CN212307745U - Water squeezing device, foam cotton mop and cleaning tool - Google Patents

Abstract

A water squeezing device for a foam cotton mop comprises a water squeezing frame with a squeezing port, wherein a squeezing part is arranged in the squeezing port; the method is characterized in that: the foaming cotton squeezing device is characterized in that the squeezing parts are arranged in two groups and are oppositely arranged at left and right intervals, a squeezing channel for squeezing the left and right sides of the foaming cotton along the length direction of the foaming cotton can be formed between the two squeezing parts, the squeezing parts are provided with a first end and a second end which is relatively far away from the first end in the axial direction, the first end is directly or indirectly hinged in the squeezing frame, the second end is restrained in the squeezing frame and can swing up and down, and a limiting structure for limiting the upper swing amplitude or the lower swing amplitude of the second end is arranged in the squeezing frame. The extrusion part is a swing center which is one end part in the axial direction, the other end part of the extrusion part in the axial direction can swing up and down to realize swing, and after the extrusion part swings, the extrusion part can fully avoid foamed cotton, so that the mop head can easily pass through the extrusion opening. The utility model discloses still relate to a foam cotton mop and burnisher.

Description

Water squeezing device, foam cotton mop and cleaning tool

Technical Field

The utility model relates to a foam cotton is crowded water installation and burnisher for mop, wherein the foam cotton can be collodion head, sponge head or analog.

Background

The collodion mop structure on the existing market is roughly the same, including the mop pole, the mop head and crowded water mechanism, crowded water installation in the collodion mop is exactly a transmission structure, crowded water installation includes the handle of pulling, the pull rod, calliper seat (crowded frame), the collodion presss from both sides and crowded water stick, calliper seat roughly is the U-shaped, the collodion is pressed from both sides the centre gripping by the collodion, the collodion presss from both sides and fixes in the pull rod bottom, the top and the handle of pull rod are in the same place to middle part activity pin joint, the rear end of handle of pulling then pin joint is on the mop pole, crowded water stick is oblate, its both ends pin joint is at the lower extreme of calliper seat. When the squeezing operation is performed, the pulling handle is pulled to drive the collodion head to move up horizontally through the pulling rod, the collodion head passes through the squeezing rods of the squeezing frame, and the collodion head of the squeezing rod can be clamped by the squeezing rods to achieve squeezing because the squeezing rods have elasticity which keeps the clamping trend. The squeezing device is arranged on the collodion mop, so that the mop is heavy in weight, the mop head needs to be arranged in the water tank for cleaning during cleaning, and then the mop head is squeezed by the squeezing device arranged on the mop rod, so that the mop needs to be cleaned by the specific water tank. Because of the particularity of the structure of the squeezing frame, the collodion head and the mop rod must be fixedly connected, the collodion head cannot be completely separated from the squeezing frame, the collodion head cannot rotate relative to the mop rod, when the mop is used for mopping, the mop is inconvenient to drag in specific occasions such as corners, and the adaptability of mopping is poor. When the collodion mop is stored, the length direction of the collodion head is perpendicular to the axial direction of the mop rod, so that the space for storing the collodion mop is large, the collodion mop is inconvenient to store, the packing box of the existing collodion mop is large in size, the collodion mop placed in the same space is small, and the transportation cost is increased.

Therefore, the invention is specially directed to a cleaning barrel of a collodion mop, for example, Chinese patent application No. CN201710920255.3 discloses similar patents in the cleaning barrel and the collodion mop for cleaning the collodion mop, Chinese patent application No. CN201811267670.4 discloses a collodion mop squeezing barrel, and the like. A squeezing device is arranged on the barrel body, and a squeezing part in the squeezing device only squeezes the bottom surface of the foaming cotton head. The foam cotton head is deformed in a single side, the deformation amount needs to be large to ensure the squeezing effect, so the resistance is large during squeezing operation, and the width dimension of the foam cotton head is larger than the thickness dimension, so the length of a squeezing part squeezed from the bottom surface is long, and the resistance is large during squeezing operation.

SUMMERY OF THE UTILITY MODEL

The utility model aims to solve the technical problem that a foam cotton mop that novel structure, crowded water laborsaving operation, extrusion part can fully swing and realize stepping down is provided to above-mentioned prior art current situation with crowded water installation, this crowded water installation can be used in on the cotton mop of crowded water foaming certainly, can also be used in the mop bucket.

The utility model provides a technical scheme that above-mentioned technical problem adopted does: a water squeezing device for a foam cotton mop comprises a water squeezing frame with a squeezing port, wherein a squeezing part is arranged in the squeezing port; the method is characterized in that: the left and right sides of the extrusion parts are arranged in a pair at intervals, a squeezing channel for squeezing the left and right sides of the foamed cotton along the length direction of the foamed cotton can be formed between the two extrusion parts, the direction in which the thicknesses of the extrusion parts and the left and right sides of the foamed cotton are in the same direction is the axial direction, and the extrusion parts can generate displacement in the axial direction.

Preferably, the pressing member swings up and down about a fulcrum in the axial direction as a rotation center to generate the displacement. Of course, displacement may also be produced by horizontal sliding. The fulcrum is not necessarily collinear with the central axis of the pressing member.

As an improvement, a limiting structure for limiting the upward or downward swinging amplitude of the extrusion part is arranged in the water extrusion frame. When the extrusion part is limited by the limiting structure, the extrusion part can not swing any more to form a fixed extrusion channel, and the foaming cotton can only be squeezed through the extrusion channel, so that the squeezing effect is good.

Preferably, the squeezing component is provided with a first end and a second end which is relatively far away from the first end in the axial direction, the first end is directly or indirectly hinged in the squeezing frame, the second end is restrained in the squeezing frame and can swing up and down, and a limiting structure which limits the upper swing amplitude or the lower swing amplitude of the second end is arranged in the squeezing frame.

The further improvement still includes the elastic component that makes the second end of extrusion part keep towards the trend of rocking of limiting structure direction. The elastic piece ensures that the squeezing component can be timely reset to the initial state position, and when the mop head moves down or moves up to enable the squeezing component to be separated from the foaming cotton, the squeezing component is timely reset to the initial state, so that the normal operation of moving up or down and squeezing water is ensured.

Preferably, the squeezing component is a squeezing roller capable of rotating around the axis of the squeezing component, the squeezing roller can roll and form rolling squeezing with the foamed cotton, the foamed cotton is not easy to damage, the squeezing roller can select a roller with a larger diameter, and thus a guide angle can be formed between the squeezing roller and the two squeezing rollers, so that the mop head can easily enter the squeezing opening, and the foamed cotton mop can be lifted or pressed more easily. Two sides of squeeze roll are equipped with the axial region of two outside extensions respectively, and the axial region of both sides forms respectively first end and second end, first end articulates in crowded water frame through the swing piece, the inner wall department of crowded water frame is equipped with opening guide way down or opening up, the second end can be in the guide way luffing motion, the guide way form limit structure. The first end is hinged with the wringing frame through the swinging block to facilitate assembly, the swinging stroke of the extruding component is prolonged, the extruding component can leave the left side surface and the right side surface of the foam cotton through swinging at a small angle, and the rotation of the extruding component around the axis of the extruding component can not be influenced. Of course, if the pressing member is a non-rotatable pressing block, the pressing member may be directly hinged to the wringing rack.

Preferably, the first end of the pressing component is inserted and matched at the lower end of the swinging block and can rotate around the axis of the swinging block, and the upper end of the swinging block is hinged on the mounting block of the water squeezing frame through a hinge shaft. The elastic part can be a torsion spring, and is sleeved on the hinged shaft.

Of course, the limiting structure is also a stop block for limiting the swing angle of the swing block, and the limit of the lower swing position of the second end is realized by limiting the swing angle of the swing block. The limiting structure can also be matched with the limiting structure for use.

The second technical problem to be solved by the utility model is to provide a foam cotton mop with labor-saving squeezing operation.

The utility model provides a foaming cotton mop, includes clean bucket, mop pole and rotates to be connected at mop head that has the foaming cotton of mop pole lower extreme, its characterized in that: the mop water squeezing device also comprises the water squeezing device, and a water squeezing frame in the water squeezing device is sleeved on the mop rod and can slide up and down. The foam cotton mop is a self-squeezing mop.

The third technical problem to be solved by the utility model is to provide a cleaning tool which is labor-saving in squeezing operation,

the utility model provides a technical scheme that above-mentioned technical problem adopted does: the utility model provides a cleaning tool, includes the mop head that has the foaming cotton of clean bucket and rotation connection at mop pole lower extreme, its characterized in that: the upper part of the cleaning barrel is provided with the water squeezing device.

The two limiting modes respectively play different roles.

If the limit structure limits the upward swinging amplitude of the second end, the mop head rotates to be aligned with the extrusion opening, then the mop head is pressed downwards to enter the extrusion opening, the extrusion component is pushed by the mop head to enable the second end to swing downwards, and the foamed cotton does not pass through the water squeezing channel; when the mop head moves upwards to enter the extrusion opening, the second end is limited by the limiting structure, and the foaming cotton is squeezed through the squeezing channel. The cleaning tool has the advantages that the squeezing component fully yields in the downward moving process relative to the water squeezing frame, the downward moving is very easy, the upward moving process is squeezing, and the squeezing effect is good. This approach is suitable for the wringing region to exist independently.

If the limiting structure limits the downward swinging amplitude of the second end, the mop head rotates to be aligned with the extrusion opening, then the second end is limited by the limiting structure in the process of pressing down into the extrusion opening, and the foamed cotton is squeezed through the squeezing channel; when the mop head moves upwards into the squeezing opening, the squeezing component is pushed by the mop head to enable the second end to swing upwards, and the foaming cotton does not pass through the squeezing channel. The cleaning tool is wringing in the downward moving process relative to the wringing frame, the wringing effect is good, the squeezing component is fully abducted in the upward moving process, and the upward moving is very easy. This configuration allows for wringing cleaning in one area.

The cleaning barrel is divided into two independent areas, the wringing rack is positioned above one area, a cleaning rack is arranged above the other area, the cleaning rack is provided with a cleaning opening, and a cleaning part is arranged in the cleaning opening; the cleaning parts are arranged in two groups and are arranged in a left-right interval in an opposite mode, the mop head rotates to be aligned with the cleaning opening during cleaning, then the mop head enters the cleaning opening, and the left side and the right side of the foam cotton are cleaned by the arranged cleaning parts along the length direction of the foam cotton.

The cleaning frame and the water squeezing frame are integrally formed together.

Compared with the prior art, the utility model has the advantages of: the squeezing parts in the squeezing device are arranged in two groups at left and right intervals in a butt mode, the left side and the right side of the foaming cotton are squeezed by the squeezing parts arranged in the right and left sides along the length direction of the foaming cotton, the contact distance between the squeezing parts and the foaming cotton is short because the thickness dimension of the foaming cotton is smaller than the width dimension, squeezing resistance is small, and the squeezing resistance can be smaller in the double-side squeezing mode compared with the single-side squeezing mode. And the extrusion part adopts brand-new swing form, and it changes the tradition and lets the extrusion part along the mode of axial direction whole swing (the axial direction of extrusion part keeps parallel displacement all the time in the swing in-process), can produce the displacement in the axial direction through the extrusion part, wherein the extrusion part is the axial direction with the thickness syntropy direction of the cotton left and right sides of foaming, and this makes the extrusion part axial produce the displacement back, and the extrusion part can fully dodge the foaming cotton for the light of mop head passes through the extrusion mouth.

Drawings

FIG. 1 is a schematic back perspective view of a first embodiment of a wringing device (with a squeezing member in a wringing position);

FIG. 2 is a schematic back perspective view of a first embodiment of the wringing device (with the squeezing member in an out-of-position);

FIG. 3 is a sectional view of a first embodiment of the wringing device (with the pressing member in a wringing position);

FIG. 4 is a sectional view of the first embodiment of the wringing device (with the pressing member in the wringing position);

FIG. 5 is an exploded perspective view of the first embodiment of the wringing device;

FIG. 6 is a schematic perspective view of a second embodiment of the wringing device (with the pressing member in the wringing position);

FIG. 7 is a schematic perspective view of a second embodiment of the wringing device (with the squeezing members in an out-of-position);

FIG. 8 is an exploded perspective view of a second embodiment of the wringing device;

FIG. 9 is a perspective view of a first embodiment of a cleaning implement;

FIG. 10 is a perspective, cross-sectional view of a first embodiment of a cleaning implement;

FIG. 11 is a perspective view of a second embodiment of a cleaning implement;

FIG. 12 is a schematic perspective view of an embodiment of a foam mop;

fig. 13 is a schematic perspective structure view of a water squeezing device in an embodiment of the foam cotton mop.

Detailed Description

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

As shown in FIGS. 1 to 5, a first embodiment of the wringing device is shown.

A water squeezing device for a foam cotton mop comprises a water squeezing frame 5 with a squeezing opening 51, wherein a squeezing part 6 is arranged in the squeezing opening 51. The two squeezing parts 6 are arranged in a left-right spaced manner, a squeezing channel P for squeezing the left and right sides of the foam cotton 4 along the length direction L of the foam cotton 4 can be formed between the two squeezing parts 6, the direction in which the squeezing parts 6 are in the same direction as the thickness D of the left and right sides of the foam cotton 4 is the axial direction X, the squeezing parts 6 can generate a displacement X 'in the axial direction, and in the embodiment, the squeezing parts 6 can swing up and down to generate the displacement X' by taking a fulcrum in the axial direction as a rotation center.

Specifically, the squeezing component 6 is provided with a first end 61 and a second end 62 which is relatively far away from the first end 61 in the axial direction X, the first end 61 is directly or indirectly hinged in the wringing frame 5, the second end 62 is constrained in the wringing frame 5 and can swing up and down, and a limiting structure which limits the swing amplitude of the second end 62 is arranged in the wringing frame 5.

The second end 62 of the pressing member 6 is kept in the form of an elastic member 7 which tends to swing upward. The squeezing component 6 is a squeezing roller capable of rotating around the axis of the squeezing roller, two side faces of the squeezing roller are respectively provided with two shaft parts extending outwards, the shaft parts on two sides respectively form a first end 61 and a second end 62, the first end 61 is hinged in the water squeezing frame 5 through the swinging block 8, the inner wall of the water squeezing frame 5 is provided with a guide groove 52 with a downward opening, the second end 62 can swing up and down in the guide groove 52, and the guide groove 52 forms the limiting structure. The first end 61 of the extrusion component 6 is inserted and matched at the lower end of the swinging block 8 and can rotate around the axis of the first end 61, the first end 61 of the extrusion component 6 can also be integrally fixed with the swinging block 8, the upper end of the swinging block 8 is hinged on the mounting block 53 of the wringing frame 5 through a hinge shaft 81, the elastic component 7 is a torsion spring, and the hinge shaft 81 is sleeved with the elastic component.

The limiting structure can also be a stop 9 for limiting the swing angle of the swing block 8, and the limit of the swing position on the second end 62 is realized by limiting the swing angle of the swing block 8. The limiting structure can also be matched with the limiting structure for use.

The working process and the principle of the wringing device are as follows:

the mop head 3 is rotated to a position substantially parallel to the mop rod 2, the mop head is aligned to move downwards through the water squeezing port 51, after the foam cotton 4 on the mop head 3 touches the squeezing component 6, the squeezing component 6 is driven to overcome the elasticity of the elastic component 7 and swing along the swing block 8, namely, the second end 62 of the squeezing component 6 moves downwards along the guide groove 52, the second end 62 is separated downwards from the guide groove 52, in the process, the squeezing component 6 is in a swing position, as shown in fig. 6, the squeezing force of the squeezing component 6 on the foam cotton 4 is very small, the water is not squeezed basically, and the mop head 3 moves downwards very easily.

As shown in fig. 5, the mop head 3 moves upward relative to the water squeezing opening 51, at this time, the squeezing members 6 are always in the initial position and are limited to be unable to swing, the foam cotton 4 can only pass through the water squeezing channel P between the two squeezing members 6, the width of the water squeezing channel P is far smaller than the width of the foam cotton 4, and the squeezing members 6 move upward along the length direction L of the foam cotton 4 to squeeze the left and right sides of the foam cotton 4.

The water squeezing device can be arranged on the mop bucket or on the mop rod to become a self-squeezing mop.

As shown in FIGS. 6 to 8, a second embodiment of the wringing device is shown.

A water squeezing device for a foam cotton mop comprises a water squeezing frame 5 with a squeezing opening 51, wherein a squeezing part 6 is arranged in the squeezing opening 51. The squeezing component 6 has two sets ofly and control the interval and to establishing, can form between two squeezing components 6 and carry out the crowded water passageway P of crowded water to the left and right sides of foaming cotton 4 along the length direction L of foaming cotton 4, the squeezing component 6 is axial direction X with the thickness D syntropy direction of the foaming cotton 4 left and right sides, squeezing component 6 has first end 61 and the second end 62 of keeping away from relatively on axial direction X, first end 61 directly or indirectly articulates in crowded water frame 5, second end 62 retrains and can the luffing motion in crowded water frame 5, be equipped with in crowded water frame 5 and carry out spacing limit structure to second end 62 lower hem range.

The second end 62 of the pressing member 6 is kept by the elastic member 7 which tends to swing downward. The squeezing component 6 is a squeezing roller capable of rotating around the axis of the squeezing roller, two side faces of the squeezing roller are respectively provided with two shaft parts extending outwards, the shaft parts on two sides respectively form a first end 61 and a second end 62, the first end 61 is hinged in the water squeezing frame 5 through the swinging block 8, the inner wall of the water squeezing frame 5 is provided with a guide groove 52 with an upward opening, the second end 62 can slide up and down in the guide groove 52, and the guide groove 52 forms the limiting structure. The first end 61 of the extrusion component 6 is inserted and matched at the lower end of the swinging block 8 and can rotate around the axis of the first end, the upper end of the swinging block 8 is hinged on the installation block 53 of the wringing frame 5 through a hinge shaft 81, the elastic component 7 is a torsion spring, and the hinge shaft 81 is sleeved with the elastic component.

The working process of this embodiment is just the reverse of the first embodiment.

Fig. 9 and 10 show a first embodiment of the cleaning tool of the present invention.

A cleaning tool comprises a cleaning barrel 1 and a mop head 3 which is rotatably connected to the lower end of a mop rod 2 and is provided with foaming cotton 4, wherein the upper part of the cleaning barrel 1 is provided with a water squeezing device according to the first embodiment.

The cleaning barrel is divided into two independent areas, the wringing frame 5 is positioned above one area, the cleaning frame 10 is arranged above the other area, and the cleaning frame 10 and the wringing frame 5 are integrally formed together in the embodiment. The cleaning frame 10 is provided with a cleaning opening 101, and a cleaning part 11 is arranged in the cleaning opening 101; two groups of cleaning components 11 are arranged in a left-right interval in an opposite mode, the mop head 3 rotates to be aligned with the cleaning opening 101 during cleaning, then the mop head enters the cleaning opening 101, and the left side and the right side of the foam cotton 4 are cleaned by the cleaning components 11 arranged along the length direction L of the foam cotton 4.

Of course the cleaning bucket may have only one cleaning area as shown.

The working process and the principle of the wringing device are as follows:

as shown in fig. 5, during squeezing, the mop head 3 is rotated to a position substantially parallel to the mop rod 2, and moves down through the squeezing port 51 in alignment, the mop head 3 moves up relative to the squeezing port 51, at this time, the squeezing members 6 are always at the initial position and are limited to be unable to swing, the foam cotton 4 can only pass through the squeezing channel P between the two squeezing members 6, the width of the squeezing channel P is far smaller than the width of the foam cotton 4, and the squeezing members 6 move down along the length direction L of the foam cotton 4 to squeeze the left and right sides of the foam cotton 4.

As shown in fig. 5, the mop head 3 swings upward relative to the water squeezing opening 51, after the foam cotton 4 on the mop head 3 touches the squeezing member 6, the squeezing member 6 is driven to swing along the swing block 8 against the elastic force of the elastic member 7, i.e., the second end 62 of the squeezing member 6 moves upward along the guide groove 52, the second end 62 is separated upward from the guide groove 52, during this process, the squeezing member 6 is in a swing position, the squeezing force of the squeezing member 6 on the foam cotton 4 is very small, the water is not squeezed basically, and the mop head 3 moves upward very easily.

Fig. 11 shows a second embodiment of the cleaning implement of the present invention.

The present embodiment is different from the first embodiment in that: the upper part of the cleaning barrel 1 is provided with the wringing device of the second embodiment.

Fig. 12 and 13 show an example of the foam mop of the present invention.

A foam cotton mop comprises a cleaning barrel 1, a mop rod 2 and a mop head 3 which is rotatably connected to the lower end of the mop rod 2 and is provided with foam cotton 4.

The mop squeezing device further comprises a squeezing device as described in the previous embodiment 1 or embodiment 2, wherein a squeezing frame 5 in the squeezing device is sleeved on the mop rod 2 and can slide up and down.

It should be noted that in the description of the present embodiment, the terms "front, back", "left, right", "up, down", etc. indicate the orientation or positional relationship based on the orientation or positional relationship shown in the drawings, which is only for convenience of description of the present invention and simplification of description, but does not indicate or imply that the device or element referred to must have a specific orientation, be constructed in a specific orientation, and be operated, and thus, should not be construed as limiting the present invention. The terms "mounted," "connected," and "coupled" are to be construed broadly and may, for example, be fixedly coupled, detachably coupled, or integrally coupled; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meaning of the above terms in the present invention can be understood in specific cases to those skilled in the art.

Claims (14)

1. A water squeezing device for a foam cotton mop comprises a water squeezing frame (5) with a squeezing opening (51), wherein a squeezing part (6) is arranged in the squeezing opening (51); the method is characterized in that: the utility model discloses a foam cotton extrusion device, including extrusion part (6), can form between extrusion part (6) along the length direction (L) of foam cotton (4) about to establish, squeeze the crowded water passageway (P) of crowded water to the left and right sides of foam cotton (4), the direction of extrusion part (6) and the thickness (D) syntropy of the foam cotton (4) left and right sides is axial direction (X), and extrusion part (6) can produce displacement (X') in axial direction.

2. The wringing device for a foam cotton mop according to claim 1, wherein: the pressing member (6) swings up and down with a fulcrum in the axial direction as a rotation center to generate the displacement (X').

3. The wringing device for a foam cotton mop according to claim 2, wherein: and a limiting structure for limiting the upward or downward swinging amplitude of the extrusion component (6) is arranged in the water extrusion frame (5).

4. The wringing device for a foam cotton mop according to claim 3, wherein: the squeezing component (6) is provided with a first end (61) and a second end (62) which is relatively far away from the first end (61) in the axial direction (X), the first end (61) is directly or indirectly hinged in the wringing frame (5), the second end (62) is constrained in the wringing frame (5) and can swing up and down, and the limiting structure limits the upward swing amplitude or the downward swing amplitude of the second end (62).

5. The wringing device for a foam cotton mop according to claim 3, wherein: the pressing device also comprises an elastic element (7) which enables the second end (62) of the pressing component (6) to keep swinging trend towards the direction close to the limiting structure.

6. The wringing device for a foam cotton mop according to claim 4, wherein: extrusion part (6) are the squeeze roll that can be rotatory around self axis, and two sides of squeeze roll are equipped with the axial region that two outside extend respectively, and the axial region of both sides forms respectively first end (61) and second end (62), first end (61) articulate in crowded water frame (5) through swing piece (8), the inner wall department of crowded water frame (5) is equipped with opening guide way (52) down or opening up, second end (62) can slide from top to bottom in guide way (52), guide way (52) form limit structure.

7. The wringing device for a foam cotton mop according to claim 5, wherein: the first end (61) of the extrusion component (6) is inserted and matched at the lower end of the swinging block (8) and can rotate around the axis of the swinging block, and the upper end of the swinging block (8) is hinged on the mounting block (53) of the water squeezing frame (5) through a hinged shaft (81).

8. The wringing device for a foam cotton mop according to claim 4, wherein: the limiting structure is a stop block (9) for limiting the swing angle of the swing block (8), and the limit of the lower swing position of the second end (62) is realized through the limitation of the swing angle of the swing block (8).

9. The utility model provides a foam cotton mop, includes clean bucket (1), mop pole (2) and rotates to be connected mop head (3) that have foam cotton (4) at mop pole (2) lower extreme, its characterized in that: the mop further comprises a water squeezing device according to any one of claims 1 to 8, wherein a water squeezing frame (5) in the water squeezing device is sleeved on the mop rod (2) and can slide up and down.

10. The utility model provides a cleaning tool, includes clean bucket (1), mop pole (2) and rotates and connect mop head (3) that have foam cotton (4) of connecting at mop pole (2) lower extreme, its characterized in that: the upper part of the cleaning barrel (1) is provided with the wringing device as claimed in claim 4.

11. The cleaning implement of claim 10, wherein: when the limiting structure limits the upward swinging amplitude of the second end (62), the mop head (3) rotates to be aligned with the extrusion opening (51), and then is pressed downwards to enter the extrusion opening (51), the extrusion part (6) is pushed by the mop head (3) to enable the second end (62) to swing downwards, and the foamed cotton (4) does not pass through the water squeezing channel (P); when the mop head (3) moves upwards to enter the extrusion opening (51), the second end (62) is limited by the limiting structure, and the foam cotton (4) is extruded through the extrusion channel (P).

12. The cleaning implement of claim 10, wherein: when the limiting structure limits the downward swinging amplitude of the second end (62), the mop head (3) rotates to be aligned with the extrusion opening (51), then the mop head is pressed downwards to enter the extrusion opening (51), the second end (62) is limited by the limiting structure, and the foamed cotton (4) is squeezed through the squeezing channel (P); when the mop head (3) moves upwards into the squeezing opening (51), the squeezing component (6) is pushed by the mop head (3) to enable the second end (62) to swing upwards, and the foamed cotton (4) does not pass through the water squeezing channel (P).

13. The cleaning implement of claim 10, wherein: the cleaning barrel is divided into two independent areas, the wringing frame (5) is positioned above one area, a cleaning frame (10) is arranged above the other area, the cleaning frame (10) is provided with a cleaning opening (101), and a cleaning component (11) is arranged in the cleaning opening (101); two groups of cleaning components (11) are arranged in a left-right interval in a paired mode, the mop head (3) rotates to be aligned with the cleaning opening (101) during cleaning, then the mop head enters the cleaning opening (101), and the left side and the right side of the foam cotton (4) are cleaned through the paired cleaning components (11) along the length direction (L) of the foam cotton (4).

14. The cleaning implement of claim 13, wherein: the cleaning frame (10) and the wringing frame (5) are integrally formed together.

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