CN111973106B - Mop bucket external member of crowded water of horizontal handstand - Google Patents

Abstract

The invention discloses a mop bucket kit for transversely inverted wringing, which relates to the technical field of cleaning tools and comprises a bucket body and a collodion mop; a middle clapboard for dividing the barrel body into a water squeezing barrel and a cleaning barrel is formed in the barrel body; a driving part is fixedly connected in the barrel body; the driving part is formed with a sliding groove; the collodion mop comprises a mop head and a collodion seat; the driving part is formed with a cleaning rack; the collodion base is formed with a driven gear which can be meshed and connected with the cleaning rack; a cleaning brush for brushing the collodion is arranged in the cleaning barrel; a plurality of wringing rollers for squeezing the collodion are rotatably connected in the wringing bucket. The invention is provided with the water squeezing bucket and the cleaning bucket at the same time; meanwhile, the cleaning brush is capable of automatically cleaning the collodion which is washed and scrubbed at the same time; the water squeezing part is positioned at the lower part of the barrel body; the design structure is compact, the volume of the barrel body is relatively small, the use and the storage are convenient, and the manufacturing cost is low; the collodion can be brushed without manual interference, the operation is simple, and the use is convenient.

Description

Mop bucket external member of crowded water of horizontal handstand

Technical Field

The invention relates to the technical field of cleaning tools, in particular to a mop bucket kit for transversely inverted wringing.

Background

Chinese patent document No. CN208426065U discloses a collodion mop cleaning barrel, which comprises a barrel body, and an extrusion device is arranged above a water storage area of the barrel body and can clamp the collodion of the collodion mop to continuously extrude the collodion mop, so as to further extrude the collodion.

Although the above patent can wash and wring out the collodion mop, when washing the collodion mop, can not wash the collodion clean through the washing, the collodion often adheres to spot or hair that are difficult to be washed away by water, often needs the manual collodion of scrubbing, and above patent can not satisfy daily user demand.

Disclosure of Invention

The technical problem to be solved by the invention is as follows: aiming at the defects in the prior art, the mop bucket external member with the functions of automatically brushing and squeezing the collodion cotton is provided.

In order to realize the purpose of the invention, the following technical scheme is adopted for realizing the purpose: a mop bucket kit for squeezing water in a transverse inverted manner comprises a bucket body and a collodion mop; a middle clapboard which is longitudinally arranged is formed in the barrel body along the length direction of the barrel body; the middle clapboard divides the barrel body into a water squeezing barrel and a cleaning barrel which are not communicated with each other.

A driving part is fixedly connected in the barrel body; the driving parts are positioned in the cleaning barrel and the water squeezing barrel, and the inner walls which are vertical to the length direction of the barrel body are respectively symmetrically formed with a sliding groove which is longitudinally arranged.

The collodion mop comprises a mop head which can be longitudinally connected in the sliding groove in a sliding manner, a collodion base which is rotatably connected in the mop head, and collodion which is fixedly connected at the lower end of the collodion base.

The driving part is positioned in the cleaning barrel, and cleaning racks which are symmetrically arranged are respectively formed on the lower part of the inner wall of the cleaning barrel, which is vertical to the length direction of the barrel body; and driven gears which can be meshed and connected with the cleaning racks are respectively formed at two ends of the collodion base.

When the wringing rack is meshed with the driven gear, the mop head moves downwards to enable the collodion base to rotate in the positive direction; the mop head moves upwards to enable the collodion cotton seat to rotate reversely.

A cleaning brush is longitudinally connected in the cleaning barrel in a sliding manner; when water is in the cleaning barrel, the cleaning brush is positioned at the upper end of the water surface by the buoyancy of the water.

When the collodion seat rotates underwater, the collodion always abuts against the cleaning brush; the relative rotation of the collodion and the cleaning brush enables the collodion to be brushed.

And a plurality of wringing rollers for squeezing the collodion are rotationally connected in the wringing bucket.

As a preferable scheme: and the driving part is positioned in the water squeezing barrel, and the upper part of the inner wall vertical to the length direction of the barrel body is respectively formed with symmetrically arranged water squeezing racks which can be meshed with the driven gear.

When the driven gear passes through the wringing rack, the collodion base rotates for half a circle.

The water squeezing roller is rotatably connected to the lower part of the inner wall of the driving part, which is positioned in the water squeezing barrel and is vertical to the middle partition plate; the wringing rollers are symmetrically arranged about the sliding groove; the collodion is compressed and dewatered as it passes between the wringing rollers.

As a preferable scheme: the collodion comprises a water squeezing part close to the collodion seat and a cleaning part far away from the collodion seat.

As a preferable scheme: the end face, far away from the collodion, of the collodion seat is close to the driven gear, and locking holes are formed in the end face and the locking holes.

Two ends of the mop head are respectively and rotatably connected with a self-resetting locking rod; a locking head capable of being clamped with the locking hole is formed at the end part of the self-resetting locking rod; a driven shifting block is formed at the other end of the self-resetting locking rod; and an unlocking slope used for driving the driven shifting block to rotate inwards is formed at the upper end of each sliding groove.

In a natural state, the locking head is positioned in the locking hole, and the collodion base is fixed relative to the mop head.

When the driven shifting block abuts against the unlocking slope and is pressed downwards, the driven shifting block rotates inwards, the locking head leaves the locking hole, and the collodion cotton seat can rotate relative to the mop head.

When the driven shifting block is separated from the unlocking slope, the self-resetting locking rod automatically returns to the original position.

As a preferable scheme: the cleaning brush comprises a floating frame which is longitudinally connected on the driving part in a sliding manner and a plurality of brush rods which are uniformly arranged along the length direction of the barrel body.

As a preferable scheme: guide plates which are longitudinally connected with the sliding groove in a sliding mode are formed at two ends of the mop head respectively.

Compared with the prior art, the invention has the beneficial effects that: when the product is used, the barrel body is placed on the horizontal plane, the cleaning brush is positioned at the bottom of the cleaning barrel, sufficient water is injected into the cleaning barrel, the water level exceeds the cleaning rack, and the cleaning brush floats to the upper end of the water surface under the buoyancy of the water. When the collodion needs to be cleaned, the mop rod is held by the hand, the mop head is placed into the cleaning barrel, the guide plate respectively enters the sliding groove, the mop head is pressed down, the unlocking slope is abutted to the driven shifting block, the driven shifting block is rotated towards the inner side, the locking head leaves the locking hole, and the collodion base can rotate relative to the mop head. The mop head is continuously pressed down to enable the driven gear to be meshed with the cleaning rack, and the guide plate is abutted to the sliding groove at the moment, so that the driven gear is meshed with the cleaning rack more stably. When the driven gear is meshed with the cleaning rack, the mop head is pressed down to enable the driven gear to rotate in the forward direction, the mop head is lifted up to enable the driven gear to rotate in the reverse direction, in the process, the cleaning brush is always abutted against the collodion by rising buoyancy of water, and the collodion moves relative to the cleaning brush to enable attached stains on the collodion to be brushed down. The cleaning brush comprises a sliding frame which is longitudinally and slidably connected to the driving part, so that the cleaning brush can only slide up and down, and the brush rod is fully contacted with the collodion cotton to be brushed more thoroughly in the brushing process. The mop head is pressed down and lifted up repeatedly, so that the collodion is rotated for many times and is brushed and cleaned by the cleaning brush. The mop head is lifted up to enable the mop head to leave the cleaning barrel, when the driven shifting block slides out of the sliding groove, the self-resetting locking rod returns to the original position again under the action of elastic force, the locking head enters the locking hole, and the collodion seat and the mop head are relatively fixed.

When the collodion needs to be squeezed, the mop rod is held by the hand, the mop head is placed into the squeezing barrel, the guide plate enters the sliding groove respectively, the mop head is pressed down, the unlocking slope is abutted to the driven shifting block, the driven shifting block is rotated towards the inner side, the locking head leaves the locking hole, and the collodion base can rotate relative to the mop head.

When the wringing rack is meshed with the driven gear, the mop head is continuously pressed down until the wringing rack is completely separated from the driven gear, and the wringing rack enables the collodion base to rotate to be positioned at the lower end of the collodion. The mop head is continuously pressed to the limit position, the collodion passes through the middle of the plurality of wringing rollers, the horizontal clearance of the wringing rollers is smaller than the thickness of the collodion, and then the collodion is compressed and dehydrated by the wringing rollers. And lifting the mop head, and after passing through the wringing rack, the wringing rack is meshed with the driven rack, so that the collodion base rotates to be positioned at the upper end of the collodion again. The mop head is pressed down and lifted repeatedly for many times, so that the collodion is squeezed and dewatered fully by the squeezing roller. The mop head is lifted up to be away from the barrel body, when the driven shifting block slides out of the sliding groove, the self-resetting locking rod returns to the original position again under the action of elastic force, the locking head enters the locking hole, the collodion seat and the mop head are relatively fixed, and the collodion mop can be used for cleaning.

According to the invention, through the design of the bucket body, the bucket body is provided with both the water squeezing bucket and the cleaning bucket, so that the design structure is more compact, and the use and the storage are convenient.

According to the invention, through the design of the locking rod, when the locking head is positioned in the locking hole, the collodion cotton seat is relatively fixed with the mop head, and the collodion cotton mop can be used for cleaning; when the locking head leaves the locking hole, the collodion seat and the mop head can rotate freely, and the collodion mop can be cleaned or squeezed.

According to the invention, through the design of the driven gear, when the driven gear is meshed with the wringing rack, the collodion can be scrubbed by moving the mop head up and down, and when the driven gear is meshed with the wringing rack, the collodion can be wrung by moving the mop head up and down.

According to the invention, through the design of the collodion mop, when the washing collodion mop is washed up and down, the driven gear is meshed with the washing rack, so that the collodion and the cleaning brush rotate relatively, the collodion is scrubbed, no new operation step is added in the use process, the collodion is scrubbed by the cleaning brush while being washed, and the collodion mop is simple to operate and convenient to use.

The invention has the water squeezing bucket and the cleaning bucket at the same time, has compact design structure and is convenient to use and store; the cleaning brush can automatically clean the collodion, manual interference is not needed, the collodion is washed by water and is scrubbed, the operation is simple, and the use is convenient; the water squeezing part is positioned at the lower part of the barrel body, so that the height of the barrel body is relatively low, the volume of the barrel body is relatively small, and the manufacturing cost is reduced to a certain extent.

Drawings

Fig. 1 is a schematic structural view of the present invention.

Fig. 2 is a schematic cross-sectional structure of the present invention.

Fig. 3 is a schematic exploded view of the present invention.

FIG. 4 is a schematic structural view of the bucket body of the present invention.

Fig. 5 and 6 are schematic structural views of the driving unit according to the present invention.

Fig. 7 is a schematic structural diagram of the gelatin cotton seat of the invention.

Fig. 8 is a schematic view of the structure of the mop head of the present invention.

Fig. 9 is a schematic structural diagram of the self-resetting locking lever of the present invention.

Fig. 10 is a schematic structural view of the locking of the self-resetting locking lever of the present invention.

Fig. 11 is a schematic view of the opening structure of the self-resetting locking rod of the present invention.

Fig. 12 is a schematic view of the operation state of the cleaning function of the present invention.

Fig. 13 is a schematic view of the overturning working state of the collodion base of the invention.

Fig. 14 is a schematic view of the working state of the wringing function of the present invention.

1. A barrel body; 11. a middle partition plate; 12. a water squeezing bucket; 13. a washing barrel; 2. a drive section; 21. a sliding groove; 22. a wringing rack; 23. rotating the hole; 24. cleaning the rack; 25. unlocking the slope; 3. a wringing roller; 4. a cleaning brush; 41. a floating frame; 42. a brush bar; 5. a collodion mop; 51. a mop head; 511. a guide plate; 512. a collodion base rotating hole a; 52. a collodion base; 521. a driven gear; 522. a locking hole; 523. a collodion base rotating hole b; 53. collodion cotton; 531. a cleaning section; 532. a water squeezing part; 54. a self-resetting locking rod; 541. a driven shifting block; 542. a locking head; 55. a mop rod.

Detailed Description

Example 1

According to the embodiment shown in fig. 1 to 14, the mop bucket kit for transverse inverted wringing comprises a bucket body 1 and a collodion mop 5; a middle clapboard 11 which is longitudinally arranged is formed in the barrel body 1 along the length direction of the barrel body 1; the middle clapboard 11 divides the barrel body 1 into a water squeezing barrel 12 and a cleaning barrel 13 which are not communicated with each other.

A driving part 2 is fixedly connected in the barrel body 1; the inner walls of the driving part 2, which are positioned in the cleaning barrel 13 and the water squeezing barrel 12 and are vertical to the length direction of the barrel body 1, are respectively symmetrically formed with a sliding groove 21 which is longitudinally arranged.

The collodion mop 5 comprises a mop head 51 which can be longitudinally and slidably connected in the sliding groove 21, a collodion seat 52 which is rotatably connected in the mop head 51, and collodion 53 which is fixedly connected at the lower end of the collodion seat 52.

One end of the mop head 51, which is far away from the collodion seat 52, is fixedly connected with a mop rod 55, and the corresponding collodion 53 is scrubbed or squeezed by holding the mop rod 55.

The two ends of the collodion seat 52 are respectively formed with a collodion seat rotating hole b 523; a collodion seat rotating hole a512 which is rotationally connected with the collodion seat rotating hole b523 is respectively formed at the two ends of the mop head 51; the collodion base rotating hole b523 is rotatably connected with the collodion base rotating hole a512 through a pin shaft.

The driving part 2 is positioned in the cleaning barrel 13, and cleaning racks 24 which are symmetrically arranged are respectively formed on the lower part of the inner wall which is vertical to the length direction of the barrel body 1; two ends of the collodion seat 52 are respectively formed with a driven gear 521 which can be meshed and connected with the cleaning rack 24.

When the wringing rack 22 is engaged with the driven gear 521, the mop head 51 moves downwards to make the collodion base 52 rotate forwards; the mop head 51 is moved upward so that the collodion mount 52 rotates in the opposite direction.

The cleaning brush 4 is longitudinally connected in the cleaning barrel 13 in a sliding manner; when water exists in the cleaning barrel 13, the cleaning brush 4 is positioned at the upper end of the water surface under the buoyancy of the water.

When the collodion seat 52 rotates underwater, the collodion 53 always abuts against the cleaning brush 4; the relative rotation of the collodion 53 and the cleaning brush 4 causes the collodion 53 to be brushed.

A plurality of wringing rollers 3 for squeezing the collodion 53 are rotatably connected in the wringing bucket 12.

The driving part 2 is positioned in the water squeezing barrel 12, and the upper part of the inner wall vertical to the length direction of the barrel body 1 is respectively formed with symmetrically arranged water squeezing racks 22 capable of being meshed with the driven gear 521.

When the driven gear 521 passes through the wringing rack 22, the collodion seat 52 rotates for half a circle.

The wringing roller 3 is rotatably connected to the driving part 2 and is positioned in the wringing bucket 12 and is vertical to the lower part of the inner wall of the middle clapboard 11; the wringing rollers 3 are symmetrically arranged about the sliding groove 21; the collodion 53 is compressed and dewatered as it passes between the wringing rollers 3.

The driving part 2 is positioned in the water squeezing barrel 12 and is symmetrically formed with rotating holes 23 at the lower part of the vertical inner wall of the middle clapboard 11; the wringing roller 3 is rotatably connected in the rotating hole 23; the adjacent gap of the wringing roller 3 in the transverse direction is smaller than the thickness of the collodion 53.

The collodion 53 comprises a water squeezing part 532 close to the collodion seat 52 and a cleaning part 531 far away from the collodion seat 52.

When the mop head 51 slides downwards along the sliding groove 21, the collodion base 52 rotates to be positioned at the upper end of the collodion 53; when the mop head 51 continuously slides downwards to pass through the water squeezing rollers 3, the included angle between the outer wall of the water squeezing part 532 and the vertical plane in the length direction of the collodion 53 is smaller than the included angle between the outer wall of the cleaning part 531 and the vertical plane in the length direction of the collodion 53; the water squeezing part 532 can enter between the water squeezing rollers 3 more easily, so that the water squeezing process is more labor-saving and the operation is more convenient.

Locking holes 522 are respectively formed in the end surfaces, far away from the collodion 53, of the collodion seats 52 and close to the driven gear 521.

Two ends of the mop head 51 are respectively and rotatably connected with a self-resetting locking rod 54; a locking head 542 which can be clamped with the locking hole 522 is formed at the end part of the self-resetting locking rod 54; a driven shifting block 541 is formed at the other end of the self-resetting locking rod 54; an unlocking slope 25 for driving the driven shifting block 541 to rotate inwards is formed at the upper end of each sliding groove 21.

In a natural state, the locking head 542 is located in the locking hole 522, and the collodion base 52 is fixed relative to the mop head 51.

When the follower shifting block 541 abuts against the unlocking slope 25 and is pressed downwards, the follower shifting block 541 rotates inwards, the locking head 542 leaves the locking hole 522, and the collodion seat 52 can rotate relative to the mop head 51.

When the driven block is separated from the unlocking ramp 25, the self-resetting locking lever 54 automatically returns to the original position.

When the collodion base 52 and the mop head 51 are relatively fixed, the corresponding cleaning and sweeping work is carried out by holding the mop rod 55; when the collodion seat 52 and the mop head 51 can rotate freely, the collodion 53 can be brushed or squeezed by holding the mop rod 55.

The cleaning brush 4 comprises a floating frame 41 longitudinally connected on the driving part 2 in a sliding manner and a plurality of brush rods 42 uniformly arranged along the length direction of the barrel body 1.

The floating frame 41 enables the cleaning brush 4 to move up and down only, and the brush rod 42 is always attached to the collodion 53 in the brushing process, so that the brushing area is larger, and the brushing effect is better.

Two ends of the mop head 51 are respectively formed with a guide plate 511 which is longitudinally connected with the sliding groove 21 in a sliding manner.

When the driven gear 521 is engaged with the wringing rack 22 or the cleaning rack 24, the guide plate 511 is always abutted against two side walls parallel to the sliding groove 21, so that the engagement process is more stable and the operation is smoother.

When using this product, on placing the horizontal plane with staving 1, cleaning brush 4 is located the bottom of wasing bucket 13, will wash the interior injected sufficient water of bucket 13, makes the water level exceed and washs rack 24, and cleaning brush 4 receives the buoyancy of water to float to the surface of water upper end. When the collodion 53 needs to be cleaned, the mop rod 55 is held by a hand, the mop head 51 is placed into the cleaning barrel 13, the guide plates 511 respectively enter the sliding grooves 21, the mop head 51 is pressed downwards, the unlocking slope 25 abuts against the driven shifting block 541, the driven shifting block 541 rotates inwards, the locking head 542 leaves the locking hole 522, and the collodion seat 52 can rotate relative to the mop head 51. The mop head 51 is further pressed down to engage the driven gear 521 with the cleaning rack 24, and at this time, the guide plate 511 abuts against the sliding groove 21, so that the engagement of the driven gear 521 with the cleaning rack 24 is more stable. When the driven gear 521 is engaged with the cleaning rack 24, the driven gear 521 rotates forward by pressing the mop head 51 downwards, the driven gear 51 rotates reversely by lifting the mop head 51, in the process, the rising buoyancy of the cleaning brush 4 bearing water always offsets the collodion 53, and the relative movement of the collodion 53 and the cleaning brush 4 enables the stains attached to the collodion 53 to be brushed down. The cleaning brush 4 comprises a sliding frame 41 longitudinally and slidably connected to the driving part 2, so that the cleaning brush 6 can only slide up and down, and the brush rod 42 is fully contacted with the collodion 53 during brushing, thereby more thoroughly brushing. The mop head 51 is pressed down and lifted repeatedly for a plurality of times, so that the collodion 53 rotates for a plurality of times and is brushed clean by the cleaning brush 4. When the mop head 51 is lifted up to leave the mop head 51 from the cleaning barrel 13, the driven shifting block 541 slides out of the sliding groove 21, the self-resetting locking rod 54 returns to the original position under the action of the elastic force, the locking head 542 enters the locking hole 522, and the collodion base 52 is relatively fixed with the mop head 51.

When the collodion 53 needs to be squeezed, the mop rod 55 is held by a hand, the mop head 51 is placed into the squeezing barrel 13, the guide plates 511 respectively enter the sliding grooves 21, the mop head 51 is pressed downwards, the unlocking slope 25 abuts against the driven shifting block 541, the driven shifting block 541 rotates inwards, the locking head 542 leaves the locking hole 522, and the collodion seat 52 can rotate relative to the mop head 51.

When the wringing rack 22 is engaged with the driven gear 521, the mop head 51 is continuously pressed down until the wringing rack 22 is completely separated from the driven gear 521, and the wringing rack 22 enables the collodion base 52 to rotate to be positioned at the lower end of the collodion 53. The mop head 51 is continuously pressed to the limit position, the collodion 53 passes through the middle of the plurality of wringing rollers 3, the horizontal gap of the wringing rollers 3 is smaller than the thickness of the collodion 53, and then the collodion is compressed and dehydrated by the wringing rollers 3. The mop head 51 is lifted up, and after passing through the wringing rack 22, the wringing rack 22 is meshed with the driven rack 521, so that the collodion base 52 rotates to be positioned at the upper end of the collodion 53 again. The mop head 51 is pressed down and lifted repeatedly for a plurality of times, so that the collodion 53 is squeezed by the squeezing roller 3 to be dehydrated fully. The mop head 51 is lifted up to leave the bucket body, when the driven shifting block 541 slides out of the sliding groove 21, the self-resetting locking rod 54 returns to the original position again under the action of the elastic force, the locking head 542 enters the locking hole 522, the collodion base 52 and the mop head 51 are relatively fixed, and the collodion mop 5 can be used for cleaning.

According to the invention, through the design of the barrel body 1, the barrel body 1 is provided with the water squeezing barrel 12 and the cleaning barrel 13, so that the design structure is more compact, and the use and the storage are convenient.

According to the invention, through the design of the locking rod 54, when the locking head 542 is positioned in the locking hole 522, the collodion base 52 and the mop head 51 are relatively fixed, and the collodion mop 5 can be used for cleaning; when the locking head 542 leaves the locking hole 522, the collodion base 52 and the mop head 51 can rotate freely, and the collodion mop 5 can be washed or squeezed.

According to the invention, through the design of the driven gear 521, when the driven gear 521 is meshed with the water squeezing rack 22, the mop head 51 moves up and down to enable the collodion 53 to be scrubbed, and when the driven gear 521 is meshed with the water squeezing rack 22, the mop head 51 moves up and down to enable the collodion 53 to be squeezed.

According to the invention, through the design of the collodion mop 5, when the washing collodion mop 5 moves up and down, the driven gear 521 is meshed with the washing rack 24, so that the collodion 53 and the cleaning brush 4 rotate relatively, the collodion 53 is scrubbed, no new operation step is added in the use process, the collodion 53 is scrubbed by the cleaning brush 4 while being washed, the operation is simple, and the use is convenient.

The invention has the water squeezing bucket and the cleaning bucket at the same time, has compact design structure and is convenient to use and store; the cleaning brush can automatically clean the collodion, manual interference is not needed, the collodion is washed by water and is scrubbed, the operation is simple, and the use is convenient; the squeezing part is positioned at the lower part of the barrel body, so that the height of the barrel body is relatively low, the volume of the barrel body is relatively small, and the manufacturing cost is reduced to a certain extent.

Claims (6)

1. A mop bucket kit for squeezing water in a transverse inverted manner comprises a bucket body and a collodion mop; the method is characterized in that: a middle clapboard which is longitudinally arranged is formed in the barrel body along the length direction of the barrel body; the middle clapboard divides the barrel body into a water squeezing barrel and a cleaning barrel which are not communicated with each other;

a driving part is fixedly connected in the barrel body; the inner walls of the driving parts, which are positioned in the cleaning barrel and the water squeezing barrel and are vertical to the length direction of the barrel body, are respectively symmetrically formed with a longitudinally arranged sliding groove;

the collodion mop comprises a mop head which can be longitudinally connected in the sliding groove in a sliding manner, a collodion base which is rotatably connected in the mop head and collodion which is fixedly connected at the lower end of the collodion base;

the driving part is positioned in the cleaning barrel, and cleaning racks which are symmetrically arranged are respectively formed at the lower part of the inner wall which is vertical to the length direction of the barrel body in the cleaning barrel; driven gears capable of being meshed and connected with the cleaning racks are formed at two ends of the collodion base respectively; the driving part is positioned in the water squeezing barrel, and the upper part of the inner wall of the water squeezing barrel, which is vertical to the length direction of the barrel body, is respectively formed with symmetrically arranged water squeezing racks which can be meshed with the driven gear;

when the wringing rack is meshed with the driven gear, the mop head moves downwards to enable the collodion cotton seat to rotate in the positive direction; the mop head moves upwards to enable the collodion cotton seat to rotate reversely;

a cleaning brush is longitudinally connected in the cleaning barrel in a sliding manner; when water is in the cleaning barrel, the cleaning brush is positioned at the upper end of the water surface by the buoyancy of the water;

when the collodion seat rotates underwater, the collodion always abuts against the cleaning brush; the relative rotation of the collodion and the cleaning brush enables the collodion to be brushed;

and a plurality of wringing rollers for squeezing the collodion are rotationally connected in the wringing bucket.

2. The mop bucket kit for inverted transverse wringing of claim 1, wherein:

when the driven gear passes through the wringing rack, the collodion seat rotates for half a circle;

the water squeezing roller is rotatably connected to the lower part of the inner wall of the driving part, which is positioned in the water squeezing barrel and is vertical to the middle partition plate; the wringing rollers are symmetrically arranged about the sliding groove; the collodion is compressed and dewatered as it passes between the wringing rollers.

3. The mop bucket kit for inverted transverse wringing of claim 2, wherein: the collodion comprises a water squeezing part close to the collodion seat and a cleaning part far away from the collodion seat.

4. The mop bucket kit for inverted transverse wringing of claim 1, wherein: locking holes are respectively formed in the end face, far away from the collodion, of the collodion seat and close to the driven gear;

two ends of the mop head are respectively and rotatably connected with a self-resetting locking rod; a locking head capable of being clamped with the locking hole is formed at the end part of the self-resetting locking rod; a driven shifting block is formed at the other end of the self-resetting locking rod; an unlocking slope used for driving the driven shifting block to rotate inwards is formed at the upper end of each sliding groove;

in a natural state, the locking head is positioned in the locking hole, and the collodion base is fixed relative to the mop head;

when the driven shifting block abuts against the unlocking slope and is pressed downwards, the driven shifting block rotates inwards, the locking head leaves the locking hole, and the collodion seat can rotate relative to the mop head;

when the driven shifting block is separated from the unlocking slope, the self-resetting locking rod automatically returns to the original position.

5. The mop bucket kit for inverted transverse wringing of claim 1, wherein: the cleaning brush comprises a floating frame which is longitudinally connected on the driving part in a sliding manner and a plurality of brush rods which are uniformly arranged along the length direction of the barrel body.

6. The mop bucket kit for inverted transverse wringing of claim 1, wherein: guide plates which are longitudinally connected with the sliding groove in a sliding mode are formed at two ends of the mop head respectively.

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