CN111839389A - Mop bucket free of manual scrubbing and squeezing - Google Patents

Abstract

The invention discloses a hand-free scrubbing and wringing collodion mop bucket, which relates to the technical field of cleaning tools and comprises a bucket body and a collodion mop; a brushing component for brushing the collodion mop is arranged at the bottom in the barrel body; the brushing component comprises two brushes and a linkage piece; the linkage piece enables the horizontal movement directions of the two brushes to be opposite; a power storage assembly capable of driving the cleaning brush to reciprocate horizontally along the length direction of the barrel body is arranged in the barrel body; the lower end of the collodion mop is provided with collodion; when the collodion is abutted against the hairbrush, the hairbrush which moves horizontally back and forth enables the collodion to be brushed cleanly; a wringing component for wringing the collodion cotton is arranged on one side of the upper part in the barrel body; the squeezing process of the collodion can enable the power storage component to store power. The invention has the roller for squeezing the collodion, has small friction force, has the cleaning brush which can avoid manually brushing the collodion, can accumulate the elasticity for driving the cleaning brush to move when squeezing the collodion, is easy to clean, is simple to use and is convenient to operate.

Description

Mop bucket free of manual scrubbing and squeezing

Technical Field

The invention relates to the technical field of cleaning tools, in particular to a mop bucket free of manual scrubbing and squeezing.

Background

Chinese patent document No. CN209595676U discloses a folding mop and a water squeezing device thereof, belonging to the technical field of daily cleaning products. Folding mop includes mop head, left and right connecting piece, a pair of slider, a pair of returning face plate and a pair of fixed plate, establishes the supporting seat on the returning face plate, and the supporting seat pivot is put on left and right connecting piece, and every downward projection in the up end middle part of supporting seat inboard has first boss, and the lateral part of first boss is downward projected to have the second boss, forms the draw-in groove between first, the second boss, and the slider has card foot I in the one end outwards, and card foot I cooperatees with the draw-in groove. The water squeezing device comprises a cleaning barrel, a water squeezing mechanism is mounted in the middle of an opening at the upper end of the cleaning barrel, a mop yielding port is formed in the middle of a body of the water squeezing mechanism, water squeezing ports are formed in the bodies on two sides of the mop yielding port, and a limiting plate extends downwards on the body of the water squeezing mechanism and surrounds the mop yielding port and the water squeezing ports. The mop is convenient to use and clean, the structure is simplified, the cost is saved, and the assembly and maintenance difficulty is reduced; the cleaning area and the cleaning efficiency are improved.

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 kit with the functions of manually brushing and squeezing the collodion is provided.

In order to realize the purpose of the invention, the following technical scheme is adopted for realizing the purpose: a hand-free scrubbing and wringing collodion mop barrel kit comprises a barrel body and a collodion mop; a brushing component for brushing the collodion mop is arranged at the bottom in the bucket body; the brushing component comprises two brushes horizontally arranged along the length direction of the barrel body and linkage pieces which are rotatably connected with the bottom in the barrel body and are respectively connected with the two brushes in a sliding manner.

The linkage piece enables the horizontal movement directions of the two hairbrushes to be opposite.

Limiting pieces for limiting the upward movement of the brush are formed at the bottom of the barrel body close to the four corners; a first spring is arranged between the middle position of the lower end of the linkage piece and the bottom end in the barrel body; under the natural state, the first spring enables the brush to be upwards abutted against the limiting piece.

One end of the limiting piece close to the width direction of the barrel body is respectively provided with a stop piece; the barrel body is internally provided with a force storage assembly which can drive the cleaning brush to reciprocate horizontally along the length direction of the barrel body.

When the two ends of the brush in the length direction respectively abut against the stop pieces, the brush cannot horizontally reciprocate.

When both ends of the brush in the length direction are not abutted against the stop pieces, the brush can horizontally reciprocate.

The lower end of the collodion mop is provided with collodion; when the collodion is abutted against the hairbrush, the hairbrush which moves horizontally in a reciprocating manner enables the collodion to be brushed cleanly.

A water squeezing component for squeezing the collodion cotton is arranged on one side of the upper part in the barrel body; the squeezing process of the collodion can enable the power storage component to store power.

As a preferable scheme: the collodion mop comprises a U-shaped frame, a turnover part, a rotating part and two collodion plates, wherein the turnover part is rotatably connected at the middle position of the lower part of the U-shaped frame, the rotating part is rotatably connected at the central position of the lower end of the turnover part, the rotating part is vertically arranged on the rotating shaft, and the two collodion plates are respectively rotatably connected at the two ends of the rotating part and symmetrically arranged.

The collodion is respectively and fixedly connected with the lower ends of the two collodion plates; when the two collodion plates rotate in opposite directions, the collodion plates extrude the collodion.

The wringing component comprises a wringing frame fixedly connected to one side of the upper part in the barrel body and a plurality of wringing rollers which are rotatably connected to the upper part of the wringing frame and are symmetrically arranged for wringing the collodion cotton.

As a preferable scheme: two elastic clamping heads which are symmetrically arranged are formed at the lower end of the turnover part; two limiting through holes and two limiting notches which can be respectively clamped with the elastic clamping heads are formed at the upper end of the rotating part; and a connecting line between the two limiting through holes is vertical to a connecting line between the two limiting notches.

When the elasticity dop with during spacing through-hole joint, U type frame lower extreme with the glued membrane offsets, upset portion can not be relative U type frame is rotatory.

When the elasticity dop with during spacing notch joint, U type frame lower extreme not with the glued membrane board offsets, upset portion can be relative U type frame is rotatory to be made the glued membrane rotate to being located the rotating part top.

As a preferable scheme: the lower end of the rotating part is longitudinally connected with an unlocking sheet in a sliding manner; the unlocking sheet is characterized in that an unlocking insertion column which is connected with the limiting through hole in a longitudinal sliding mode and is located in the limiting through hole is formed in the upper end of the unlocking sheet.

The upper end of the brush is located under the unlocking sheet, and an upper top convex strip is formed.

Under the natural state, elasticity dop with spacing through-hole joint, the rotating part can not be relative upset portion rotates.

When the collodion and the brush are tightly abutted and pressed down, the upward ejection convex strip enables the unlocking sheet to slide upwards, so that the elastic chuck leaves the limiting through hole, and the rotating part can rotate relative to the overturning part.

As a preferable scheme: one end of the collodion board close to the rotating part is respectively formed with a limiting clamping groove; the rotating part is internally provided with an automatic locking part which can be respectively clamped with the limiting clamping grooves.

The self-locking part comprises two clamping heads which can be clamped with the limiting clamping grooves respectively and a second spring which is fixedly connected between the two clamping heads.

Under the natural state, the dop with spacing draw-in groove joint, two the glued membrane board can keep parallel relatively.

When carrying out the wringing, the dop with spacing draw-in groove separation, the collodion board can be relative the rotating part is rotatory.

As a preferable scheme: the power accumulating assembly comprises an eccentric wheel which is positioned below the brush and used for driving the brush to horizontally move along the length direction of the barrel body and a power accumulating gear which is positioned in the eccentric wheel and is in one-way transmission connection with the eccentric wheel; and a clockwork spring for driving the power accumulating gear to rotate is arranged in the power accumulating gear and is positioned below the eccentric wheel.

A driving column is formed at the non-circle center position of the upper end of the eccentric wheel; the lower end of the brush is provided with a driving sliding chute which is connected with the driving column in a sliding way.

When the eccentric wheel rotates, the driving column drives the driving sliding groove to enable the brush to horizontally reciprocate along the length direction of the barrel body.

As a preferable scheme: a plurality of elastic pawls are uniformly arranged on the outer wall of the power storage gear along the circumferential direction; a ratchet wheel in one-way transmission connection with the elastic pawl is formed in the eccentric wheel.

When the power accumulating gear rotates in the positive direction, the eccentric wheel does not rotate, so that the clockwork spring accumulates power.

When the power accumulating gear rotates reversely, the eccentric wheel rotates synchronously, and the brush is driven to horizontally reciprocate.

As a preferable scheme: two limiting chucks which are symmetrically arranged are formed at the upper part of the outer wall of the eccentric wheel; the lower end of the barrel body is fixedly connected with an elastic stop block which can limit the limiting clamping head to pass through.

When the elasticity of the clockwork spring is large enough, the limiting chuck can pass through the elastic stop block.

When the elasticity of the clockwork spring is reduced to the limit chuck and the limit chuck can not pass through the elastic stop block, the two ends of the hairbrush in the length direction are overlapped.

As a preferable scheme: the power accumulating assembly comprises a driving shaft which is positioned in the barrel body and is in transmission connection with the power accumulating gear and used for accumulating power of the power accumulating gear, a driving ratchet which is positioned in the driving shaft and is longitudinally and slidably connected with the driving shaft, and a spiral sheet which is positioned in the driving shaft and is longitudinally and slidably connected with the driving shaft and used for driving the driving ratchet to rotate.

A driven ratchet wheel in transmission connection with the driving ratchet wheel is formed in the driving shaft and is positioned below the driving ratchet wheel; and a driving groove which penetrates through the driving ratchet wheel and is longitudinally connected with the spiral sheet in a sliding manner is formed in the center of the upper end of the driving ratchet wheel.

When the spiral piece moves downwards, the driving groove rotates along the spiral direction of the spiral piece in a positive direction relatively, the driving ratchet wheel is meshed with the driven ratchet wheel, and then the driving shaft rotates in a positive direction.

When the spiral piece moves upwards, the driving groove rotates oppositely along the spiral direction of the spiral piece, the driving ratchet wheel moves upwards to be separated from the driven ratchet wheel, and the driving shaft does not rotate.

The upper end of the spiral sheet is fixedly connected with a lower pressing sheet; the lower pressing sheet is positioned right below the wringing jack; and a third spring is fixedly connected between the lower end of the water squeezing frame and the lower end of the lower pressing sheet close to four corners.

When the rotating part is pressed downwards, the rotating part is abutted against the lower pressing sheet and moves downwards; the rotating part is lifted up, and the lower pressing plate moves upwards under the action of the elastic force of the third spring.

As a preferable scheme: the upper part of the barrel body is rotatably connected with a handle.

Compared with the prior art, the invention has the beneficial effects that: according to the invention, through the design of the rotating part, when the elastic chuck is positioned in the limiting through hole, the turnover part cannot rotate, the collodion mop can be used for cleaning or scrubbing work, when the elastic chuck is positioned in the limiting notch, the turnover part can rotate upwards, and when the collodion rotates to the position above the rotating part, the collodion mop can be used for wringing operation.

According to the invention, through the design of the force accumulation assembly, when two ends of the hairbrush in the length direction abut against the stop plate, the lower pressing plate moves downwards to enable the clockwork spring to accumulate force, and when two ends of the hairbrush in the length direction do not abut against the stop plate, the elastic force accumulated by the clockwork spring can enable the eccentric wheel to rotate, so that the hairbrush is driven to reciprocate to scrub the collodion.

According to the invention, through the design of the elastic stop block, when the elasticity of the clockwork spring is large enough, the eccentric wheel can enable the limiting chuck to pass through when rotating, so that the hairbrush can reciprocate, when the elasticity of the clockwork spring is not large enough, the eccentric wheel stops moving when rotating to enable the limiting chuck to abut against the elastic stop block, at the moment, two ends in the length direction of the hairbrush are respectively superposed, and can move upwards under the action of the elasticity of the first spring so that two ends in the length direction of the hairbrush abut against the stop block.

According to the invention, through the design of the lower pressing plate, when the collodion mop is pressed down and lifted, the lower pressing plate can be reset upwards to prepare for the next driving of the spiral piece, and the collodion mop can be lifted more easily.

The mop squeezer is provided with the rollers which are arranged in pairs and used for squeezing the collodion, when the mop is pressed down to pass through the water squeezing assembly, the friction force is small, the operation is labor-saving, and the use is convenient. The cleaning brush has the advantages that the cleaning brush can be used for brushing the collodion without hands, attached stains which are difficult to wash away by water can be removed without manual operation, and the cleaning brush is convenient to use. The invention can accumulate the elastic force for driving the cleaning brush to move while squeezing the collodion, does not add a new operation step, and has simple use and convenient operation.

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 and 5 are schematic structural views of the barrel body of the invention.

FIG. 6 is an exploded view of the brush assembly of the present invention.

FIG. 7 is a schematic view showing the structure of the brush of the present invention.

Fig. 8 is a schematic structural view of the wringing assembly of the present invention.

Fig. 9 is a schematic exploded view of the collodion mop of the present invention.

Fig. 10 is a schematic view of the structure of the turning part of the present invention.

Fig. 11 is a schematic view of the structure of the rotary part of the present invention.

FIG. 12 is a schematic exploded view of the power storage assembly of the present invention.

FIG. 13 is a schematic diagram of the power storage gear of the present invention.

Fig. 14 is a schematic view of the construction of the drive shaft of the present invention.

Fig. 15 and 16 are schematic structural views of the eccentric wheel of the invention.

FIG. 17 is a schematic view of the natural state of the brush assembly of the present invention.

FIG. 18 is a schematic view of the brushing status of the brush assembly of the present invention.

FIG. 19 is a schematic view of the construction of the present invention when the collodion board is locked.

Fig. 20 is a schematic view showing a locked state of the rotary unit according to the present invention.

Fig. 21 is a schematic structural view showing an unlocked state of the rotary portion of the present invention.

Fig. 22 and 23 are schematic structural views of the state of the collodion cotton when the collodion cotton is turned over.

Fig. 24 is a schematic structural view of the wringing function of the present invention.

10. A barrel body; 101. connecting sheets; 1011. a limiting sheet; 1012. a stopper piece; 102. a linkage sheet positioning column; 103. a support table; 104. water level identification; 105. a handle rotation hole; 106. a card slot; 107. an elastic stopper; 108. rotating the bin; 1081. a first sealed rotation aperture; 1082. a second sealed rotation aperture; 11. a handle; 111. a handle rotating head; 2. a wringing component; 21. a water squeezing frame; 211. clamping a head; 212. a sliding post; 213. a water squeezing jack; 22. a wringing roller; 3. a power storage assembly; 31. a lower pressing plate; 311. a spiral sheet; 32. a third spring; 33. driving the ratchet wheel; 331. a drive slot; 34. a drive shaft; 341. a drive gear; 342. a driven ratchet wheel; 35. a transmission gear; 351. a transmission pinion; 36. a power storage gear; 361. an upper convex ring; 362. an elastic pawl; 363. a clockwork spring; 37. an eccentric wheel; 371. a drive column; 372. a limiting chuck; 373. a ratchet wheel; 374. a seal ring; 38. a lower block cover; 4. a brushing assembly; 41. a brush; 411. upward jacking convex strips; 412. a drive chute; 413. a linkage column; 42. a linkage piece; 421. a linkage chute; 422. a first spring; 423. rotating the through hole; 5. a collodion mop; 51. a U-shaped frame; 511. rotating the hole; 52. a turning part; 521. rotating the column; 522. a central rotation hole; 523. an elastic chuck; 53. a rotating part; 531. a rotating base; 532. a limiting through hole; 533. a self-locking through groove; 534. a limiting notch; 535. a central rotating post; 54. a collodion board; 541. a spin column; 542. a limiting block; 543. a limiting clamping groove; 55. collodion cotton; 56. unlocking the plate; 561. unlocking the inserted column; 57. an auto-lock portion; 571. clamping a head; 572. a second spring; 58. a mop rod.

Detailed Description

Example 1

Referring to fig. 1 to 23, the scrubbing and squeezing collodion mop bucket set without manual brushing according to the embodiment includes a bucket body 10 and a collodion mop 5; a brushing component 4 for brushing the collodion mop 5 is arranged at the bottom in the barrel body 10; the brushing assembly 4 comprises two brushes 41 horizontally arranged along the length direction of the barrel 10 and a linkage piece 42 rotatably connected to the bottom in the barrel 10 and slidably connected to the two brushes 41 respectively.

The linkage pieces 42 make the two brushes 41 move in opposite directions horizontally.

Two ends of the lower end of the brush 41, which are close to the length direction of the brush 41, are respectively provided with a linkage column 413; two ends of the upper end of the linkage piece 42 close to the width direction of the brush 41 are respectively formed with a linkage sliding groove 421 which is connected with the linkage column 413 in a sliding manner; when one of the brushes 41 moves toward one end of the length of the tub 10, the link plate 42 rotates about the link post 413, so that the other brush 41 moves toward the other end of the length of the tub 10.

A limiting sheet 1011 for limiting the upward movement of the brush 41 is formed at the bottom of the barrel body 10 near the four corners; a first spring 422 is arranged between the middle position of the lower end of the linkage plate 42 and the bottom end of the barrel body 10; in a natural state, the first spring 422 makes the brush 41 upwards abut against the position-limiting piece 1011.

A rotation through hole 423 penetrating through the linkage piece 42 is formed at the center of the upper end of the linkage piece 42; linkage sheet positioning columns 102 rotatably connected with the rotating through holes 423 are formed at the inner bottom end of the barrel body 10 respectively; the linkage piece 42 can slide along the linkage piece positioning column 102 longitudinally, and the first spring 422 is arranged on the outer wall of the linkage piece positioning column 102.

A stop piece 1012 is respectively formed at one end of the limiting piece 1011 close to the width direction of the barrel body 10; the bucket body 10 is internally provided with a power storage assembly 3 which can drive the cleaning brush 41 to reciprocate horizontally along the length direction of the bucket body 10.

A coupling piece 101 for supporting the stopper 1011 and the stopper 1012 is formed upward at the inner bottom end of the tub 10.

When both ends of the brush 41 in the length direction are respectively abutted against the stopper 1012, the brush 41 cannot horizontally reciprocate.

When both ends of the brush 41 in the length direction do not abut against the stopper 1012, the brush 41 can horizontally reciprocate.

A rotating bin 108 extending upwards is formed at one end of the lower end of the barrel body 10 close to the length direction of the barrel body 10; a support table 103 is formed at the other end of the inner bottom end of the barrel body 10, which is close to the length direction of the barrel body 10; the height of the rotating bin 108 in the barrel body 10 is equal to the height of the supporting platform 103; when the brush 41 abuts against the upper end of the support base 103, both ends of the brush 41 in the length direction do not abut against the stop piece 1012, and the support base 103 and the rotation bin 108 make the horizontal reciprocating motion of the brush 41 more stable.

The lower end of the rotating bin 108 is fixedly connected with a lower baffle cover 38 used for closing the lower end of the rotating bin 108; the lower end surface of the lower blocking cover 38 coincides with the lower end surface of the barrel body 10, so that the barrel body 10 is more stable on the horizontal plane.

The lower end of the collodion mop 5 is provided with collodion 55; when the collodion 55 is abutted against the brush 41, the brush 41 which reciprocates horizontally brushes the collodion 55.

A water squeezing component 2 for squeezing the collodion 55 is arranged on one side of the inner upper part of the barrel body 10; the squeezing process of the collodion 55 can make the power storage component 3 store power.

The collodion mop 5 comprises a U-shaped frame 51, a turning part 52 which is rotatably connected at the middle position of the lower part of the U-shaped frame 51 and is horizontally arranged on a rotating shaft, a rotating part 53 which is rotatably connected at the central position of the lower end of the turning part 52 and is vertically arranged on the rotating shaft, and two collodion plates 54 which are respectively rotatably connected at the two ends of the rotating part 53 and are symmetrically arranged.

One end of the U-shaped frame 51 far away from the overturning part 52 is fixedly connected with a mop rod 58; the corresponding brushing or wringing operation is performed by holding the mop rod 58.

The collodion 55 is respectively fixedly connected to the lower ends of the two collodion plates 54; when the two collodion plates 54 rotate towards each other, the collodion plates 54 press the collodion 55.

The wringing component 2 comprises a wringing frame 21 fixedly connected to one side of the upper part in the barrel body 10 and a plurality of symmetrically arranged wringing rollers 22 rotatably connected to the upper part of the wringing frame 21 and used for wringing the collodion 55.

Three side edges of the upper part of the wringing frame 21 are respectively abutted against the barrel body 10, and clamping heads 211 are respectively and uniformly formed on the three side edges; a clamping groove 106 clamped with the clamping head 211 is formed at the upper end of the barrel body 10; the clamping head 211 is clamped with the clamping groove 106, so that the wringing frame 21 and the barrel body 10 are relatively fixed.

A wringing jack 213 which penetrates through the wringing frame 21 is formed in the center of the upper end of the wringing frame 21; the wringing rollers 22 are symmetrically disposed about the wringing receptacle 213.

When the rotating part 53 is located at the upper end of the turning part 52 and is inserted into the wringing insertion hole 213, the wringing roller 22 can enable the collodion plates 54 to rotate towards the direction far away from the turning part 52, the included angle between the two collodion plates 54 is reduced, and the collodion 55 is compressed and dehydrated.

The lower end of the turning part 52 is formed with two elastic clamping heads 523 which are symmetrically arranged; two limiting through holes 532 and two limiting notches 534 which can be respectively clamped with the elastic clamping heads 523 are formed at the upper end of the rotating part 53; a connecting line between the two limiting through holes 532 is perpendicular to a connecting line between the two limiting notches 534.

When the elastic clamping head 523 is clamped with the limiting through hole 532, the lower end of the U-shaped frame 51 is abutted to the collodion board 54, and the turnover part 52 cannot rotate relative to the U-shaped frame 51.

When the elastic chuck 523 is clamped with the limiting notch 534, the lower end of the U-shaped frame 51 does not abut against the collodion board 54, and the turning part 52 can rotate relative to the U-shaped frame 51 to enable the collodion 55 to rotate to be located above the rotating part 53.

Two ends of the turning part 52 are respectively formed with symmetrically arranged rotating columns 521; the U-shaped frame 51 is arranged in an inverted U shape, and the turning part 52 is rotatably connected between two straight edges of the U-shaped frame 51; two straight edges of the U-shaped frame 51 are respectively formed with a rotating hole 511 which is rotatably connected with the rotating column 521; the U-shaped frame 51 has an opening height sufficient to allow the collodion 55 to rotate through.

The lower end of the rotating part 53 is longitudinally connected with an unlocking sheet 56 in a sliding manner; an unlocking insertion column 561 which is longitudinally connected with the limiting through hole 532 in a sliding mode and is located in the limiting through hole 532 is formed at the upper end of the unlocking piece 56.

The upper end of the brush 41 is located under the unlocking sheet 56 and is formed with an upper top convex strip 411.

In a natural state, the elastic chuck 523 is clamped with the limiting through hole 532, and the rotating part 53 cannot rotate relative to the overturning part 52.

When the collodion 55 abuts against the brush 41 and is pressed down, the upward protruding strip 411 enables the unlocking sheet 56 to slide upwards, so that the elastic chuck 523 leaves the limiting through hole 532, and the rotating part 53 can rotate relative to the turning part 52.

A central rotating hole 522 is formed in the center of the lower end of the turning part 52; a central rotation post 535 rotatably connected to the central rotation hole 522 is formed at the center of the upper end of the rotation portion 53.

One end of the collodion board 54 close to the rotating part 53 is respectively formed with a limiting clamping groove 543; the rotating portion 53 is provided with a self-locking portion 57 which can be respectively clamped with the limiting clamping grooves 543.

The self-locking part 57 includes two chuck heads 571 that can be respectively clamped with the limit clamping groove 543 and a second spring 572 that is fixedly connected between the two chuck heads 571.

A self-locking through groove 533 which penetrates through the rotating part 53 is formed at the center of one end of the rotating part 53, which is close to the collodion board 54; the self-locking part 57 is located in the self-locking through groove 533, and the clamp 571 respectively penetrates out of two ends of the self-locking through groove 533; due to the elastic force of the second spring 572, the chuck 571 always abuts against the collodion plate 54.

In a natural state, the chuck 571 is clamped with the limit clamping groove 543, and the two collodion boards 54 can keep relatively parallel.

When squeezing, the chuck 571 is separated from the limit slot 543, and the collodion plate 54 can rotate relative to the rotating part 53.

Two ends of the rotating part 53 are respectively formed with symmetrically arranged rotating seats 531; the collodion plate 54 is formed with rotation columns 541 which are rotatably connected with the rotating base 531 near the rotating base 531.

A limiting block 542 is formed at the upper end of the collodion board 54 far away from the rotating part 53; when the collodion 55 is pressed down into the wringing assembly 2 and moves to the limit block 542 to abut against the wringing roller 22, the collodion mop 5 moves downwards to the limit position.

The power accumulating assembly 3 comprises an eccentric wheel 37 positioned below the brush 41 and used for driving the brush 41 to horizontally move along the length direction of the barrel body 10, and a power accumulating gear 36 positioned inside the eccentric wheel 37 and connected with the eccentric wheel 37 in a one-way transmission manner; a clockwork spring 363 for driving the power accumulating gear 36 to rotate is arranged in the power accumulating gear 36 and is positioned below the eccentric wheel 37.

A driving column 371 is formed at the non-circle center position of the upper end of the eccentric wheel 37; the lower end of the brush 41 is formed with a driving sliding groove 412 slidably connected to the driving post 41.

When the eccentric wheel 37 rotates, the driving rod 371 drives the driving sliding groove 412 to make the brush 41 reciprocate horizontally along the length direction of the tub 10.

An upper convex ring 361 concentric with the power accumulating gear 36 is formed at the upper end of the power accumulating gear 36; the clockwork spring 363 is arranged in the upper convex ring 361; one end of the tail end of the clockwork spring 363 is fixedly connected with the lower baffle cover 38, and the other end of the tail end of the clockwork spring 363 is fixedly connected with the power storage gear 36.

The power accumulating gear 36 and the eccentric wheel 37 are rotationally connected in the rotating bin 108; a first sealing rotating hole 1081 penetrating through the rotating bin 108 is formed at the top end in the rotating bin 108, and a sealing ring 374 which is concentric with the eccentric wheel 37 and is in sealing and rotating connection with the first sealing rotating hole 1081 is formed at the upper end of the eccentric wheel 37; the drive post 371 is located within the seal ring 374.

The collodion 55 is pressed down against the brush 41, and the brush 41 moves down to be separated from the stopper 1012 and the first spring 422 is compressed. The eccentric wheel 37 is rotated forward by the elastic force of the spring 363, the driving column 371 drives the driving sliding groove 412 to reciprocate horizontally, so that the brush 41 reciprocates horizontally, and the brush 41 and the collodion 55 move relatively to each other, so that the collodion 55 is brushed clean.

The collodion 55 no longer abuts against the brush 41, and the brush 41 moves upwards to the limit position under the elastic force of the first spring 422 and is located between the adjacent stop tabs 1012.

A plurality of elastic pawls 362 are uniformly arranged on the outer wall of the power storage gear 36 along the circumferential direction; a ratchet 373 in one-way transmission connection with the elastic pawl 362 is formed in the eccentric wheel 37.

When the power accumulating gear 36 rotates in the forward direction, the eccentric wheel 37 does not rotate, so that the clockwork spring 363 accumulates power.

When the power accumulating gear 36 rotates reversely, the eccentric wheel 37 rotates synchronously, thereby driving the brush 41 to reciprocate horizontally.

The elastic pawl 362 is positioned on the outer wall of the upper convex ring 361; a torsion spring is arranged between the elastic pawl 362 and the upper convex ring 361, and when the power storage gear 36 rotates in the positive direction, the elastic pawl 362 is not meshed with the ratchet 373; when the power storage gear 36 rotates in the reverse direction, the elastic pawl 362 engages with the ratchet 373, i.e., with the eccentric wheel 37.

Two limiting clamping heads 372 which are symmetrically arranged are formed at the upper part of the outer wall of the eccentric wheel 37; the lower end of the barrel body 10 is fixedly connected with an elastic stop 107 which can limit the limiting chuck 372 to pass through.

When the elasticity of the spiral spring 363 is large enough, the limit chuck 372 can pass through the elastic stopper 107.

When the elasticity of the spiral spring 363 is reduced to the point that the limit chuck 372 cannot pass through the elastic stopper 107, the two ends of the brush 41 in the length direction are overlapped.

The elastic block 107 is fixedly connected to the top end in the rotating bin 108.

The power accumulating assembly 3 comprises a driving shaft 34 which is positioned in the barrel body 10 and is in transmission connection with the power accumulating gear 36 for accumulating power of the power accumulating gear 36, a driving ratchet wheel 33 which is positioned in the driving shaft 34 and is longitudinally and slidably connected with the driving shaft 34, and a spiral sheet 311 which is positioned in the driving shaft 34 and is longitudinally and slidably connected with the driving shaft 34 and is used for driving the driving ratchet wheel 33 to rotate.

The driving shaft 34 is rotatably connected in the rotating bin 108; a second sealing rotating hole 1082 penetrating through the rotating bin 108 is formed at the top end in the rotating bin 108; the driving column 34 is connected in the second sealing rotation 1082 in a sealing rotation manner, and the rotating column 34 penetrates upwards into the barrel body 10.

A driving gear 341 concentric with the driving shaft 34 is formed at the lower end of the driving shaft 34; a transmission gear 35 rotationally connected with the driving gear 341 is rotationally connected in the rotating bin 108; a transmission pinion 351 concentric with the transmission gear 35 is formed at the lower end of the transmission gear 35; the diameter of the transmission pinion 351 is larger than that of the transmission gear 35, so that the torque of the driving shaft 34 is amplified, and the power storage gear 36 stores power more laborsavingly.

A driven ratchet wheel 342 which is in transmission connection with the driving ratchet wheel 33 is formed in the driving shaft 34 and is positioned below the driving ratchet wheel 33; a driving groove 311 which penetrates through the driving ratchet wheel 33 and is longitudinally and slidably connected with the spiral sheet 311 is formed in the center of the upper end of the driving ratchet wheel 33.

When the spiral piece 311 moves downward, the driving groove 311 rotates relatively in the spiral direction of the spiral piece 311 in the forward direction, and the driving ratchet wheel 33 engages with the driven ratchet wheel 342, so that the driving shaft 34 rotates in the forward direction.

When the spiral piece 311 moves upward, the driving groove 311 relatively rotates in the reverse direction in the spiral direction of the spiral piece 311, the driving ratchet wheel 33 moves upward to be separated from the driven ratchet wheel 342, and the driving shaft 34 does not rotate.

The upper end of the spiral sheet 311 is fixedly connected with a lower pressing sheet 31; the lower pressing piece 31 is positioned right below the water squeezing jack 213; and a third spring 32 is fixedly connected between the lower end of the water squeezing frame 21 and the lower end of the lower pressing sheet 31 close to four corners.

Sliding columns 212 are formed at the lower end of the wringing frame 21 close to the four corners; the third spring 32 is arranged on the outer wall of the sliding column 212; the third spring 32 is fixedly connected with the lower end of the sliding column 212.

When the rotating part 53 is pressed down, it is pressed against the lower pressing piece 31 and moves downward; the rotating part 53 is lifted up, and the lower pressing piece 31 is moved upward by the elastic force of the third spring 32.

The upper part of the barrel body 10 is rotatably connected with a handle 11.

A handle rotating hole 105 is formed in the center of the upper part of the side wall of the barrel body 10 in the length direction; handle rotating heads 111 which are rotatably connected with the handle rotating holes 105 are formed at the tail ends of the two ends of the handle 11; the handle 11 makes the movement of the tub 10 more convenient.

A water level mark 104 is formed on the side wall of the barrel body 10 at the limit position of the downward movement of the lower pressure plate 31; the water level mark 104 cannot be exceeded by adding water into the barrel body 10; so that the collodion 55 is pressed down and squeezed to be dry, and does not contact with water, and a better squeezing effect can be obtained.

In an initial state, the brush 41 is located at the upper end limit position, two ends of the brush 41 in the length direction abut against the stop piece 1012, the lower pressing plate 31 is located at the upper end limit, the clockwork spring 363 has enough elasticity, for the collodion mop, the upper end of the unlocking plug 561 abuts against the elastic chuck 523, the elastic chuck 523 is located in the limit through hole 532, and the chuck 571 is located in the limit clamping groove 543.

When the product is used for brushing, the handle 11 is held by hands, the barrel body 10 is placed on a horizontal plane, and a proper amount of water is added into the barrel body 10, so that the water level reaches the water level mark 104. The mop rod 58 is held by hand, the U-shaped frame 51 is put into the barrel body 10 to ensure that the collodion 55 is completely submerged in water, and the collodion 55 is rinsed in the water. The collodion 55 is pressed against the brush 41, and the brush 41 moves downward to be separated from the stopper 1012 and the first spring 422 is compressed. The eccentric wheel 37 is rotated forward by the spring force of the spring 363, and the driving rod 371 drives the driving slide groove 412 to reciprocate horizontally, so that the brush 41 reciprocates horizontally. The brush 41 is in transmission connection with the other brush 41 through the linkage piece 42, when the brush 41 moves to one side, the linkage piece 42 rotates around the linkage piece positioning column 102 to drive the other brush 41 to move to the other side, so that the two brushes 41 respectively reciprocate synchronously in two opposite directions. The relative movement between the brush 41 and the collodion 55 causes the collodion 55 to be brushed clean. In the process of rotation of the eccentric wheel 37, the initial elastic force of the spiral spring 363 can enable the limit chuck 372 to continue to rotate through the elastic stopper 107, the elastic deformation of the spiral spring 363 is gradually reduced, the elasticity is reduced, when the elastic force of the spiral spring 363 is insufficient to enable the limit chuck 372 to pass through the elastic stopper 107, the movement of the hairbrush 41 is stopped, and at the moment, two ends of the two hairbrushes 41 in the length direction are overlapped.

After the brushing is finished, the mop rod 58 is held to press the U-shaped frame 51 downwards, so that the collodion 55 is compressed, the upward ejection convex strip 411 upwards compresses the unlocking sheet 56 through the collodion 55, the unlocking plug 561 moves upwards, and the elastic chuck 523 is ejected out of the limiting through hole 532 upwards. While holding the U-shaped frame 51 down and rotating the handle bar 58 ninety degrees, the flip portion 52 rotates relative to the rotating portion 53 such that the resilient catch 523 snaps into the retention notch 534. The mop rod 58 is removed upward and the collodion 55 no longer abuts the brush 41, so that the brush 41 moves upward to the limit position between the adjacent stoppers 1012 under the elastic force of the first spring 422. The wringing frame 21 abuts against the collodion board 54 in the lifting process, so that the turning part 52 rotates for a certain angle around the rotating hole 511, the collodion board 54 rotates to pass through the U-shaped frame 51, the turning part 52 is positioned below, and the collodion 55 is positioned above.

Then the turning part 52 is abutted against the lower pressing plate 31, the mop rod 58 is pressed downwards, the collodion plates 54 are abutted against the wringing roller 22 and move downwards relative to the wringing roller 22, the chuck 571 leaves the limit clamping groove 543 while the second spring 572 enters a compressed state, the two collodion plates 54 are turned upwards synchronously, so that the included angle between the two collodion plates 54 is reduced, the collodion 55 is compressed and dehydrated, and meanwhile the third spring 32 enters a compressed state. The mop rod 58 is lifted upwards, the lower pressing plate 31 moves upwards under the elastic force of the third spring 32, the labor is saved in the process of lifting the mop rod 58, the elastic deformation of the collodion 55 is recovered, and the collodion plate 54 is relatively parallel after the collodion plate 54 is lifted. The mop rod 58 is pressed down 5-7 times in a reciprocating way, and the collodion 55 can be squeezed to be dry. The collodion mop 5 is taken out for use, the collodion 55 is pressed against the ground, the collodion plate 54 is turned outwards to the limit position, the chuck 571 enters the limit clamping groove 543 again, the collodion plate 54 and the rotating part 53 are relatively fixed, the collodion 55 always abuts against the ground when the ground is wiped, the collodion plate cannot rotate, meanwhile, the rotating mop rod 58 enables the overturning part 52 to rotate ninety degrees relative to the rotating part 53, the elastic chuck 523 enters the limit through hole 532 again under the elastic action of the second spring 572, and the overturning part 52 cannot rotate relative to the rotating part 53.

During the downward movement of the lower pressure plate 31, the spiral piece 311 is longitudinally slidably connected in the driving groove 331, so that the driving ratchet wheel 33 positively rotates relative to the spiral piece 311 during the downward movement of the lower pressure plate 31. When the driving ratchet wheel 33 rotates in the forward direction, the driven ratchet wheel 342 rotates in the forward direction synchronously, and during the upward movement of the lower pressing plate 31, the driving ratchet wheel 33 moves upward to be separated from the driven ratchet wheel 342, so that when the driving ratchet wheel 33 rotates in the reverse direction, the driven ratchet wheel 342 does not rotate. The driven ratchet gear 342 rotates in the forward direction so that the driving column 34 rotates in the forward direction, and the driving gear 341 engages with the transmission gear 35 while maintaining the synchronous reverse rotation with the driving gear 341. The transmission gear 35 is meshed with the power storage gear 36, so that the power storage gear 36 and the driving gear 341 synchronously rotate in the positive direction, the spring 363 is elastically deformed when the power storage gear 36 rotates so as to store power, and the pressing-down process of squeezing is not enough to enable the spring 363 to reach the elastic limit. The elastic pawl 362 and the ratchet 373 form a ratchet mechanism, the eccentric wheel 37 does not rotate during the forward rotation of the power storage gear 36, and the eccentric wheel 37 rotates forward during the reverse rotation of the power storage gear 36. The wringing process allows the spring 363 to accumulate the force in preparation for the next scrubbing of the collodion 55.

According to the invention, through the design of the rotating part 53, when the elastic chuck 523 is positioned in the limiting through hole 532, the turnover part 52 cannot rotate, the collodion mop 5 can be used for cleaning or brushing, when the elastic chuck 523 is positioned in the limiting notch 534, the turnover part 52 can rotate upwards, and when the collodion 55 rotates to the upper part of the rotating part 53, the collodion mop 5 can be used for wringing operation.

According to the invention, through the design of the power accumulating assembly 3, when two ends of the brush 41 in the length direction abut against the stop piece 1012, the downward movement of the lower pressing plate 31 can enable the spring 363 to accumulate power, and when two ends of the brush 41 in the length direction do not abut against the stop piece 1012, the elastic force accumulated by the spring 363 can enable the eccentric wheel 37 to rotate, so as to drive the brush 41 to reciprocate to scrub the collodion 55.

According to the invention, through the design of the elastic stop block 107, when the elasticity of the clockwork spring 363 is large enough, the eccentric wheel 37 rotates to enable the limit chuck 372 to pass through, so that the hairbrush 41 reciprocates, and when the elasticity of the clockwork spring 363 is not large enough, the eccentric wheel 37 rotates to enable the limit chuck 372 to abut against the elastic stop block 107 and stops moving, at the moment, two ends of the hairbrush 41 in the length direction are respectively overlapped, and can move upwards under the action of the elasticity of the first spring 422, so that two ends of the hairbrush 41 in the length direction abut against the stop piece 1012.

According to the invention, through the design of the lower pressing plate 31, when the collodion mop 5 is pressed down and lifted, the lower pressing plate 31 can be reset upwards to prepare for the next driving of the spiral piece 311, and the collodion mop 5 can be lifted more easily.

The mop squeezer is provided with the rollers which are arranged in pairs and used for squeezing the collodion, when the mop is pressed down to pass through the water squeezing assembly, the friction force is small, the operation is labor-saving, and the use is convenient. The cleaning brush has the advantages that the cleaning brush can be used for brushing the collodion without hands, attached stains which are difficult to wash away by water can be removed without manual operation, and the cleaning brush is convenient to use. The invention can accumulate the elastic force for driving the cleaning brush to move while squeezing the collodion, does not add a new operation step, and has simple use and convenient operation.

Claims (10)

1. A hand-free scrubbing and wringing collodion mop barrel kit comprises a barrel body and a collodion mop; the method is characterized in that: a brushing component for brushing the collodion mop is arranged at the bottom in the bucket body; the brushing assembly comprises two brushes horizontally arranged along the length direction of the barrel body and a linkage piece which is rotatably connected to the bottom in the barrel body and is respectively connected with the two brushes in a sliding manner;

the linkage piece enables the horizontal movement directions of the two hairbrushes to be opposite;

limiting pieces for limiting the upward movement of the brush are formed at the bottom of the barrel body close to the four corners; a first spring is arranged between the middle position of the lower end of the linkage piece and the bottom end in the barrel body; under a natural state, the first spring enables the brush to be upwards abutted against the limiting piece;

one end of the limiting piece close to the width direction of the barrel body is respectively provided with a stop piece; a force storage assembly capable of driving the cleaning brush to reciprocate horizontally along the length direction of the barrel body is arranged in the barrel body;

when two ends of the brush in the length direction respectively abut against the stop pieces, the brush cannot horizontally reciprocate;

when the two ends of the brush in the length direction are not abutted against the stop pieces, the brush can horizontally reciprocate;

the lower end of the collodion mop is provided with collodion; when the collodion is abutted against the hairbrush, the hairbrush which moves horizontally back and forth enables the collodion to be brushed cleanly;

a water squeezing component for squeezing the collodion cotton is arranged on one side of the upper part in the barrel body; the squeezing process of the collodion can enable the power storage component to store power.

2. A hands-free scrub wringer mop bucket, as in claim 1, wherein: the collodion mop comprises a U-shaped frame, a turning part horizontally arranged on a rotating shaft rotatably connected to the middle position of the lower part of the U-shaped frame, a rotating part vertically arranged on the rotating shaft rotatably connected to the central position of the lower end of the turning part, and two collodion plates symmetrically arranged and respectively rotatably connected to two ends of the rotating part;

the collodion is respectively and fixedly connected with the lower ends of the two collodion plates; when the two collodion plates rotate oppositely, the collodion plates extrude the collodion;

the wringing component comprises a wringing frame fixedly connected to one side of the upper part in the barrel body and a plurality of wringing rollers which are rotatably connected to the upper part of the wringing frame and are symmetrically arranged for wringing the collodion cotton.

3. A hands-free scrub wringer mop bucket, as in claim 2, wherein: two elastic clamping heads which are symmetrically arranged are formed at the lower end of the turnover part; two limiting through holes and two limiting notches which can be respectively clamped with the elastic clamping heads are formed at the upper end of the rotating part; a connecting line between the two limiting through holes is vertical to a connecting line between the two limiting notches;

when the elastic clamping head is clamped with the limiting through hole, the lower end of the U-shaped frame abuts against the collodion board, and the overturning part cannot rotate relative to the U-shaped frame;

when the elasticity dop with during spacing notch joint, U type frame lower extreme not with the glued membrane board offsets, upset portion can be relative U type frame is rotatory to be made the glued membrane rotate to being located the rotating part top.

4. A hands-free scrub wringer mop bucket, as in claim 3, wherein: the lower end of the rotating part is longitudinally connected with an unlocking sheet in a sliding manner; the upper end of the unlocking sheet is provided with an unlocking insertion column which is longitudinally connected with the limiting through hole in a sliding manner and is positioned in the limiting through hole;

an upper top convex strip is formed at the upper end of the brush and is positioned under the unlocking sheet;

in a natural state, the elastic chuck is clamped with the limiting through hole, and the rotating part cannot rotate relative to the overturning part;

when the collodion and the brush are tightly abutted and pressed down, the upward ejection convex strip enables the unlocking sheet to slide upwards, so that the elastic chuck leaves the limiting through hole, and the rotating part can rotate relative to the overturning part.

5. A hands-free scrub wringer mop bucket, as in claim 2, wherein: one end of the collodion board close to the rotating part is respectively formed with a limiting clamping groove; the rotating part is internally provided with an automatic locking part which can be respectively clamped with the limiting clamping grooves;

the self-locking part comprises two clamping heads which can be clamped with the limiting clamping grooves respectively and a second spring which is fixedly connected between the two clamping heads;

in a natural state, the clamping head is clamped with the limiting clamping groove, and the two collodion boards can keep relatively parallel;

when carrying out the wringing, the dop with spacing draw-in groove separation, the collodion board can be relative the rotating part is rotatory.

6. A hands-free scrub wringer mop bucket, as in claim 1, wherein: the power accumulating assembly comprises an eccentric wheel which is positioned below the brush and used for driving the brush to horizontally move along the length direction of the barrel body and a power accumulating gear which is positioned in the eccentric wheel and is in one-way transmission connection with the eccentric wheel; a clockwork spring for driving the power accumulating gear to rotate is arranged in the power accumulating gear and is positioned below the eccentric wheel;

a driving column is formed at the non-circle center position of the upper end of the eccentric wheel; a driving sliding chute which is connected with the driving column in a sliding manner is formed at the lower end of the hairbrush;

when the eccentric wheel rotates, the driving column drives the driving sliding groove to enable the brush to horizontally reciprocate along the length direction of the barrel body.

7. A hands-free scrub wringer mop bucket, as in claim 6, wherein: a plurality of elastic pawls are uniformly arranged on the outer wall of the power storage gear along the circumferential direction; a ratchet wheel in one-way transmission connection with the elastic pawl is formed in the eccentric wheel;

when the power accumulating gear rotates in the positive direction, the eccentric wheel does not rotate, so that the clockwork spring accumulates power;

when the power accumulating gear rotates reversely, the eccentric wheel rotates synchronously, and the brush is driven to horizontally reciprocate.

8. A hands-free scrub wringer mop bucket, as in claim 6, wherein: two limiting chucks which are symmetrically arranged are formed at the upper part of the outer wall of the eccentric wheel; the lower end of the barrel body is fixedly connected with an elastic stop block which can limit the limiting chuck to pass through;

when the elasticity of the clockwork spring is large enough, the limiting chuck can pass through the elastic stop block;

when the elasticity of the clockwork spring is reduced to the limit chuck and the limit chuck can not pass through the elastic stop block, the two ends of the hairbrush in the length direction are overlapped.

9. A hands-free scrub wringer mop bucket, as in claim 6, wherein: the power accumulating assembly comprises a driving shaft which is positioned in the barrel body and is in transmission connection with the power accumulating gear and used for accumulating power of the power accumulating gear, a driving ratchet which is positioned in the driving shaft and is longitudinally and slidably connected with the driving shaft, and a spiral sheet which is positioned in the driving shaft and is longitudinally and slidably connected with the driving shaft and used for driving the driving ratchet to rotate;

a driven ratchet wheel in transmission connection with the driving ratchet wheel is formed in the driving shaft and is positioned below the driving ratchet wheel; a driving groove which penetrates through the driving ratchet wheel and is longitudinally connected with the spiral sheet in a sliding manner is formed in the center of the upper end of the driving ratchet wheel;

when the spiral piece moves downwards, the driving groove rotates along the spiral direction of the spiral piece in a relative positive direction, and the driving ratchet wheel is meshed with the driven ratchet wheel so as to enable the driving shaft to rotate in the positive direction;

when the spiral piece moves upwards, the driving groove rotates oppositely along the spiral direction of the spiral piece, the driving ratchet wheel moves upwards to be separated from the driven ratchet wheel, and the driving shaft does not rotate;

the upper end of the spiral sheet is fixedly connected with a lower pressing sheet; the lower pressing sheet is positioned right below the wringing jack; a third spring is fixedly connected between the lower end of the water squeezing frame and the lower end of the lower pressing sheet close to four corners;

when the rotating part is pressed downwards, the rotating part is abutted against the lower pressing sheet and moves downwards; the rotating part is lifted up, and the lower pressing plate moves upwards under the action of the elastic force of the third spring.

10. A hands-free scrub wringer mop bucket, as in claim 1, wherein: the upper part of the barrel body is rotatably connected with a handle.

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