in the first water storage chamber 12, the support plate 14 and the roller brush 13 can be removed to clean the base 10, so as to avoid excessive dirt and affect the cleaning effect.
[0059] like Figure 1 and Figure 4As shown, in this embodiment, a motor 16 is provided at one end of the base 10. The output end of the motor 16 is connected to the end of each roller through a sprocket and chain structure. The motor 16 drives the roller to rotate, thereby driving the roller brush 13 to brush the sole of the shoe.
[0060] In other embodiments, the rollers may be driven to rotate in other ways, and this invention does not limit this to any particular method.
[0061] In other embodiments, the transmission method between the motor 16 and the roller brush 13 is not limited to the sprocket and chain structure, and other methods can also be used. This utility model does not limit this.
[0062] It should be noted that at least one inlet sensor 15 is provided at the front end of the frame 11. The inlet sensor 15 detects a human body entering the shoe sole cleaning mechanism 1 to automatically control the rotation of the roller brush 13. In this embodiment, inlet sensors 15 are provided at both the high and low points of the front end of the frame 11. When the inlet sensor 15 detects a human body passing by, it sends a start signal to the motor 16, which drives the roller brush 13 to rotate. The roller brush 13 rotates with water to clean the shoe sole. When the first sensor 32 detects a human body passing by, the human body has entered the drying area, and a stop signal is sent to the motor 16, thereby stopping the rotation of the roller brush 13.
[0063] It should be noted that the first water storage chamber 12 is located below the roller brush 13, and the first water storage chamber 12 is kept with sufficient water. When the roller brush 13 rotates, it can drive the water in the first water storage chamber 12 to rotate as well, thereby washing the shoe sole with water and ensuring that the shoe sole is clean.
[0064] The first water storage chamber 12 is equipped with a clean water inlet 121 and a first wastewater outlet 122. A liquid level detection device 123 is installed inside the first water storage chamber 12 to detect the water level and automatically control water replenishment. The clean water inlet 121 is connected to an automatic water replenishment pump (not shown) via a water pipe. The automatic water replenishment pump can start and stop automatically. When the liquid level detection device 123 detects that the water level in the first water storage chamber 12 is lower than the set water level, the automatic water replenishment pump starts, adding water to the first water storage chamber 12 through the clean water inlet 121. When the liquid level detection device 123 detects that the water level in the first water storage chamber 12 reaches the set water level, the automatic water replenishment pump stops replenishing water and simultaneously sends a signal to the shoe sole cleaning mechanism 1, indicating that the water level meets the start-up conditions of the shoe sole cleaning mechanism 1.
[0065] In this embodiment, the first water storage chamber 12 is filled with clean water. In other embodiments, water with cleaning solution can also be added to the first water storage chamber 12 to clean the soles of the shoes more thoroughly.
[0066] Example 3
[0067] like Figure 1 and Figure 3 As shown, the static electricity elimination mechanism 3 includes an ion blowing assembly 31 and a static electricity elimination chain 34. The ion blowing assembly 31 includes a side frame 311 located on one side of the drying mechanism 2; multiple ion blowers 312 are disposed within the side frame 311; wherein the air outlets of the ion blowers 312 face the drying area where the drying mechanism 2 is located. The static electricity elimination chain 34 is disposed above the drying mechanism 2 and is used to contact the human body to eliminate static electricity from the human body.
[0068] In this embodiment, the side frames 311 are arranged on opposite sides of the drying mechanism 2, and the air outlets of the ion fans 312 inside the side frames 311 are arranged facing each other to blow on the human body located in the drying area, thereby eliminating static electricity from the human body. The ion fans 312 are mainly used to blow away static electricity from the lower half of the human body.
[0069] It should be noted that the side frame 311 has multiple slots 313 in the front-to-back direction facing the drying area. The air outlet of the ion fan 312 is located in the slots 313. The multiple slots 313 are arranged along the height direction of the side frame 311. Therefore, the air from the ion fan 312 can be blown evenly to the lower body of the human body, thereby removing static electricity from the lower body and feet.
[0070] In some embodiments, a first sensor 32 is provided at the front edge of the side frame 311, and a second sensor 33 is provided at the rear edge of the side frame 311. The first sensor 32 and the second sensor 33 are respectively used to detect whether a person enters or leaves the drying area. Both the first sensor 32 and the second sensor 33 are electrically connected to the static elimination mechanism 3, thereby automatically controlling the opening or closing of the ion blower 312, and realizing the automatic opening or closing of the ion blowing assembly 31. When a person does not enter the drying area, the ion blower 312 is not turned on. When the first sensor 32 detects a person passing by, it controls the ion blower 312 to turn on, blowing on the person to eliminate static electricity. When the second sensor 33 detects a person passing by, it indicates that the person has walked out of the rear of the drying area, and at this time, it controls the ion blower 312 to turn off to save energy.
[0071] In some embodiments, the ion blowing assembly 31 needs to periodically detect the ion wind concentration to ensure the electrostatic blowing effect.
[0072] It should be noted that the static electricity eliminator chain 34 is grounded to conduct static electricity from the human body to the ground. When a person passes by and comes into contact with the static electricity eliminator chain 34, the static electricity on the person is eliminated, mainly eliminating static electricity from the upper body. In this embodiment, the static electricity eliminator chain 34 is grounded through the metal frame 11 and the base 10 connected to the ground. The static electricity from the human body is conducted to the base 10 through the static electricity eliminator chain 34, the connecting beam 113, and the column 111, and finally to the ground, thus achieving the grounding of the static electricity eliminator chain 34 and conducting the static electricity from the human body to the ground, thereby eliminating static electricity from the human body.
[0073] In this embodiment, a connecting beam 113 is provided at the top rear end of the frame 11, and an electrostatic eliminator chain 34 is suspended on the connecting beam 113. When a human body walks through the drying area, the upper body or head of the human body comes into contact with the electrostatic eliminator chain 34, thereby guiding the static electricity of the upper body to the connecting beam 113 and the frame 11, thus eliminating the static electricity of the human body.
[0074] like Figure 1 and Figure 2 As shown, the shoe sole cleaning mechanism 1 includes a first water storage chamber 12, which is disposed in the base 10; and a roller brush 13, which is rotatably mounted on the base 10 and is located above the first water storage chamber 12. When the roller brush 13 rotates, it drives the water in the first water storage chamber 12 to rotate, thereby cleaning the shoe sole.
[0075] It should be noted that multiple roller brushes 13 are installed side by side inside the base 10. Each roller brush 13 includes a roller and brushes installed on the outer periphery of the roller. The two ends of the roller are installed inside the base 10 through a pivot. The brushes are made of soft material, such as cloth strips, fur, or other materials. The brushes are arranged in rows around the outer periphery of the roller. When the roller rotates, it drives the brushes to rotate, thereby brushing the sole of the shoe.
[0076] A support plate 14 is mounted on the base 10. The support plate 14 is installed on the top of the first water storage chamber 12 in a grid pattern. The brush part of the roller brush 13 passes through the grid of the support plate 14, thereby contacting the sole of the shoe. When a person walks in the sole cleaning mechanism 1, their feet step on the support plate 14, which provides support for the person. At the same time, the open grid on the support plate 14 allows the brush to pass through and clean the sole of the shoe.
[0077] When it is necessary to clean the dirt in the first water storage chamber 12, the support plate 14 and the roller brush 13 can be removed to clean the base 10, so as to avoid excessive dirt and affect the cleaning effect.
[0078] like Figure 1 and Figure 4As shown, in this embodiment, a motor 16 is provided at one end of the base 10. The output end of the motor 16 is connected to the end of each roller through a sprocket and chain structure. The motor 16 drives the roller to rotate, thereby driving the roller brush 13 to brush the sole of the shoe.
[0079] In other embodiments, the rollers may be driven to rotate in other ways, and this invention does not limit this to any particular method.
[0080] In other embodiments, the transmission method between the motor 16 and the roller brush 13 is not limited to the sprocket and chain structure, and other methods can also be used. This utility model does not limit this.
[0081] It should be noted that at least one inlet sensor 15 is provided at the front end of the frame 11. The inlet sensor 15 detects a human body entering the shoe sole cleaning mechanism 1 to automatically control the rotation of the roller brush 13. In this embodiment, inlet sensors 15 are provided at both the high and low points of the front end of the frame 11. When the inlet sensor 15 detects a human body passing by, it sends a start signal to the motor 16, which drives the roller brush 13 to rotate. The roller brush 13 rotates with water to clean the shoe sole. When the first sensor 32 detects a human body passing by, the human body has entered the drying area, and a stop signal is sent to the motor 16, thereby stopping the rotation of the roller brush 13.
[0082] It should be noted that the first water storage chamber 12 is located below the roller brush 13, and the first water storage chamber 12 is kept with sufficient water. When the roller brush 13 rotates, it can drive the water in the first water storage chamber 12 to rotate as well, thereby washing the shoe sole with water and ensuring that the shoe sole is clean.
[0083] The first water storage chamber 12 is equipped with a clean water inlet 121 and a first wastewater outlet 122. A liquid level detection device 123 is installed inside the first water storage chamber 12 to detect the water level and automatically control water replenishment. The clean water inlet 121 is connected to an automatic water replenishment pump (not shown) via a water pipe. The automatic water replenishment pump can start and stop automatically. When the liquid level detection device 123 detects that the water level in the first water storage chamber 12 is lower than the set water level, the automatic water replenishment pump starts, adding water to the first water storage chamber 12 through the clean water inlet 121. When the liquid level detection device 123 detects that the water level in the first water storage chamber 12 reaches the set water level, the automatic water replenishment pump stops replenishing water and simultaneously sends a signal to the shoe sole cleaning mechanism 1, indicating that the water level meets the start-up conditions of the shoe sole cleaning mechanism 1.
[0084] In this embodiment, the first water storage chamber 12 is filled with clean water. In other embodiments, water with cleaning solution can also be added to the first water storage chamber 12 to clean the soles of the shoes more thoroughly.
[0085] like Figure 1 and Figure 4As shown, the air-drying mechanism 2 includes a drain plate 21, which is installed on the base 10; and a plurality of negative pressure fans 22, which are located at the bottom of the drain plate 21, and the negative pressure fans 22 blow the water on the soles of the shoes dry.
[0086] The rear end of the base 10 is provided with a second water storage chamber 23, which is located below the drain plate 21. The drain plate 21 has multiple holes. When a person passes through the shoe sole cleaning mechanism 1, the shoe sole is washed with water. At this time, the shoe sole will carry water. When the person enters the drying mechanism 2, the shoe sole steps on the drain plate 21, and the water on the shoe sole will flow into the second water storage chamber 23 through the holes of the drain plate 21. At the same time, the negative pressure fan 22 is started, and the air from the negative pressure fan 22 blows towards the shoe sole, thereby drying the shoe sole.
[0087] In this embodiment, the second water storage chamber 23 and the first water storage chamber 12 are respectively located at the front end and rear end of the base 10, and are separated to prevent water from flowing in the two water storage chambers.
[0088] In this embodiment, the negative pressure fan 22 and the ion fan 312 are turned on or off synchronously. When the first sensor 32 detects a person passing by, it indicates that the person has entered the drying area. At this time, the negative pressure fan 22 and the ion fan 312 are activated. While the negative pressure fan 22 dries the soles of the shoes, the ion fan 312 blows on the lower body of the person to eliminate static electricity. When the second sensor 33 detects a person passing by, it indicates that the person has left the drying area. At this time, the negative pressure fan 22 and the ion fan 312 are turned off.
[0089] In some embodiments, the second water storage chamber 23 is provided with a second sewage outlet 24, and the base 10 is provided with a drain button 25. The drain button 25 controls the discharge of sewage from the first water storage chamber 12 and / or the second water storage chamber 23. To ensure the cleaning effect, the sewage in the first water storage chamber 12 and the second water storage chamber 23 needs to be cleaned regularly. The cleaning personnel manually press the drain button 25, at which time the first sewage outlet 122 and the second sewage outlet 24 open, and the internal drain pump starts to drain, realizing the discharge of sewage from the first water storage chamber 12 and the second water storage chamber 23.
[0090] In some embodiments, the drain plate 21 is detachably mounted on the base 10. When it is necessary to clean the dirt in the second water storage chamber 23, the drain plate 21 and the negative pressure fan 22 can be removed to clean the base 10 and avoid excessive dirt accumulation.
[0091] This utility model of a shoe sole cleaning and static electricity elimination device can be automatically controlled. The operation process is as follows:
[0092] The liquid level detection device 123 detects the water level in the first water storage chamber 12. When the liquid level detection device 123 detects that the water level in the first water storage chamber 12 is lower than the set water level, the automatic water replenishment pump is turned on and water is added to the first water storage chamber 12 through the clean water inlet 121. When the liquid level detection device 123 detects that the water level in the first water storage chamber 12 reaches the set water level, the automatic water replenishment pump stops replenishing water and sends a signal to the shoe sole cleaning mechanism 1 to indicate that the water level meets the start-up conditions of the shoe sole cleaning mechanism 1.
[0093] When the entrance sensor 15 detects a human entering, it sends a start signal to the motor 16. The motor 16 starts, driving the roller brush 13 to rotate. The roller brush 13 rotates with water from the first water storage chamber 12, cleaning the soles of the shoes. After a certain cleaning time (30 seconds), the human enters the drying area. When the first sensor 32 detects the human entering, it sends a stop signal to the motor 16, causing the motor 16 to stop rotating. Simultaneously, the negative pressure fan 22 and the ion fan 312 start. While the negative pressure fan 22 dries the soles of the shoes, the ion fan 312 blows on the lower half of the human body, eliminating static electricity. After the human body is in the static elimination mechanism 3 for a certain period of time (30 seconds), it leaves the ion elimination mechanism. During the departure process, the human touches the static elimination chain 34, which further eliminates static electricity from the upper half of the human body. When the second sensor 33 detects the human leaving, the negative pressure fan 22 and the ion fan 312 turn off, realizing the automatic cleaning of the soles of the shoes and the elimination of static electricity from the human body.
[0094] After the shoe sole cleaning and static elimination device has been running for a certain period of time, the employee manually drains the sewage by pressing the drain button 25. The first sewage outlet 122 and the second sewage outlet 24 open, and the internal drain pump starts to drain the sewage, realizing the discharge of sewage from the first water storage chamber 12 and the second water storage chamber 23.
[0095] This utility model of a shoe sole cleaning and static electricity elimination device can be used in workshops of various electronic manufacturing plants to clean the soles of workers' shoes and eliminate static electricity from their bodies, preventing damage to electronic products caused by static electricity or quality hazards caused by non-compliance with 5S standards. Furthermore, the device has a simple overall structure and can be transported to different locations to meet the needs of different sites and factories.
[0096] Although the present invention has been described with reference to preferred embodiments, various modifications can be made thereto and components can be replaced with equivalents without departing from the scope of the invention. In particular, the technical features mentioned in the various embodiments can be combined in any manner, provided there is no structural conflict. The present invention is not limited to the specific embodiments disclosed herein, but includes all technical solutions falling within the scope of the claims.
Claims
1. A shoe sole cleaning and static electricity eliminating device, characterized in that, include: Shoe sole cleaning service; A drying mechanism is located at the rear end of the shoe sole cleaning mechanism; as well as An electrostatic elimination mechanism includes an ion blowing component and an electrostatic elimination chain. The ion blowing component is disposed on at least one side of the drying mechanism to blow away static electricity from the human body. The electrostatic elimination chain is disposed above the drying mechanism for contact with the human body to eliminate static electricity.
2. The shoe sole cleaning and static electricity eliminating device according to claim 1, wherein, The ion blowing assembly includes: A side frame, located on one side of the drying mechanism; Multiple ion fans are installed inside the side frame; The outlet of the ion fan faces the drying area where the drying mechanism is located.
3. The shoe sole cleaning and static electricity elimination device according to claim 2, characterized in that, The side frames are arranged on opposite sides of the drying mechanism, and the air outlets of the ion fans in the side frames are arranged facing each other to blow on the human body located in the drying area.
4. The shoe sole cleaning and static electricity elimination device according to claim 2 or 3, characterized in that, The side frame has multiple slots facing the drying area, and the air outlet of the ion fan is located in the slots.
5. The shoe sole cleaning and static electricity elimination device according to claim 2, characterized in that, The front edge of the side frame is provided with a first sensor, and the rear edge of the side frame is provided with a second sensor. The first sensor and the second sensor are respectively used to detect whether a human body enters or leaves the drying area. Both the first sensor and the second sensor are electrically connected to the static elimination mechanism.
6. The shoe sole cleaning and static electricity elimination device according to claim 1, characterized in that, The static electricity elimination link is used to discharge static electricity from the human body to the ground.
7. The shoe sole cleaning and static electricity elimination device according to claim 1, characterized in that, It also includes a base, and the sole cleaning mechanism includes: The first water storage chamber is disposed within the base; A roller brush is rotatably mounted on the base, and the roller brush is located above the first water storage chamber; When the roller brush rotates, it causes the water in the first water storage chamber to rotate as well, in order to clean the soles of the shoes.
8. The shoe sole cleaning and static electricity elimination device according to claim 7, characterized in that, The base is provided with a frame, the front end of the frame is provided with a handrail, and the rear end of the frame extends above the static electricity elimination mechanism.
9. The shoe sole cleaning and static electricity elimination device according to claim 8, characterized in that, The front end of the frame is provided with at least one inlet sensor, which detects a human body entering the shoe sole cleaning mechanism to automatically control the rotation of the roller brush.
10. The shoe sole cleaning and static electricity elimination device according to claim 7, characterized in that, The first water storage chamber is equipped with a clean water inlet and a first wastewater outlet. The first water storage chamber is equipped with a liquid level detection device, which detects the water level in the first water storage chamber to automatically control water replenishment or drainage.
11. The shoe sole cleaning and static electricity elimination device according to claim 7, characterized in that, The air-drying mechanism includes: A draining board, installed on the base; and Multiple negative pressure fans are installed at the bottom of the drain plate to dry the soles of the shoes.
12. The shoe sole cleaning and static electricity elimination device according to claim 11, characterized in that, The base has a second water storage chamber at its rear end, which is located below the drain plate and is separated from the first water storage chamber.
13. The shoe sole cleaning and static electricity elimination device according to claim 12, characterized in that, The base is equipped with a drain button, which controls the discharge of sewage from the first water storage chamber and / or the second water storage chamber.