An online wringing mechanism based on a car-wiping device
By designing an online water-squeezing mechanism on the car wiping device, and utilizing a sealed liquid exchange zone to achieve the alternating replacement of clean water and wastewater, the problem of cleaning and water squeezing not being completed simultaneously during the wiping process is solved, thereby improving wiping efficiency and cleaning effect.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Patents(China)
- Current Assignee / Owner
- WUHAN WATER MAGIC CUBE INTELLIGENT TECH CO LTD
- Filing Date
- 2022-10-13
- Publication Date
- 2026-06-19
AI Technical Summary
Existing car washing devices cannot simultaneously clean and wring out water during the washing process, resulting in low washing efficiency.
Design an online water squeezing mechanism based on a car wiping device, including a first interference part that interferes axially with the surface of the car wiping roller and a sealing part to form a sealed liquid exchange zone. Through a water-guiding structure, the alternating replacement of clean water and wastewater is achieved to ensure the cleanliness of the car wiping roller surface.
It enables continuous drainage of wastewater during the car wiping process, avoiding stains after wiping and improving wiping efficiency and cleaning effect.
Smart Images

Figure CN115489485B_ABST
Abstract
Description
Technical Field
[0001] This invention relates to the field of vehicle cleaning technology, and more particularly to an online water-squeezing mechanism based on a car wiping device. Background Technology
[0002] Vehicles require regular washing; otherwise, dust easily accumulates on their surfaces, affecting their appearance. Currently, vehicles are cleaned in two ways: one is through professional car detailing shops, and the other is by the user using specialized tools. The former has drawbacks: it requires moving the vehicle to a detailing shop, takes a long time, is expensive, and uses a lot of water, which is not environmentally friendly. The latter, while cheaper, uses a significant amount of water, leading to waste, and is also more labor-intensive and prone to incomplete cleaning, failing to achieve the desired results.
[0003] Chinese patent CN201420322721.X discloses a split-type combined car wash machine, which solves the aforementioned problems of the prior art. It is an environmentally friendly, ultra-compact car wash machine that requires no water source, electric pump, water pipes, water tank, or spray gun, and is water-saving and energy-efficient. It includes a power control handle and separate sweeping and washing mechanisms. In use, the sweeping mechanism first cleans the surface of the car body of dust and sand, and then the washing mechanism cleans the surface of the car body to achieve a cleaning effect.
[0004] Existing car washing equipment typically requires wiping and cleaning to be done separately, resulting in low washing efficiency. Summary of the Invention
[0005] The main technical problem solved by this invention is to provide an online water squeezing mechanism based on a car wiping device, which can achieve cleaning simultaneously during the car wiping process, thereby improving the efficiency of vehicle washing.
[0006] To solve the above-mentioned technical problems, the present invention provides an online water squeezing mechanism based on a car wiping device. The online water squeezing mechanism based on the car wiping device includes a first interference portion that axially interferes with the surface of the car wiping roller. A fixing portion and a sealing portion are respectively provided on both sides of the first interference portion. The sealing portion, the first interference portion and the fixing portion are distributed along the circumference of the car wiping roller. The online water squeezing mechanism also includes a water guiding structure that contacts the surface of the car wiping roller. The water guiding structure cooperates with the sealing portion to form a sealed liquid exchange zone axially on the surface of the roller.
[0007] Furthermore, a V-shaped groove is formed between the sealing part and the fixing part on the side opposite to the first interference part.
[0008] Furthermore, a fixing plate is provided between the sealing part and the fixing part on the side opposite to the first interference part.
[0009] Furthermore, the sealing part is located on the side where the car wiping roller squeezes out the sewage, and the fixing part is located on the side where the car wiping roller has squeezed out all the sewage.
[0010] Furthermore, the online water-squeezing mechanism also includes a water-guiding structure that contacts the surface of the wiping roller.
[0011] Furthermore, the water intake section includes a contact section that contacts the surface of the wiping roller and a water storage section connected to the contact section. The water storage section cooperates with the sealing section to form a sealed liquid exchange zone axially on the roller surface.
[0012] Furthermore, the water storage section and the sealing section are arc-shaped.
[0013] Furthermore, the contact portion extends into the sealed liquid exchange zone.
[0014] Furthermore, the sealed liquid exchange zone is equipped with a clean water inlet and a wastewater outlet.
[0015] Furthermore, the clean water inlet and the wastewater outlet are located at opposite ends of the sealed liquid exchange zone.
[0016] Furthermore, the cross-section of the first interference portion is triangular.
[0017] This invention relates to an online water-squeezing mechanism for a car wiping device, comprising a first interference portion that axially interferes with the surface of the car wiping roller. A fixing portion and a sealing portion are respectively provided on both sides of the first interference portion. The sealing portion, the first interference portion, and the fixing portion are distributed circumferentially along the car wiping roller. The online water-squeezing mechanism also includes a water-guiding structure that contacts the surface of the car wiping roller. This water-guiding structure cooperates with the sealing portion to form a sealed liquid exchange zone axially on the roller surface. In use, the online water-squeezing mechanism can continuously squeeze the car wiping roller, carrying away debris such as dust through the discharged water. The squeezed-out liquid is wastewater. Since it is impossible to effectively squeeze out all the wastewater from the car wiping roller during the squeezing process, clean water is injected into the sealed liquid exchange zone to dilute the wastewater, making the liquid that can be absorbed by the roller surface in contact with the liquid exchange zone slightly cleaner. This keeps the surface of the car wiping roller clean and avoids the phenomenon of wiping without leaving stains after continuous wiping. Attached Figure Description
[0018] To more clearly illustrate the technical solutions in the embodiments of the present invention or the prior art, the drawings used in the description of the embodiments or the prior art will be briefly introduced below. Obviously, the drawings in the description only show some embodiments of the present invention, and therefore should not be regarded as a limitation of the scope. For those skilled in the art, other related drawings can be obtained based on these drawings without creative effort.
[0019] Figure 1 This is a cross-sectional view of an embodiment of an online water-squeezing mechanism based on a car-wiping device, taken along the vertical direction of the car-wiping roller axis.
[0020] Figure 2 This is a three-dimensional structural schematic diagram of an embodiment of an online water-squeezing mechanism based on a car-wiping device.
[0021] Figure 3 This is a front view of an embodiment of an online water-squeezing mechanism based on a car-wiping device.
[0022] Figure 4 for Figure 1 Schematic diagram of the structure exploded.
[0023] Figure 5 for Figure 2 Enlarged schematic diagram of section C.
[0024] Figure 6 This is a schematic diagram of another embodiment of an online water-squeezing mechanism based on a car-wiping device.
[0025] Figure 7 This is a schematic diagram of another embodiment of an online water-squeezing mechanism based on a car-wiping device.
[0026] Figure label:
[0027] 1. Cleaning roller; 2. Cleaning mechanism (water squeezing structure assembly); 3. Housing; 4. Sealed liquid exchange zone A; 5. Water outlet pipe; 6. Water return pipe; 7. Water return inlet; 8. Clean water inlet A1; 9. Wastewater outlet A2; 10. Water intake structure.
[0028] First interference part 20, arc-shaped protrusion 201, fixing part 21, sealing part 22, water squeezing structure 23, rib plate 25, shell cover snap-fit groove 25, mounting part 27.
[0029] Water intake bar 61
[0030] Extension 610, water intake 611, second interference section 6111, guide bar 612, inclined surface 6121, protrusion 6122, water storage section 614, straight section 616.
[0031] First fastener 62, gap 621, curved surface 623
[0032] Second fastener 63, third interference part 631;
[0033] The realization of the objective of this invention, its functional features and advantages will be further explained in conjunction with the embodiments and with reference to the accompanying drawings. Detailed Implementation
[0034] The claims of the present invention will be further described in detail below with reference to specific embodiments and accompanying drawings. Obviously, the described embodiments are only some embodiments of the present invention, and not all embodiments. Based on the embodiments of the present invention, all other embodiments obtained by those skilled in the art without creative effort are also within the scope of protection of the present invention.
[0035] It should be understood that, in the description of the embodiments of the present invention, all directional indicating terms, such as "up," "down," "left," "right," "front," and "back," indicate the orientation or positional relationship based on the orientation and positional relationship shown in the accompanying drawings or the orientation or positional relationship commonly used when the product is in use. These terms are merely for the purpose of simplifying the description of the present invention and do not explicitly or implicitly suggest that the device, element, or component referred to must have a specific orientation or specific orientational structure, and should not be construed as a limitation of the present invention. They are only used to explain the relative positional relationships and movements between the components shown in the accompanying drawings. When this specific orientation changes, the directional indication may also change accordingly.
[0036] Furthermore, in this invention, ordinal numbers such as "first" and "second" are used for distinguishing purposes only and should not be construed as indicating or implying their relative importance or implicitly indicating the number of technical features indicated. Thus, the features referred to as "first" and "second" may explicitly or implicitly include at least one of those technical features. In the description of this invention, "a plurality of" means at least two, i.e., two or more, unless otherwise explicitly defined; "at least one" means one or more.
[0037] In this invention, unless otherwise explicitly specified and limited, the terms "installation," "setting," "connection," "fixing," and "screw-in" should be interpreted broadly. For example, they can refer to a relatively fixed positional relationship between components, or a physically fixed connection between components; they can be detachable connections or integral structures; they can be mechanical connections or electrical signal connections; they can be direct connections or indirect connections through intermediate media or components; they can refer to the internal communication of two elements or the interaction between two elements. Unless otherwise explicitly limited in the specification, other interpretations will not achieve the corresponding functions or effects. For those skilled in the art, the specific meaning of the above terms in this invention can be understood according to the specific circumstances.
[0038] If the controllers or control circuits involved in this invention are conventional control technologies or units for those skilled in the art, such as the control circuits of the controllers, they can be implemented by those skilled in the art using existing methods, such as simple programming. Regarding software or programs that work with hardware to achieve control results, unless the description provides a detailed explanation of the control process of the software or programs involved, this pertains to the use of existing technology or conventional techniques for those skilled in the art. The power supply also employs existing technology in the art. Furthermore, since the main inventive aspect of this invention lies in the improvement of the mechanical device, this invention will not provide a detailed explanation of the specific circuit control relationships and circuit connections.
[0039] This invention discloses many different embodiments or examples for implementing different structures of the invention. To simplify the disclosure, specific examples of components and arrangements are described herein. Of course, these are merely examples and are not intended to limit the invention. Furthermore, reference numerals and / or letters may be repeated in different examples; such repetition is for simplification and clarity and does not in itself indicate a relationship between the various embodiments and / or arrangements discussed. In addition, examples of various specific processes and materials are provided in this invention, but those skilled in the art will recognize the application of other processes and / or the use of other materials.
[0040] The preferred embodiments of the present invention will be described below with reference to the accompanying drawings. It should be understood that the preferred embodiments described herein are for illustration and explanation only and are not intended to limit the present invention.
[0041] like Figures 1-5 As shown, the present invention provides an embodiment of an online water-squeezing mechanism based on a car wiping device.
[0042] like Figure 1 As shown, the online dewatering mechanism based on the car wiping device includes a dewatering structure assembly 2 that interferes axially with the surface of the car wiping roller 1. This assembly includes a first interference portion 20, a fixing portion 21 connected to both sides of the first interference portion, and a sealing portion 22. The sealing portion 22, the first interference portion 20, and the fixing portion 21 are distributed circumferentially along the car wiping roller 1. The online dewatering mechanism also includes a water-guiding structure 61 that contacts the surface of the car wiping roller 1 to form a water seal. The sealing portion 22 extends outward to form a mounting portion 27 with a straight mounting surface for fixing the water-guiding structure 21. The water-guiding structure 61 and the sealing portion 22 cooperate to form a sealed liquid exchange zone A axially on the surface of the roller 1. The fixing portion 21 can be fixed to the housing of the car wiping device. The water-guiding structure 61 can connect with the sealing portion 22 to form a water-sealed contact on the surface of the washing roller 1.
[0043] The online dewatering mechanism can be an integral structure. Although the online dewatering mechanism is implemented by multiple parts in the following embodiments, the component numbers and names involved in the following description are consistent with those of this embodiment. Alternatively, those skilled in the art can make simple modifications and expansions based on the following text description and drawings, all of which are within the protection scope of the technical solution disclosed in this embodiment.
[0044] As a further improved implementation, the online dewatering mechanism can also be implemented by multiple parts working together. When multiple separate parts work together, the processing and manufacturing difficulty of the cleaning mechanism can be reduced.
[0045] This embodiment uses an online dewatering mechanism as an example of a separating component structure for illustration.
[0046] like Figure 1 , Figure 4 As shown, specifically, the online squeezing mechanism refers to the entire assembly of all related components that can continuously squeeze the car wiping roller 1 and continuously discharge wastewater during the rotation of the car wiping roller 1.
[0047] like Figure 1 As shown, the first interference portion 20 interferes with the surface of the car-wiping roller 1, thus exerting a squeezing effect on the surface of the car-wiping roller 1 even when the surface of the car-wiping roller 1 is under certain deformation. The car-wiping roller 1 is typically a sponge roller, i.e., the surface has a layer of liquid-absorbing sponge and a bracket for fixing and supporting the sponge (not shown in the figure). A V-shaped groove 23 is formed between the sealing portion 22 and the fixing portion 21 on the side opposite to the first interference portion 20. The V-shaped groove 23 can reduce the weight of the water-squeezing structure assembly 2, making it more convenient to wash the vehicle. The cross-sectional shape of the first interference portion 20 is not limited. In this embodiment, it is set to have a triangular cross-section, which can reduce the contact area with the car-wiping roller 1 during squeezing, thereby reducing the rotational resistance of the car-wiping roller 1. The first interference portion 20 is used to squeeze the roller surface.
[0048] In practical engineering, since the water-squeezing structure component 2 is usually made of plastic, in order to maintain its strength requirements, a rib 25 is provided between the sealing part and the fixing part on the side opposite to the first interference part 20. A rib 25 is also provided on the back of the first interference part, connecting the sealing part 22 and the fixing part 21. In this embodiment, multiple ribs are provided, and each fixing plate 25 is arranged in parallel. The first interference part 20 has a V-shaped cross-section, which allows for the squeezing of the car wiping roller 1 while reducing the contact area with the roller 1, effectively reducing resistance during water squeezing.
[0049] like Figure 1 As shown, the sealing part 22 is located on the side of the car wiping roller 1 that squeezes out sewage, and the fixing part 21 is located on the side of the car wiping roller 1 that has squeezed out all the sewage.
[0050] like Figure 1 , Figure 4 , Figure 5 As shown, the water-squeezing structure assembly 2 also includes a water-guiding strip 61 that contacts the surface of the car-wiping roller 1. The water-guiding strip 61 includes a contact portion 611 that contacts the surface of the car-wiping roller 1 and a water-storing portion 614 connected to the contact portion 611. The water-storing portion 614 cooperates with the sealing portion 22 to form a sealed liquid exchange zone A axially on the roller surface 1. Since the direction is not constant during car wiping, to ensure that no liquid seeps out or leaks, the liquid exchange zone A must be set as a sealed structure.
[0051] To better understand the function of the sealed liquid exchange zone A, its working process will be explained in detail. For example... Figure 1 , Figure 4 As shown, when the car wiping roller 1 wipes the vehicle surface, it inevitably carries dust. When the wet car wiping roller 1 passes through the first interference section 20, the liquid inside the car wiping roller 1 is discharged or flows out. During the discharge or flow out process, dust and other debris are carried away from the surface of the car wiping roller 1. On the one hand, the first interference section 20 cannot completely squeeze out all the liquid on the car wiping roller 1 (not due to technical limitations, but because the car wiping roller 1 is usually a sponge roller, and to a certain extent it is unnecessary to completely squeeze the entire sponge roller dry in the non-squeezing area). On the other hand, excessive squeezing force would cause the car wiping roller 1 to have excessive resistance and become unable to work. In order to maintain a certain level of moisture and cleanliness of the adsorbed liquid in the car wiping roller 1, liquid is injected into the liquid exchange zone A to dilute the wastewater, ensuring that the cleanliness of the car wiping roller 1 before contact with the vehicle is greater than after contact. This can avoid the presence of stains after wiping during continuous wiping.
[0052] In this embodiment, the water-guiding structure 61 in the online water-squeezing mechanism is a separate component from other parts, but it can also be set as an integral structure as needed.
[0053] As needed, such as Figure 1 , Figure 4 As shown, the water storage section 614 and the sealing section 22 are arc-shaped. The contact section 611 extends into the sealed liquid exchange zone A, so that the wastewater discharged during the squeezing of the car cleaning roller 1 will not stagnate at the contact position with the surface of the car cleaning roller 1, and fine particles can be effectively settled. The water inlet section near the sealed liquid exchange zone A is in contact with the surface of the car cleaning roller 1, and a gap B1 is provided between the water inlet section away from the sealed liquid exchange zone A and the surface of the car cleaning roller 1. The sealed liquid exchange zone has an arc-shaped cross-section along its length perpendicular to the cross-section, and the arc shape includes a C-shape.
[0054] As a further improved implementation method, as needed, such as Figure 4As shown, the first interference part 20 has protrusions 201 at both ends. The extrusion force formed by the protrusions 201 on the surface of the car wiping roller 1 is less than or equal to that of the first interference part 20. The protrusions 201 can prevent the liquid on both sides of the car wiping roller 1 from seeping outward when squeezing water.
[0055] As a further improved implementation method, as needed, such as Figure 4 As shown in the figure, the protrusion 201 is not on the same straight line as the first interference portion 20 in the length direction. It is preferably extended into the sealed liquid exchange zone A, so that the squeezed liquid can be gathered in the middle and prevent leakage from both sides. The protrusion 201 is arc-shaped in the axial direction of the wiping roller 1. The arc-shaped protrusion 201 deviates from the axial arc direction of the wiping roller 1. The arc can be gradually changed in the direction of rotation of the wiping roller 1, either with or without the direction of rotation.
[0056] like Figure 4 , Figure 5 As shown, the water-guiding structure 61 includes a water-guiding part 611 in contact with the surface of the car-wiping roller 1, a water-storing part 614 connected to the water-guiding part, guide strips 612 that cause interference between the two ends of the car-wiping roller 1, and an extension part 610 with a first gap B1 between it and the surface of the car-wiping roller 1. The circumferential end of the water-guiding part 611 is provided with a second interference part 6111 that forms a water seal with the surface of the car-wiping roller 1. Guide strips 612 that cause interference between the two ends of the car-wiping roller 1 are provided at both ends of the length direction of the water-guiding part 611, that is, the guide strips 612 are in partial contact with the surface of the car-wiping roller 1. The inner side of the guide strip 612 is provided with an inclined surface 6121. The inclined surface 6121 has an arc-shaped structure. The arc-shaped structure design of the inclined surface 6121 can keep the contact pressure of each part when the inclined surface contacts the surface of the car-wiping roller 1 basically the same. The guide strip 612 extends towards the sealed liquid exchange zone A with protrusions 6122. These protrusions 6122, together with the first interference portion 20, the second interference portion 6111, the water storage portion 614, and the sealing portion 22, enclose the sealed liquid exchange zone A near the two ends of the car cleaning roller 1 on both sides of the sealed liquid exchange zone A. The water storage portion 614, the water intake portion 611, the guide strip 612, and the sealing portion 22 cooperate with the surface of the car cleaning roller 1 to form a complete sealed liquid exchange zone A. The extension portion 610 and the water intake portion 611 are located on both sides of the water storage portion 614. The water storage portion 614 and the sealing portion 22 are fixed by a waterproof connection.
[0057] As a further improved implementation, the second interference part 6111 can adopt a strip structure, and the contact surface formed between it and the surface of the car cleaning roller 1 is as small as possible. This can ensure that no leakage occurs from the second interference part 6111 during the water exchange process, while also reducing the rotational resistance of the car cleaning roller 1 during operation. In addition, it can effectively increase the gap length in the circumferential direction of the car cleaning roller 1, thereby increasing the pressure relief area.
[0058] As a further improved implementation method, such as Figure 5 , Figure 6 , Figure 7 As shown, the water-guiding structure 61 includes a water-guiding part 611 that contacts the surface of the car-wiping roller 1, a water-storing part 614 connected to the water-guiding part 611, and an extension part 610 with a first gap B1 between it and the surface of the car-wiping roller 1. The circumferential end of the water-guiding part 611 is provided with a second interference part 6111 that forms a watertight contact with the surface of the car-wiping roller 1. The water-guiding part 611 extends all the way to the end of the car-wiping device housing that clamps the car-wiping roller 1 from the top and bottom. This eliminates the need for the complex structure of guide strips 612 that extend at both ends of the water-guiding part 611 in the length direction to cause interference between the surfaces of the two ends of the car-wiping roller 1. This implementation can reduce the processing and manufacturing difficulty of the water-guiding structure 61.
[0059] like Figure 4 , Figure 5 As shown, the straight portion 616 of the water-guiding structure 61 has several through holes (not shown in the figure), and the top of the first fixing member 62 has several nut posts (not shown in the figure). The nut posts mate with the through holes. Then, by driving the fastening screws down through the mounting portion 27 of the water-squeezing structure assembly 2 through the top of the straight portion 616 of the water-guiding structure 61, the fastening screws can be driven into the nut posts on the top of the first fixing member 62, thereby realizing the installation of the large component of the water-squeezing structure assembly 2. Furthermore, the second fixing member 63 can be detachably connected to the first fixing member 62 by an interference fit through an opening at the bottom of the first fixing member 62 (not shown in the figure). To facilitate disassembly and assembly, a gap 621 is left between the second fixing member 63 and the first fixing member 62 so that the compressed air during the interference fit insertion process still has some space, improving the convenience of disassembly and assembly.
[0060] like Figure 4 , Figure 5As shown, in the middle of the online water-squeezing mechanism assembled by the water-guiding structure 61, the first fixing member 62, and the second fixing member 63, a pressure relief port 622 communicating with the air outlet 28 is provided. The main body of the pressure relief port 622 communicating with the air outlet 28 is located in the middle of the first fixing member 62. The side of the first fixing member 62 facing the surface of the car wiping roller 1 is an arc surface 623 with a similar curvature. The arc surface 623, the pressure relief port 622, and the surface of the car wiping roller 1 together form a second gap B2. The upper half of the pressure relief port 622 (not shown in the figure) is located in the middle of the water-guiding structure 61, and the lower half of the pressure relief port 622 (not shown in the figure) is located in the middle of the second fixing member 63. The two upper and lower half guide portions together form a complete guide portion of the pressure relief port 622 (not shown in the figure). The guide portion of the pressure relief port 622 can increase the air outlet area of the pressure relief port 622, further reduce the air outlet velocity, and at the same time make it more conducive to the exhaust air being evenly dispersed on the surface of the car washing roller 1, further reducing the noise generated by the car washing device during the pressure relief and exhaust process.
[0061] As a further improved implementation method, as needed, such as Figure 3 As shown, an exhaust pipe interface seat for connecting a pressure relief pipeline (not shown in the attached figure) is provided in the middle of the side of the first fixing member 62 facing away from the car wiping roller 1. The exhaust pipe interface seat has an air outlet 28 inside. When it is necessary to release the pressure accumulated inside the car wiping device, the pressure relief pipeline discharges air to the pressure relief chamber B through the air outlet 28 in the exhaust pipe interface seat. The pressure relief chamber B further releases the accumulated pressure, thereby realizing the release of the pressure accumulated inside the car wiping device.
[0062] like Figure 3 As shown, the cleaning fluid holding mechanism (not shown in the attached figure) of the car wiping device can deliver clean water and collect wastewater through an interface mechanism (not shown in the attached figure). Clean water is delivered to the clean water pipe 6 through the clean water outlet (not shown in the attached figure), and wastewater is collected in the wastewater pipe 7 through the wastewater return outlet (not shown in the attached figure). Figure 1To ensure continuous exchange of the sealed liquid exchange zone A during operation, it can be equipped with a clean water inlet A1 connected to the outlet pipe 61 and a wastewater outlet A2 connected to the return water inlet 71. The clean water inlet can be connected to the cleaning fluid container (not shown in the attached diagram) via a water pump (not shown in the diagram), and the wastewater outlet can also be connected to the wastewater container (not shown in the attached diagram) via a water pump. A conversion device (not shown in the attached diagram) can be provided between the wastewater container and the cleaning fluid container to convert wastewater into cleaning fluid, thus protecting the vehicle from continuous washing for extended periods. The cleaning fluid can include clean water, a mixture of clean water and cleaning fluid, or only cleaning fluid. The cleaning fluid inlet A1 and wastewater outlet A2 are located at opposite ends of the sealed liquid exchange zone A. This design, with the clean water inlet and wastewater outlet located at opposite ends of the sealed liquid exchange zone, improves the efficiency of the alternating replacement of wastewater in the squeezed-out cleaning rollers and clean water in the injected cleaning rollers.
[0063] As a further improved implementation, as needed, in the above embodiments, the cross-section of the first interference part 20 can be triangular, and the top of the three angles is a smooth arc structure. This can reduce the resistance generated by the large contact surface during interference, and at the same time reduce the frictional wear on the wiping roller 1, thus extending its service life.
[0064] During use, the online squeezing mechanism continuously squeezes the car wiping roller, carrying away debris such as dust through the discharged water. The squeezed-out liquid is wastewater. Since it is impossible to effectively squeeze out all the wastewater from the car wiping roller during the squeezing process, clean water is injected into the sealed liquid exchange area to dilute the wastewater, making the liquid that can be absorbed by the roller surface in contact with the liquid exchange area slightly cleaner. This keeps the surface of the car wiping roller clean and avoids the phenomenon of wiping without leaving any stains after continuous wiping.
[0065] The above embodiments are only used to illustrate the technical solutions of the present invention, and are not intended to limit it. Although the present invention has been described in detail with reference to the foregoing embodiments, those skilled in the art should understand that modifications can still be made to the technical solutions described in the foregoing embodiments, or equivalent substitutions can be made to some of the technical features. Such modifications or substitutions do not cause the essence of the corresponding technical solutions to deviate from the spirit and scope of the technical solutions of the embodiments of the present invention.
Claims
1. An online wringing mechanism based on a car-wiping device, characterized in that, include: The first interference section interferes axially with the surface of the car wiping roller. A fixing part and a sealing part are respectively provided on both sides of the first interference section. The sealing part, the first interference section, and the fixing part are distributed along the circumference of the car wiping roller. The water-guiding structure, in conjunction with the sealing part, forms a sealed liquid exchange zone axially on the drum surface, including: The water inlet section contacts the surface of the car wiping roller, and guide strips are provided at both ends of its length to cause interference between the surfaces of the two ends of the car wiping roller; The water storage section connects to the water intake section; The extension has a gap between it and the surface of the car wiping roller; The water storage section, water intake section, guide strip, sealing section, and the surface of the wiping roller work together to form a complete sealed liquid exchange zone.
2. The online water-squeezing mechanism based on the car-wiping device according to claim 1, characterized in that, The circumferential end of the water intake section is provided with a second interference section that forms a water seal contact with the surface of the car wiping roller.
3. The online water-squeezing mechanism based on the car-wiping device according to claim 2, characterized in that, The inner side of the guide bar is set as a slope, and the slope is an arc structure.
4. The online water-squeezing mechanism based on the car-wiping device according to claim 2, characterized in that, The guide bar extends toward the sealed liquid exchange area with protrusions. These protrusions, together with the first interference part, the second interference part, the water storage part, and the sealing part, enclose the portion of the sealed liquid exchange area near the two ends of the wiping roller.
5. The online water-squeezing mechanism based on the car-wiping device according to claim 1, characterized in that, The extension and the water intake are located on both sides of the water storage section, and the water storage section and the sealing section are fixed together with a waterproof connection.
6. The online water-squeezing mechanism based on the car-wiping device according to claim 1, characterized in that, A V-shaped groove is formed between the sealing part and the fixing part on the side opposite to the first interference part, and a fixing plate is provided between the sealing part and the fixing part on the side opposite to the first interference part.
7. The online water-squeezing mechanism based on the car-wiping device according to claim 1, characterized in that, The water-introducing structure contacts the surface of the car wiping roller and cooperates with the sealing part to form a sealed liquid exchange zone axially on the roller surface; the sealing part is located on the side of the car wiping roller that squeezes out sewage, and the fixing part is located on the side of the car wiping roller that has squeezed out all the sewage; the water-introducing part includes a contact part that contacts the surface of the car wiping roller and a water storage part connected to the contact part, and the water storage part cooperates with the sealing part to form a sealed liquid exchange zone axially on the roller surface.
8. The online water-squeezing mechanism based on the car-wiping device according to claim 7, characterized in that, The water storage section and the sealing section are arc-shaped.
9. The online water-squeezing mechanism based on the car-wiping device according to claim 7, characterized in that, The contact portion may extend into the sealed liquid exchange zone; or the sealed liquid exchange zone may be provided with a clean water inlet and a wastewater outlet.
10. The online water-squeezing mechanism based on the car-wiping device according to claim 8, characterized in that, The clean water inlet and the wastewater outlet are located at opposite ends of the sealed liquid exchange zone; or, the cross-section of the first interference section is triangular.