CN213309524U - Mop external member and dewatering component thereof - Google Patents

Abstract

The utility model discloses a mop external member and a dewatering component thereof, wherein the dewatering component comprises a bracket, and a through hole for a mop plate to pass through is arranged on the bracket; a water squeezing component is arranged on one side of the support positioned at the through hole, and an abutting component is arranged on the other side of the support positioned at the through hole in a sliding manner; when the abutting part is positioned at the initial position, a cleaning opening for the mop plate to pass through without obstruction is formed between the abutting part and the water squeezing part; when the abutting part is positioned at the water squeezing position, a water squeezing opening for squeezing and dehydrating the mop plate is formed between the abutting part and the water squeezing part; the leaning component is provided with a stressed part, and when the stressed part is subjected to downward external force, the leaning component moves to the wringing position from the initial position. Because the mop squeezes water in the upward pulling process instead of squeezing water in the conventional downward pushing process, a separate water squeezing bucket is not needed, the volume of the bucket body is reduced, and the packaging, transportation and storage cost is also reduced.

Description

Mop external member and dewatering component thereof

Technical Field

The utility model belongs to the burnisher field, concretely relates to supporting mop and mop bucket structure of using.

Background

The existing flat mop bucket is generally respectively used for cleaning and dewatering a flat mop by arranging an independent cleaning area and a water squeezing area, and the mop bucket has the advantage of convenient use, but has the defects that the mop bucket has larger integral volume and occupies larger space due to the independent cleaning area and the water squeezing area, and the manufacturing cost of the bucket is correspondingly higher.

SUMMERY OF THE UTILITY MODEL

The utility model discloses the technical problem that will solve is: aiming at the defects in the prior art, the mop kit integrating the cleaning area and the water squeezing area into a single barrel and the matched dewatering component thereof are provided.

In order to realize the purpose of the utility model, the following technical scheme is adopted to realize: a dewatering component of a mop comprises a bracket, wherein a penetrating port for a mop plate to penetrate through is arranged on the bracket;

a water squeezing component is arranged on one side of the support positioned at the through hole, and an abutting component is arranged on the other side of the support positioned at the through hole in a sliding manner;

the abutting part is provided with an initial position far away from the wringing part and a wringing position close to the wringing part; when the abutting part is positioned at the initial position, a cleaning opening for the mop plate to pass through without obstruction is formed between the abutting part and the water squeezing part; when the abutting part is positioned at the water squeezing position, a water squeezing opening for squeezing and dehydrating the mop plate is formed between the abutting part and the water squeezing part;

the abutting part is provided with a stressed part, and when the stressed part is subjected to downward external force, the abutting part moves to the wringing position from the initial position.

A reset component for driving the abutting component to reset from the wringing position to the initial position is connected between the abutting component and the bracket;

or the abutting part is provided with a floater, so that the abutting part can be reset to the initial position from the wringing position under the buoyancy action of water.

Preferably, the method comprises the following steps: the bracket is provided with a guide groove in sliding connection with the abutting part, and the guide groove comprises a first groove part and a second groove part which are communicated with each other; the first groove part is obliquely and downwards arranged from one side far away from the through opening to one side close to the through opening.

Preferably, the method comprises the following steps: the abutting part is provided with a guide part which is connected with the guide groove in a sliding or rolling manner; one end, far away from the first slot part, of the second slot part forms a wringing positioning part, and when the guide part is located in the wringing positioning part, the abutting part is located at a wringing position.

The first groove part enables the width difference value of the cleaning opening and the water squeezing opening to be larger, namely, when the mop plate penetrates through the cleaning opening to be cleaned, the mop can be prevented from being in contact with the stress part on the leaning part, and the interference of the leaning part on the mop cleaning process is avoided. The second groove part is used for positioning the abutting part, specifically, the connecting position of the first groove part and the second groove part is a dead point position, and the abutting part can cross the dead point position in the process of sliding from the first groove part to the second groove part and is finally positioned at the end position of the second groove part. Because the second groove part is obliquely arranged, the second groove part has a component along the horizontal direction, when the mop plate is clamped in the water squeezing opening, the abutting part cannot enter the first groove part from the second groove part beyond the dead point position, and therefore the abutting part can be temporarily and stably positioned in the second groove part in the mop water squeezing process.

Preferably, the method comprises the following steps: the support is including the lid to and connect the mounting panel of two symmetry settings at the lid lower extreme, every be equipped with respectively on the mounting panel with support to lean on part sliding connection's guide way.

Preferably, the method comprises the following steps: the water squeezing component is a water squeezing roller which is rotatably connected with the two mounting plates through a rotating shaft; or the water squeezing component is a sheet-shaped water squeezing plate, and the water squeezing plate is fixedly connected with the mounting plate.

Preferably, the method comprises the following steps: the rotating shaft is rotationally connected with the tubular wringing roller; or the rotating shafts are integrally formed at two ends of the wringing roller.

When the rotating shaft is formed at two ends of the wringing roller, the wringing roller is firstly rotatably connected with the mounting plates at two sides, and then the two mounting plates are connected with the cover body; or after one mounting plate is connected with the cover body, the rotating shaft of the water squeezing roller is connected with the two mounting plates, and then the other mounting plate is connected with the cover body.

Preferably, the method comprises the following steps: the abutting part is provided with a groove body with a downward opening, and the groove body forms the floater capable of floating on the water surface.

The initial position of the abutting part is higher than the water squeezing position, so that the abutting part can be designed into a structural form of a floater, the abutting part is reset by utilizing the buoyancy of water in the barrel, the resetting part such as a spring is omitted, and the phenomenon that dirt is adhered or wound on the resetting part is well avoided.

Preferably, the method comprises the following steps: the leaning component is provided with a mop rod containing opening, and the stress part is positioned at the bottom of the mop rod containing opening.

The utility model also provides a mop kit, which comprises a mop barrel and a mop, wherein the mop barrel comprises a barrel body and a dewatering component arranged on the barrel body;

the mop comprises a mop rod and a mop plate which is rotatably connected to the lower end of the mop rod;

the mop can be connected with or abut against the stress part, and when the mop moves downwards, the mop can drive the abutting part to move from the initial position to the water squeezing position through the stress part.

Preferably, the method comprises the following steps: when the mop drives the abutting part to reach the water squeezing position, the upper end part of the mop plate is just opposite to or close to the water squeezing part.

Compared with the prior art, the beneficial effects of the utility model are that: the dewatering component only adopts the leaning component as the movable component, and other components are relatively fixed components, so that the structural stability is good. When leaning on the part and being in initial condition, the mop can be in the barrel that stretches into dehydration subassembly below of unimpeded washs, after the washing finishes, can drive through the mop and lean on the part by initial position switch to crowded water position to make the mop board press from both sides tightly in crowded water mouthful, only need vertical pull-up mop can accomplish the dehydration of mop board, convenient operation. Because the mop squeezes water in the upward pulling process instead of squeezing water in the conventional downward pushing process, a separate water squeezing bucket is not needed, the volume of the bucket body is reduced, and the packaging, transportation and storage cost is also reduced.

Drawings

Fig. 1 is a schematic structural view of a mop which extends into a barrel body through a penetrating opening for cleaning.

Fig. 2 is a schematic structural view of the mop in a state of being engaged with the abutting member in an initial state.

Fig. 3 is a schematic structural diagram of the mop moving downwards to drive the abutting part to move from the initial state to the water squeezing state.

Fig. 4 is a schematic view showing a structure in which the mop is pulled up for dewatering while the abutting member is in the wringing state.

FIG. 5 is a schematic view of the mop plate rotated relative to the mop bar to a cleaning or dewatering position.

Fig. 6 and 7 are schematic structural views of the dewatering assembly when the abutting component is in the initial state.

Fig. 8 is a schematic view of the dewatering assembly with the abutting member in the wringing condition.

Fig. 9 is a schematic structural view of the abutting member.

1. A barrel body; 2. a mop; 21. a mop rod; 22. a plate body; 221. rotating the head; 23. a wipe; 3. a support; 31. a cover body; 30. perforating; 32. mounting a plate; 33. a guide groove; 331. a first groove portion; 332. a second groove portion;

4. an abutting member; 40. the mouth of the mop rod is held; 41. a guide portion; 42. a force receiving portion; 43. a trough body; 5. a wringing roller; 51. a rotating shaft; 6. a brush; 7. a handle; 8. a spring.

Detailed Description

Example 1

Referring to fig. 1 to 9, the present embodiment is a dewatering assembly for a mop, which comprises a support 3, wherein the support is provided with a through hole 30 for a mop plate to pass through; and a water squeezing component is arranged on one side of the support positioned at the through hole, and an abutting component 4 is arranged on the other side of the support positioned at the through hole in a sliding manner.

The abutting part is provided with an initial position far away from the wringing part and a wringing position close to the wringing part; when the abutting part is positioned at the initial position, a cleaning opening for the mop plate to pass through without obstruction is formed between the abutting part and the water squeezing part; when the abutting part is positioned at the water squeezing position, a water squeezing opening for squeezing and dewatering the mop plate is formed between the abutting part and the water squeezing part.

The abutting part is provided with a stress part 42, and when the stress part is acted by downward external force, the abutting part moves from the initial position to the wringing position.

As shown in fig. 6 and 7, the bracket is provided with a guide groove 33 slidably connected to the abutting member, and the guide groove includes a first groove portion 331 and a second groove portion 332 communicated with each other; the first groove part is obliquely and downwards arranged at one side, far away from the penetrating opening, of the first groove part, and the second groove part is obliquely and downwards arranged at one side, far away from the penetrating opening, of the second groove part.

The abutting part is provided with a guide part 41 which is connected with the guide groove in a sliding or rolling manner; one end, far away from the first slot part, of the second slot part forms a wringing positioning part, and when the guide part is located in the wringing positioning part, the abutting part is located at a wringing position.

The first groove part enables the width difference value of the cleaning opening and the water squeezing opening to be larger, namely, when the mop plate penetrates through the cleaning opening to be cleaned, the mop can be prevented from being in contact with the stress part on the leaning part, and the interference of the leaning part on the mop cleaning process is avoided. The second groove part is used for positioning the abutting part, specifically, the connecting position of the first groove part and the second groove part is a dead point position, and the abutting part can cross the dead point position in the process of sliding from the first groove part to the second groove part and is finally positioned at the end position of the second groove part. Because the second groove part is obliquely arranged, the second groove part has a component along the horizontal direction, when the mop plate is clamped in the water squeezing opening, the abutting part cannot enter the first groove part from the second groove part beyond the dead point position, and therefore the abutting part can be temporarily and stably positioned in the second groove part in the mop water squeezing process.

Further, the support 3 includes a cover 31 and two symmetrically disposed mounting plates 32 connected to the lower end of the cover, and each of the mounting plates is provided with an upper guide groove 33 and a lower guide groove 33 which are slidably connected to the abutting members.

The water squeezing component is a water squeezing roller 5 which is rotatably connected with the two mounting plates through a rotating shaft 51; the rotating shaft is rotationally connected with the tubular wringing roller; or the rotating shafts are integrally formed at two ends of the wringing roller.

When the rotating shaft is formed at two ends of the wringing roller, the wringing roller is firstly rotatably connected with the mounting plates at two sides, and then the two mounting plates are connected with the cover body; or after one mounting plate is connected with the cover body, the rotating shaft of the water squeezing roller is connected with the two mounting plates, and then the other mounting plate is connected with the cover body.

Or the water squeezing component is a sheet-shaped water squeezing plate, and the water squeezing plate is fixedly connected with the mounting plate.

Further, the leaning component is provided with a mop rod containing opening 40, and the stress part is located at the bottom of the mop rod containing opening.

In addition, a brush is arranged on the bracket below the water squeezing part and is used for brushing and cleaning the wiping materials on the mop plate when the mop is cleaned.

And a reset component for driving the abutting component to reset to the initial position from the wringing position is connected between the abutting component and the bracket. As shown in fig. 7 and 8, the return component is a spring 8, and the spring is connected between the mounting plate and the abutting component. As shown in fig. 8, when the abutting part is located at the water squeezing position, the spring is in a stretching state, and after the mop plate is separated from the water squeezing opening, the spring is shortened under the action of the self elastic force, and the abutting part is pulled to return to the initial position. The reset component can also be a torsion spring, an elastic rope and the like, and the reset component can play a role in driving the leaning component to reset as long as the installation position of the reset component is adjusted.

Or the abutting part is provided with a floater, so that the abutting part can be reset to the initial position from the wringing position under the buoyancy action of water.

As shown in fig. 9, the abutting member is provided with a groove 43 having a downward opening, and the groove forms the float capable of floating on the water surface.

The initial position of the abutting part is higher than the water squeezing position, so that the abutting part can be designed into a structural form of a floater, the abutting part is reset by utilizing the buoyancy of water in the barrel, the resetting part such as a spring is omitted, and the phenomenon that dirt is adhered or wound on the resetting part is well avoided.

Example 2

The embodiment is a mop kit adopting the dewatering component in the embodiment 1, and the mop kit comprises a mop bucket and a mop 2, wherein the mop bucket comprises a bucket body 1 and the dewatering component arranged on the bucket body. The mop bucket further comprises a handle 7, inserting shafts are arranged at two ends of the handle 7 and penetrate through the side faces of the bucket body and the cover body at the same time, and therefore the dewatering assembly is fixedly connected with the bucket body relatively.

The mop 2 comprises a mop rod 21 and a mop plate which is rotatably connected to the lower end of the mop rod; the mop plate comprises a plate body 22 and a wiping object 23 connected to the lower end of the plate body 22.

The mop can be connected with or abut against the stress part, and when the mop moves downwards, the mop can drive the abutting part to move from the initial position to the water squeezing position through the stress part. Specifically, the mop is abutted against the stress part through the lower end of the mop rod.Or A rotating head 221 is connected to the plate body, the lower end of the mop rod is rotatably connected with the rotating head, and the mop rotates The head abuts against the force receiving portion.

Further, in order to reduce the resistance when the mop is pulled up, the side of the abutting part facing the water squeezing part can be provided with The roller is matched with the back of the mop plate in a rolling way. In order to reduce the resistance of the abutment member to movement relative to the bracket, the guide portion is also provided Can be matched with the guide groove in a rolling way by arranging the roller.

When the mop drives the abutting part to reach the water squeezing position, the upper end part of the mop plate is just opposite to or close to the water squeezing part. The upper end of the mop plate is in a cleaning and dewatering state of the mop, namely the mop rod is in a roughly vertical state, the mop plate rotates to be roughly parallel to the mop rod, namely, the mop plate is also in a roughly vertical state, when the mop plate is used for mopping, the wiping materials at the lower end of the mop plate are abutted against the ground, and the mop rod can be in any angle according to requirements.

Specifically, when the wiping material is the collodion, the collodion has larger elasticity and deformation amplitude and larger water absorption capacity, so when the abutting part reaches the water squeezing position under the driving of the mop, the position of the water squeezing part relative to the support is designed to be just used for clamping the upper end of the mop plate, all positions of the collodion from top to bottom can be squeezed by the water squeezing part, and the phenomenon that excessive water is remained in the collodion to influence the squeezing degree is avoided. When the water squeezing part is provided with a plurality of water squeezing rollers, the leaning part is positioned in a water squeezing state, at least the water squeezing rollers positioned relatively below clamp the upper end of the mop plate, and the two water squeezing rollers can also clamp the upper end of the mop plate.

When the mop is a mop, the position of the wringing component relative to the bracket is designed to be just above and near the upper end of the mop plate when the abutment component is driven by the mop to the wringing position, since the mop cloth is less resilient and absorbent and is harder to wring than the collodion. In other words, since the elasticity of the mop cloth is small, if the wringing member grips the upper end of the mop plate at the wringing position, the driving force required by the wringing member is excessively large, and the operation is laborious when the mop is pulled up to wring, it is preferable that the wringing member does not grip the upper end of the mop plate but is located in the vicinity of the upper end of the mop plate when the abutting member reaches the wringing position, which also reduces the resistance when the abutting member reaches the wringing position. And in the process of pulling up the mop after the abutting part reaches the water squeezing position, even if a larger squeezing force is formed between the water squeezing part and the mop plate, the squeezing force is approximately vertical to the direction of the mop plate, so that the upward pulling of the mop is not obviously influenced. And the water squeezing rollers and the rollers can form rolling fit with the two surfaces of the mop plate, so that the resistance of the mop when the mop is pulled upwards to squeeze water is further reduced.

When the mop kit is used, water is firstly filled in the barrel body to a position that the water level approximately exceeds the brush, then the mop plate is rotated to a state of being parallel to the mop rod, then one side of a mop wiping object faces the brush direction, the mop plate is extended into the barrel body from the penetrating port for cleaning as shown in figure 1, and the brush hair on the brush and the wiping object move relatively to cause dirt on the wiping object to fall off.

After the cleaning is finished, the rotating head on the mop plate is abutted against the upper end of the force bearing part on the abutting part as shown in fig. 2, then the mop rod is pushed downwards as shown in fig. 3, so that the rotating head pushes the abutting part to move from the initial position to the water squeezing position, namely, after the mop plate is clamped in the water squeezing port, the mop rod is pulled upwards as shown in fig. 4, and then the water in the wiping object can be squeezed out through the water squeezing part.

After the mop plate is separated from the water squeezing port upwards, the abutting part returns to the initial state under the action of the tensile force of the spring or the buoyancy of water in the barrel body, so that the mop can pass through the cleaning port without obstruction when being cleaned next time.

Claims (10)

1. A dewatering assembly for a mop, comprising: comprises a bracket, wherein the bracket is provided with a through hole for the mop plate to pass through;

a water squeezing component is arranged on one side of the support positioned at the through hole, and an abutting component is arranged on the other side of the support positioned at the through hole in a sliding manner; the abutting part is provided with an initial position far away from the wringing part and a wringing position close to the wringing part; when the abutting part is positioned at the initial position, a cleaning opening for the mop plate to pass through without obstruction is formed between the abutting part and the water squeezing part; when the abutting part is positioned at the water squeezing position, a water squeezing opening for squeezing and dehydrating the mop plate is formed between the abutting part and the water squeezing part;

the abutting part is provided with a stressed part, and when the stressed part is stressed by downward external force, the abutting part moves from an initial position to a water squeezing position; a reset component for driving the abutting component to reset from the wringing position to the initial position is connected between the abutting component and the bracket; or the abutting part is provided with a floater, so that the abutting part can be reset to the initial position from the wringing position under the buoyancy action of water.

2. The dewatering assembly for a mop, as claimed in claim 1, wherein: the bracket is provided with a guide groove in sliding connection with the abutting part, and the guide groove comprises a first groove part and a second groove part which are communicated with each other; the first groove part is obliquely and downwards arranged from one side far away from the through opening to one side close to the through opening.

3. The dewatering assembly for a mop of claim 2, wherein: the abutting part is provided with a guide part which is connected with the guide groove in a sliding or rolling manner; one end, far away from the first slot part, of the second slot part forms a wringing positioning part, and when the guide part is located in the wringing positioning part, the abutting part is located at a wringing position.

4. The dewatering assembly for a mop of claim 2, wherein: the support is including the lid to and connect the mounting panel of two symmetry settings at the lid lower extreme, every be equipped with respectively on the mounting panel with support to lean on part sliding connection's guide way.

5. The dewatering assembly for a mop, as claimed in claim 1, wherein: the water squeezing component is a water squeezing roller which is rotatably connected with the two mounting plates through a rotating shaft; or the water squeezing component is a sheet-shaped water squeezing plate, and the water squeezing plate is fixedly connected with the mounting plate.

6. The dewatering assembly for a mop, as claimed in claim 5, wherein: the rotating shaft is rotationally connected with the tubular wringing roller; or the rotating shafts are integrally formed at two ends of the wringing roller.

7. The dewatering assembly for a mop, as claimed in claim 1, wherein: the abutting part is provided with a groove body with a downward opening, and the groove body forms the floater capable of floating on the water surface.

8. The dewatering assembly for a mop, as claimed in claim 1, wherein: the leaning component is provided with a mop rod containing opening, and the stress part is positioned at the bottom of the mop rod containing opening.

9. A mop kit, comprising: the mop bucket comprises a bucket body and a mop, wherein the mop bucket comprises the bucket body and the dewatering assembly as claimed in any one of claims 1 to 8 arranged on the bucket body;

the mop comprises a mop rod and a mop plate which is rotatably connected to the lower end of the mop rod;

the mop can be connected with or abut against the stress part, and when the mop moves downwards, the mop can drive the abutting part to move from the initial position to the water squeezing position through the stress part.

10. A mop kit as defined in claim 9, wherein: when the mop drives the abutting part to reach the water squeezing position, the upper end part of the mop plate is just opposite to or close to the water squeezing part.

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