CN210472065U - A water squeezing device for foaming cotton head mop - Google Patents

Abstract

The utility model is mainly used for squeezing water of a foam cotton head mop, and the concrete scheme is that the water squeezing device for the foam cotton head mop comprises a cleaning barrel and a water squeezing groove arranged on the cleaning barrel through a squeezing frame, wherein the water squeezing groove is provided with an outlet for water to flow out, the cleaning barrel is internally provided with an independent clear water area and a sewage area, and the outlet of the water squeezing groove corresponds to the sewage area; the waste region is for receiving water from the outlet of the wringing receptacle. Compared with the prior art, the utility model has the advantages that the water squeezing device of the foam cotton head mop not only has simple structure and convenient use, but also can conveniently squeeze water, has better water squeezing effect and is convenient to process and use. Wherein, will clean bucket internal partitioning for independent clear water district and sewage district, can guarantee that the water of squeezing out of water tank can not pollute the water in the clear water district, improve the cleaning efficiency, reduce the frequency of clear water district water change, using water wisely.

Description

A water squeezing device for foaming cotton head mop

Technical Field

The utility model relates to a water squeezing device, in particular to a water squeezing device for a foam cotton head mop.

Background

The cleaning of the conventional foam cotton head mop is not limited by the barrel shape or structure of the mop, for example, the foam cotton head mop is folded or extruded by the structure of the foam cotton head mop to achieve the purpose of cleaning the foam cotton, or a squeezing roller is arranged on the mop, and the foam cotton head is squeezed and cleaned by the relative movement between the squeezing roller and the foam cotton head, but inevitably, the structure of the foam cotton head mop is more complicated, the weight is increased, and the defects of component failure and labor waste are easy to occur in the using process. However, the mop bucket which is used as a special cleaning and squeezing mop with a foaming cotton head in the prior art still has the following defects.

The utility model discloses a mop bucket of horizontal extrusion glued membrane mop is disclosed in the utility model application of publication number CN105769083A, title "the clean bucket of glued membrane mop", including being used for the abluent staving of glued membrane head, fixing the base on the staving, the base on be equipped with water squeezing device and drive arrangement, water squeezing device include water squeezing fixed plate, water squeezing fly leaf, guide rail connecting rod, the upper portion of base is equipped with the extension portion, is equipped with the guide rail groove in the extension portion, the guide rail connecting rod sets up on the guide rail groove, water squeezing fixed plate passes through the fixed plate seat to be fixed in the extension portion, water squeezing fly leaf passes through the movable plate seat to be fixed on the guide rail connecting rod, the glued membrane head is placed between water squeezing fixed plate and water squeezing fly leaf when dehydrating, drive arrangement drives water squeezing fly leaf through the guide rail connecting rod and moves the tight glued membrane head water squeezing to water squeezing fixed plate direction. However, in the mop bucket of the scheme, a plurality of parts participate in linkage, once a certain part fails or is damaged, the cleaning work of the collodion mop cannot be finished, the environment in the bucket is humid, the parts in the bucket are frequently stressed, the more the parts are, and the higher the probability of failure is.

SUMMERY OF THE UTILITY MODEL

The technical problem to be solved by the utility model is to provide a wringing device for a foam cotton head mop, which has simple and compact structure, rapid wringing, high wringing rate and easy processing.

The utility model provides a technical scheme that above-mentioned technical problem adopted does: a water squeezing device for a foam cotton head mop comprises a cleaning barrel and a squeezing frame positioned on the cleaning barrel, wherein a water squeezing groove is arranged on the squeezing frame, an outlet for water to flow out is formed in the water squeezing groove, an independent clear water area and a sewage area are arranged in the cleaning barrel, and the outlet of the water squeezing groove corresponds to the sewage area; the waste region is for receiving water from the outlet of the wringing receptacle.

Compared with the prior art, the utility model has the advantages that the water squeezing device of the foam cotton head mop not only has simple structure and convenient use, but also can conveniently squeeze water, has better water squeezing effect and is convenient to process and use. Wherein, will clean bucket internal partitioning for independent clear water district and sewage district, can guarantee that the water of squeezing out of water tank can not pollute the water in the clear water district, improve the cleaning efficiency, reduce the frequency of clear water district water change, using water wisely.

The outlet of the squeezing trough is connected to the upper part or the inner part of the sewage area through a channel. The water squeezing groove can be arranged at other positions, so that the space of the sewage area can not be temporarily used, and the opening size of the sewage area can be smaller than that of the water squeezing groove, so that the clear water area is guaranteed to have enough space to contain water, the cleaning efficiency is greatly improved, and the frequency of repeated cleaning is increased. The channel can be in a pipeline form or a diversion trench form, and only water flowing out of the outlet of the water squeezing trench needs to be introduced into the sewage area.

The clear water area and the sewage area of the cleaning bucket are separated by a partition board. Cut apart through the baffle, simple structure, it is with low costs, especially can process through once only fashioned injection moulding technique, greatly reduced manufacturing cost.

The clear water area and the sewage area of the cleaning barrel are separated by a partition plate, the squeezing frame is positioned on the inner wall of the sewage area and protrudes towards the inner side, or the squeezing frame is positioned at the bottom of the sewage area and protrudes from bottom to top; the water squeezing groove is positioned at the upper part of the squeezing frame. The squeezing frame is raised from the bottom of the sewage area, and the water squeezing groove is arranged at the upper part of the squeezing frame, so that dirty water can be prevented from splashing outside to a certain extent during water squeezing. Particularly, when the position of the wringing groove is lower than the opening position of the sewage area, the splashing of dirty water can be effectively prevented; if the water squeezing groove is positioned at the central position of the sewage area, the anti-splash effect can be further improved. In a similar way, the squeezing frame is positioned on the inner wall of the sewage area and is protruded towards the inner side, so that the anti-splash effect can be effectively improved.

The extruding frame and the cleaning barrel are integrally formed or separately formed. Wherein when crowded frame and cleaning barrel integrated into one piece, crowded basin and crowded frame can also be divided into integrated into one piece or components of a whole that can function independently shaping, when crowded frame and cleaning barrel components of a whole that can function independently shaping the same reason. In a comprehensive aspect, when the extrusion frame and the cleaning barrel, the water extrusion groove and the extrusion frame are integrally formed, only one set of die is needed, and the cleaning barrel from one set of die not only saves assembly, but also reduces production cost.

The outlet is a water squeezing hole, and the circumferential surface and at least part of the bottom surface of the water squeezing groove are provided with the water squeezing holes. Wherein, the water squeezing holes are arranged on at least part of the surface, and because of the existence of the at least two characters, the positions of the water squeezing holes mainly refer to the following three conditions: 1. the water squeezing holes are only positioned on the part of the peripheral surface; 2. the water squeezing holes are only positioned on the part where the bottom surface is positioned; 3. the water squeezing holes are positioned on the parts of the peripheral surface and the bottom surface at the same time.

In order to ensure better extrusion effect, the outlet is provided with a slot, the slot is arranged on the circumferential surface of the water extruding groove, and the bottom surface of the water extruding groove is provided with a convex point protruding upwards.

In order to enable the water squeezing groove to have a better water squeezing effect, the cross section of the water squeezing groove is gradually reduced from top to bottom. When the bottom surface of the foaming cotton head faces downwards and the whole body enters the water squeezing groove from top to bottom, the inner surface of the water squeezing groove is squeezed, and the squeezing deformation is increased in the downward movement process, so that the water squeezing effect is greatly improved, and the water squeezing is realized

Preferably, the bottom surface of the water squeezing groove is arc-shaped and protrudes upwards.

Wherein, be equipped with belt cleaning device in the clear water district, this belt cleaning device locates clear water district lateral wall or/and clear water district bottom. Can improve cleaning performance and efficiency to the cotton head of foaming through belt cleaning device, improve user's experience and feel.

One scheme of the cleaning device is as follows: the cleaning device is a scraper, and the surface of the scraper is convexly provided with bulges or/and bristles for scraping and brushing the surface of the foam cotton head. When the foaming cotton head is cleaned in the sewage area, the foaming cotton head is hung and brushed at the cleaning device, so that dirt adhered to the surface of the foaming cotton head is removed, and the cleaning efficiency is improved.

The other scheme of the cleaning device comprises the following steps: the cleaning device is a cleaning groove matched with the foam cotton head in size, and protrusions or/and bristles for scraping and brushing the surface of the foam cotton head are/is convexly arranged on the inner surface of the cleaning groove. The size of washing tank and the volume phase-match of foaming cotton head, through with foaming cotton head insert the washing tank in, then the arch or the brush hair on washing tank surface will scrape the brush to foaming cotton head surface to detach the filth of foaming cotton head surface adhesion, and then improve abluent efficiency.

The protrusions are convex strips or/and convex points. The convex strip or the convex point can effectively scrape and brush the surface of the foaming cotton head, and the cleaning efficiency is better than that of other structures.

The outlet is a water squeezing hole or a slot, and the water squeezing hole or the slot is arranged on the circumferential surface and at least part of the bottom surface of the water squeezing groove.

Wherein, the "at least partial surface of the peripheral surface and the bottom surface of the water squeezing groove" mainly refers to the following three conditions because of the existence of the "at least" two characters: 1. only the bottom surface is provided with a water squeezing hole or a slot; 2. only the peripheral surface is provided with water squeezing holes or slots; 3. the bottom surface and the peripheral surface are simultaneously provided with water squeezing holes or slots. The circumferential surface is a general term of the circumferential side surface of the water squeezing groove which is surrounded in the conventional sense, namely the circumferential surface is generally formed by surrounding side surfaces in four directions.

The cross section of the water squeezing groove is gradually reduced from top to bottom. When the bottom surface of the foaming cotton head faces downwards, the foaming cotton head integrally enters the water squeezing groove from top to bottom, the foaming cotton head is squeezed through the inner surface of the water squeezing groove, and the squeezing deformation is increased in the downward movement process, so that the water squeezing effect is greatly improved, and the water squeezing is more sufficient.

Drawings

Fig. 1 is a schematic structural diagram of a first embodiment of the present invention.

Fig. 2 is a schematic structural diagram of a second embodiment of the present invention.

Fig. 3 is a schematic structural diagram of a third embodiment of the present invention.

Fig. 4 is a schematic structural diagram of a fourth embodiment of the present invention.

Fig. 5 is a schematic structural view of a cleaning device according to an embodiment of the present invention.

Fig. 6 is a schematic structural view of a mop with a foam cotton head according to an embodiment of the present invention.

Fig. 7 is a schematic structural view of a fifth extruding frame according to an embodiment of the present invention.

Fig. 8 is a schematic structural view of another extrusion frame according to a fifth embodiment of the present invention.

The cleaning device comprises a cleaning barrel 1, a clean water area 11, a sewage area 12, a partition plate 13, a squeezing frame 2, a squeezing groove 3, a squeezing hole 31, a bottom surface 32, a side surface 33, a mop rod 61, a foaming cotton head 62, an iron clamp 63, a cleaning device 7, a scraping plate 71, a cleaning groove 72, a bulge 76 and bristles 75.

Detailed Description

The present invention will be described in further detail with reference to the following embodiments.

The first embodiment is as follows: as shown in fig. 1, the wringing device includes a cleaning bucket 1, the cleaning bucket 1 forms a space for containing water, the cleaning bucket 1 is a container with an opening and a closed bottom, and the container forms a space for containing water. The opening part of the cleaning barrel 1 is provided with a squeezing frame 2, the squeezing frame 2 is provided with a squeezing groove 3, the squeezing groove 3 is provided with an outlet for water to flow out, the space for containing water in the cleaning barrel 1 is divided into an independent clear water area 11 and a sewage area 12 through a partition plate 13, the outlet of the squeezing groove 3 corresponds to the sewage area 12, and the sewage area 12 is used for receiving the water from the outlet of the squeezing groove 3. The squeezing frame 2 is located above the shell 1, and is used for fixing the squeezing groove 3 and positioning the squeezing groove 3 at a position above the shell 1, an upward opening is arranged on the squeezing groove 3, and at least partial surfaces of the side surface 33, the end surface and the bottom surface 32 of the squeezing groove 3 are provided with squeezing holes 31. In this embodiment, a plurality of water squeezing holes 31 are uniformly spaced on the bottom surface of the water squeezing groove 3, the water squeezing holes 31 are provided on a part of the side surface 33, and as shown in the figure, a plurality of water squeezing holes 31 are uniformly spaced on a part of the side surface 33 close to the bottom surface 32. Wherein, the water squeezing holes 3 can be replaced by a slotted structure.

It should be pointed out that, crowded frame 2 and crowded water groove 3 in this embodiment are integrated into one piece, and cleaning barrel 1 is the enclosure space, and cleaning barrel 1 is equipped with ascending opening, and crowded frame 2 is located cleaning barrel 1's top to play the effect of the open-ended of sealed cleaning barrel 1, crowded water groove 3 communicates the space in the cleaning barrel 1 through the crowded hole 31 that is equipped with on it, and the water of extruding from crowded water groove 3 just flows into in cleaning barrel 1 through crowded hole 31.

Wherein, the size phase-match of the size of the cotton head 62 of foaming of crowded water groove 3 and foaming cotton head mop, in order to reach better crowded water effect, can extend more embodiments: the water squeezing groove 3 may be slightly smaller than the foam cotton head 62 so that the foam cotton head 62 can be inserted and squeeze the foam cotton head 62 through the peripheral surface; or may be in accordance with the foam tip 62; or slightly larger than the size of the foam cotton head 62; alternatively, the size of the squeezing trough 3 is larger than the size of the foam head 62, so that the foam head 62 is squeezed only against the bottom surface 32. For example, the size of the transverse cross section of the wringing slot 3 is gradually reduced. The side surfaces 33 of the water squeezing grooves 3 gradually get closer from top to bottom, and the end surfaces of the water squeezing grooves 3 are parallel to each other in this embodiment. Moreover, as can be understood by those skilled in the art, the end surface of the wringing slot 3 can also gradually get closer from top to bottom, so that the cross section at the opening of the wringing slot 3 is slightly larger than the foam cotton head 62, and the cross section at the bottom surface is slightly smaller than the foam cotton head 62, thereby further causing the squeezing effect on the foam cotton head 62.

Example two: as shown in fig. 2, the main difference from the first embodiment is that the dimensions of the clean water area 11 and the dirty water area 12 are not the same, wherein the dimensions of the dirty water area 12 are much smaller than those of the clean water area 11, so as to ensure that the clean water area 11 has enough space to contain clean water. Meanwhile, the part of the squeezing frame 2 is positioned above the clear water area 11, the water squeezing holes 31 of the water squeezing grooves 3 on the squeezing frame 2 are positioned above the sewage area 12, and at the moment, sewage flowing out of the water squeezing holes 31 directly enters the sewage area 12.

In addition, other schemes are developed in the embodiment. If the squeezing frame 2 is located above the clear water area 11, the squeezing holes 31 of the squeezing grooves 3 on the squeezing frame 2 are connected to the inside of the sewage area 12 through pipelines, and at the moment, sewage flowing out of the squeezing holes 31 also directly enters the sewage area 12. Here the pipe is a pipe interfacing with the wringing aperture 31, which is connected to the waste zone 12; further, the piping may be replaced with a guide passage (guide groove) for guiding the sewage flowing out of the squeeze hole 31 to the sewage area 12. The structure or trajectory of the pipe or the guiding channel can be chosen arbitrarily, even curved, according to the actual situation, as long as it is possible to achieve a guiding of the sewage into the sewage zone 12.

Example three: as shown in figure 3, the difference from the first embodiment is that a cleaning device 7 is further arranged in the clean water area 11, the cleaning device 7 comprises a scraping plate 71 arranged on the side wall of the clean water area and the bottom of the cleaning area, and the surface of the scraping plate 71 is convexly provided with bristles 76 for scraping the surface of the foaming cotton head 62. As shown in fig. 5, the bristles 76 may be replaced with protrusions 76, and may replace the blades 71 at the side walls, or the blades 71 at the bottom. The structure of the protrusion 76 in this embodiment is a bump, but it can also be a raised strip.

Furthermore, the scrapers 71 can be integrated with the side wall and the bottom of the clear water region 11, i.e. the bristles can be directly fixed to the side wall or the bottom of the clear water region 11.

Example four: as shown in fig. 4, the difference from the second embodiment is only that a cleaning device 7 is arranged in the clean water area, the cleaning device 7 is a cleaning groove 72 with a size matched with that of the foam cotton head 62, and bristles 75 for scraping the surface of the foam cotton head 62 are protruded from the inner surface of the cleaning groove 72. The bristles 75 can be replaced by protrusions 76, and can replace the scrapers 71 on the side walls or the scrapers 71 on the bottom. The structure of the protrusion 76 in this embodiment is a bump, but it can also be a raised strip.

Example five: as shown in fig. 7, the difference from the first embodiment is the position of the squeezing frame 2 on the cleaning bucket 1, the squeezing frame 2 is located at the bottom of the sewage area 12 and is raised from bottom to top, the squeezing groove 3 is located at a position lower than the opening position of the sewage area 12, and the squeezing groove 3 is located at the upper part of the squeezing frame 2. When the water is squeezed, the structure can effectively prevent a large amount of dirty water from splashing outside, and the position of the water squeezing groove 3 is lower than the opening position of the sewage area 12, so that the probability of splashing of the dirty water is greatly improved.

In addition, as shown in fig. 8, another structure of the trestle 2 exists. The squeezing frame 2 is positioned on the inner wall of the sewage area 12 and protrudes towards the inside of the sewage area 12, and the water squeezing groove 3 is positioned on the upper part of the squeezing frame 2. The squeezing frame 2 with the structure can further prevent dirty water from splashing.

In the above embodiments, as shown in fig. 6, the foam cotton head mop includes a mop rod 61 and a foam cotton head 62, the foam cotton head 62 and the mop rod 61 are rotatably engaged with each other through a rotating shaft, and the foam cotton head 62 can rotate relative to the mop rod 61 and rotate to a position parallel to the mop rod 61. In the state that mop pole 61 and the cotton head 62 of foaming are mutually perpendicular, put into this crowded water groove 3 with the cotton head 62 of foaming, through exerting decurrent pressure to mop pole 61, extrude the cotton head 62 of foaming downwards gradually, the water of extruding in the cotton head 62 of foaming flows into in the space below through crowded water hole 31 for the cotton head 62 of foaming is crowded futilely. The structure is simple and compact, the processing is convenient, and the water squeezing effect is good. In addition, the foam cotton head 62 is provided with an elongated iron clip 63, and the iron clip 63 is provided along the longitudinal direction of the foam cotton head 62 and fixed to the foam cotton head 62. When exerting pressure downwards through mop pole 61, pressure transmits earlier to iron clamp 63 on, because iron clamp 63 non-deformable, consequently the power of exerting on can evenly transmit foaming cotton head 62 to extrude fully each position of foaming cotton head 62, and then improve crowded water effect, be particularly suitable for the form of pushing down the formula crowded water and extrude.

Claims (10)

1. The utility model provides a water installation for cotton first mop of foaming, includes clean bucket, and is located the crowded frame on the clean bucket, is equipped with crowded basin on this crowded frame, and this crowded basin department is equipped with the export that supplies water to flow out, its characterized in that: the cleaning barrel is internally provided with a clear water area and a sewage area which are independent, and the outlet of the water squeezing groove corresponds to the sewage area; the waste region is for receiving water from the outlet of the wringing receptacle.

2. The wringing device for a foam cotton head mop of claim 1, wherein: the outlet of the water squeezing groove is connected to the upper part or the inner part of the sewage area through a channel.

3. The wringing device for a foam cotton head mop as claimed in claim 1 or 2, wherein: the clear water area and the sewage area of the cleaning barrel are separated by a partition plate.

4. The wringing device for a foam cotton head mop as claimed in claim 1 or 2, wherein: the squeezing frame is positioned on the inner wall of the sewage area and protrudes towards the inside, or the squeezing frame is positioned at the bottom of the sewage area and protrudes from bottom to top; the water squeezing groove is positioned at the upper part of the squeezing frame.

5. The wringing device for a foam cotton head mop as claimed in claim 1 or 2, wherein: the squeezing frame and the cleaning barrel are integrally formed or separately formed.

6. The wringing device for a foam cotton head mop of claim 1, wherein: and a cleaning device is arranged in the clear water area and is arranged on the side wall of the clear water area or/and the bottom of the clear water area.

7. The wringing device for a foam cotton head mop of claim 6, wherein: the cleaning device is a scraper, and the surface of the scraper is convexly provided with bulges or/and bristles for scraping and brushing the surface of the foam cotton head.

8. The wringing device for a foam cotton head mop of claim 6, wherein: the cleaning device is a cleaning groove matched with the foam cotton head in size, and protrusions or/and bristles used for scraping and brushing the surface of the foam cotton head are/is convexly arranged on the inner surface of the cleaning groove.

9. The wringing device for a foam cotton head mop of claim 7 or 8, wherein: the bulges are convex strips or/and convex points.

10. The wringing device for a foam cotton head mop of claim 1, wherein: the cross section of the water squeezing groove is gradually reduced from top to bottom.

Images