CN110013202B - Mop bucket, cleaning tool kit and flat mop dewatering method - Google Patents

Abstract

The invention relates to the technical field of cleaning tools, and provides a mop bucket, a cleaning tool set and a flat mop dehydration method. Wherein, the mop bucket comprises a bucket body, a guiding unit and a cleaning device; the guide unit is arranged in the barrel body, the guide unit can be detachably connected with the flat mop, and the flat mop can move along the surface of the cleaning device in a friction way after being detachably connected with the guide unit; the guide unit can change the distance between the flat mop and the cleaning device under the action of external force. After the flat mop is connected with the guide unit, the guide unit can change the distance between the flat mop and the cleaning device under the action of external force, so that the extrusion force between the flat mop and the cleaning device can be changed. Therefore, the mop bucket provided by the invention can solve the problem that the degree of dryness and humidity of dehydration cannot be controlled when the conventional mop bucket is used for dehydrating a flat mop.

Description

Mop bucket, cleaning tool kit and flat mop dewatering method

Technical Field

The invention relates to the technical field of cleaning tools, in particular to a mop bucket, a cleaning tool set and a flat mop dehydration method.

Background

The mop bucket is used as a cleaning tool and is usually matched with a mop to contain clean water for cleaning the mop. Typically, the mop bucket also has a dewatering function. The mop barrel suitable for the round mop adopts a centrifugal dehydration mode to dehydrate the round mop; the mop barrel suitable for the flat mop adopts a squeezing dehydration mode to dehydrate the flat mop.

The existing mop bucket suitable for the flat mop generally comprises a barrel body, a bucket cover and a stripping opening arranged on the bucket cover and used for scraping water; when the flat mop is used, a user holds clear water by using the cylinder, folds the flat mop into a cleanable state, inserts the flat mop into the stroking opening, stretches into the cylinder to enable the clear water to wet the flat mop so as to rinse stains on the flat mop, then pulls the flat mop up and down, and wipes wiping objects (such as cotton sheets, sponge sheets, cloth strips and the like) of the flat mop at the edge of the stroking opening to scrape the wiping objects of the flat mop, and extrudes and scrapes the wiping objects of the flat mop to dry, so that the effects of cleaning and dewatering are finally achieved.

As described above, the conventional mop bucket achieves a dehydrating effect by a user lifting up and down the mop while pressing the dehydrating flat mop. However, the existing mop bucket can not control the degree of drying and wetting of the flat mop, and is inconvenient to use.

Disclosure of Invention

Accordingly, the present invention is directed to a mop bucket, a cleaning tool kit and a method for dehydrating a flat mop, which solve the problem that the existing mop bucket cannot control the degree of drying and wetting when dehydrating a flat mop.

In order to achieve the above object, the present invention provides the following technical solutions:

in a first aspect, an embodiment of the present invention provides a mop bucket including a bucket body, a guide unit, and a cleaning device;

the guide unit is arranged in the barrel body, the guide unit can be detachably connected with the flat mop, and the flat mop can move along the surface of the cleaning device in a friction way after being detachably connected with the guide unit; the guide unit can change the distance between the flat mop and the cleaning device under the action of external force.

Optionally, the guiding unit includes a first guiding subunit and a second guiding subunit;

the distance between the second guiding subunit and the cleaning device can be changed under the action of external force, the second guiding subunit is in sliding connection with the first guiding subunit, the second guiding subunit can slide back and forth along the first guiding subunit, and the second guiding subunit can be detachably connected with the flat mop.

Optionally, the first guiding subunit is a sliding rod, a sliding groove, a sliding strip or a side wall of the barrel body, and a limiting piece is arranged on the first guiding subunit and is used for limiting the second guiding subunit to continue to slide forwards when the second guiding subunit slides to the end part of the first guiding subunit; and sliding parts capable of sliding back and forth along the first guiding unit are arranged on the left side and the right side of the second guiding subunit.

Optionally, the lower extreme of the guiding unit is articulated, the guiding unit can be swung towards the belt cleaning device under the exogenic action to reduce its with the distance between the belt cleaning device, when dull and stereotyped mop with the guiding unit can dismantle the connection back, dull and stereotyped mop can reciprocate on the guiding unit.

Optionally, the mop bucket further comprises a foot pedal, wherein the foot pedal is arranged at the bottom of the bucket body and extends forwards to the outside of the side wall of the bucket body.

Optionally, the barrel body is divided into a clear water storage area and a sewage containing area, the clear water storage area is positioned above the sewage containing area, and a drain hole is formed in the bottom of the sewage containing area;

the clean water storage area comprises a first storage area and a second storage area, the second storage area is located at the bottom of the first storage area, the volume of the second storage area is smaller than that of the first storage area, at least one water outlet hole is formed in the side wall and/or the bottom of the second storage area, a first switch device is arranged between the first storage area and the second storage area, and the first switch device is used for controlling the communication state between the first storage area and the second storage area.

Optionally, a vertical partition board is arranged in the second storage area, the vertical partition board divides the second storage area into a front part and a rear part, the front part and the rear part are respectively a front side sub-storage area and a rear side sub-storage area, the rear side sub-storage area is communicated with the first storage area through the first switch device, and at least one row of water outlets are arranged on the side wall and/or the bottom of the front side sub-storage area;

a communication hole is formed in the vertical partition plate, a second switching device is arranged at the communication hole, a penetrating hole is formed in the front wall of the front side sub-storage area, and a part of the second switching device is penetrated out of the front side sub-storage area through the penetration Kong Shenzhi; when the flat mop and the cleaning device scrape each other, the flat mop can abut against the second switch device, the second switch device moves into the front side sub-storage area and opens the communication hole; when the flat mop is removed from the cleaning device, the second switch device is reset and closes the communication hole.

In a second aspect, embodiments of the present invention also provide a cleaning implement set, including a flat mop and a mop bucket as described in any of the above, wherein the flat mop includes a mop rod and a mop plate, and the mop rod and the mop plate are foldable in parallel with each other.

Optionally, the guiding unit includes a first guiding subunit and a second guiding subunit; the second guiding subunit can change the distance between the second guiding subunit and the cleaning device under the action of external force, the second guiding subunit is in sliding connection with the first guiding subunit, the second guiding subunit can slide back and forth along the first guiding subunit, and the second guiding subunit can be detachably connected with the flat mop;

the second guiding subunit comprises a cylinder body, and a mounting groove penetrating through the cylinder wall is formed in the cylinder wall of the cylinder body; a rotating piece is arranged in the mounting groove, a first end of the rotating piece is positioned inside the cylinder, a second end of the rotating piece is positioned outside the cylinder, and an elastomer is arranged between the first end of the rotating piece and the cylinder wall of the cylinder;

the mop rod of the flat mop is provided with a jack matched with the first end of the rotating piece, and when the mop rod of the flat mop folded into a parallel state is inserted into the cylinder, the first end of the rotating piece is in sliding contact with the surface of the mop rod, and the elastic piece is pressed; when the mop rod of the flat mop is inserted to a preset position, the elastic piece pushes the first end of the rotating piece into the insertion hole so as to realize detachable connection between the flat mop and the second guiding subunit; when the second end of the rotating member is pressed, the rotating member rotates, so that the second end of the rotating member is pulled away from the insertion hole, and the elastic member is pressed.

In a third aspect, an embodiment of the present invention further provides a method for dehydrating a flat mop, which is applied to a mop bucket, the mop bucket including a bucket body, a guide unit, and a cleaning device, the method including:

the guide unit is detachably connected with the flat mop;

the guide unit receives the action of external force, so that the guide unit and the flat mop connected with the guide unit move towards or away from the cleaning device;

the guiding unit receives the action of external force, so that the flat mop connected with the guiding unit can reciprocate on the guiding unit, and the flat mop connected with the guiding unit and the cleaning device scrape each other.

Compared with the prior art, the invention has the following beneficial effects:

the mop bucket provided by the invention comprises a bucket body, a guide unit and a cleaning device; the guide unit is arranged in the barrel body, the guide unit can be detachably connected with the flat mop, and after the flat mop is detachably connected with the guide unit, the flat mop can be rubbed and moved along the surface of the cleaning device to clean or squeeze water of the flat mop; the guide unit can change the distance between the flat mop and the cleaning device under the action of external force. Thus:

first point: after the flat mop is connected with the guide unit, the guide unit can change the distance between the flat mop and the cleaning device under the action of external force, so that the extrusion force between the flat mop and the cleaning device can be changed. For example, when the distance between the flat mop and the cleaning device is short, the pressing force therebetween is large, and when the distance between the flat mop and the cleaning device is long, the pressing force therebetween is small. For example, the user may apply an external force to the mop rod of the flat mop, which transmits the external force to the guide unit, thereby causing the guide unit to change the distance between the flat mop and the cleaning device, i.e., the pressing force therebetween. Because the flat mop is drier after being dehydrated when the extrusion force is larger, and is more moist after being dehydrated when the extrusion force is smaller. Therefore, the mop bucket provided by the invention can solve the problem that the degree of dryness and humidity of dehydration cannot be controlled when the conventional mop bucket is used for dehydrating a flat mop.

Second point: in the prior art, the width of the smoothing opening for scraping water is fixed, and the mop is only suitable for a mop with certain fixed thickness, when the mop is used, if a thinner mop is required to be dehydrated, the squeezing force between the mop and the smoothing opening is small after the mop is inserted into the smoothing opening, so that the dehydration effect is poor, and if a thicker mop is required to be dehydrated, the mop is difficult to squeeze into the smoothing opening due to thicker mop, so that the dehydration is difficult. In the mop bucket provided by the invention, the distance between the flat mop and the cleaning device can be controlled by the guide unit, so that the mop bucket provided by the invention is suitable for flat mops with any thickness. For example, when the flat mop is thin, an external force can be applied to the guiding unit, and the guiding unit can enable the flat mop to move a larger distance towards the cleaning device, so that a proper extrusion force can be generated between the flat mop and the cleaning device; when the flat mop is thicker, an external force can be applied to the guide unit, and the guide unit enables the flat mop to move a small distance towards the cleaning device, so that proper extrusion force can be generated between the flat mop and the cleaning device.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings that are needed in the embodiments will be briefly described below, it being understood that the following drawings only illustrate some embodiments of the present invention and therefore should not be considered as limiting the scope, and other related drawings may be obtained according to these drawings without inventive effort for a person skilled in the art.

FIG. 1 (a) shows a schematic view of the structure of a mop bucket provided in some examples;

FIG. 1 (b) shows a schematic structural view of a cleaning kit provided in some examples;

fig. 2 (a) shows a schematic structural view of the guide unit described in some examples;

fig. 2 (b) shows a schematic structural view of the guide unit described in some examples;

fig. 2 (c) shows a schematic structural view of the guide unit described in some examples;

FIG. 3 shows a schematic diagram of the structure of a second guiding sub-unit described in some examples;

FIG. 4 shows a schematic structural view of a bucket as described in some examples;

FIG. 5 illustrates a schematic diagram of the structure of the second storage area described in some examples;

fig. 6 shows a schematic structural diagram of a second switching device described in some examples;

fig. 7 (a) shows a schematic cross-sectional view of a second guiding unit described in some examples;

fig. 7 (b) shows a schematic cross-sectional view of a second guide unit described in some examples;

fig. 8 shows a schematic structural view of the guide unit described in some examples.

Detailed Description

The following describes specific embodiments of the invention, which are illustrative and are intended to disclose specific working of the invention, and are not to be construed as further limiting the scope of the claims.

Example 1:

referring to fig. 1 (a) and 1 (b), an embodiment provides a mop bucket including a bucket body 100, a guide unit 200, and a cleaning device 300. The guiding unit 200 is disposed in the tub 100, the guiding unit 200 may be detachably connected to the flat mop 400, and when the flat mop 400 is detachably connected to the guiding unit 200, the guiding unit may move along the surface of the cleaning device 300; the guide unit 200 may change the distance between the flat mop 400 and the cleaning device 300 under the external force.

In use, a user may apply an external force to the mop rod 410 of the flat mop 400, and the flat mop 400 transmits the external force to the guide unit 200, thereby causing the guide unit 200 to change the distance between the flat mop 400 and the cleaning device 300, i.e., change the pressing force therebetween. For example, when the distance between the flat mop 400 and the cleaning device 300 is short, the pressing force therebetween is large, and when the distance between the flat mop 400 and the cleaning device 300 is long, the pressing force therebetween is small. Because the flat mop 400 is drier after being dehydrated when the pressing force is large, and the flat mop 400 is more moist after being dehydrated when the pressing force is small. So that the dehydration dryness and humidity can be conveniently controlled when the flat mop 400 is dehydrated using the mop bucket. The arrow shown in fig. 1 indicates a direction in which a user pulls the mop rod 410 of the flat mop 400, so that the flat mop 400 transmits an external force applied by the user to the guide unit 200, and thus the guide unit 200 changes the distance between the flat mop 400 and the cleaning device 300, and the flat mop 400 approaches the cleaning device 300 and is pressed with each other with the cleaning device 300.

On the basis of the mop bucket, the embodiment provides specific implementation distances, and on the premise of not interfering with each other, the examples can be combined arbitrarily to form a new mop bucket. It should be understood that it is within the scope of the present invention to provide a new flat mop 400 that is formed by any combination of examples.

As an example, the guiding unit may be a sliding rod, the lower end of the sliding rod is hinged to the bottom of the barrel, a jack matched with the sliding rod is formed in the flat mop, and the flat mop is inserted into the sliding rod through the jack and can slide back and forth along the length direction of the sliding rod. The user pulls the direction of the mop rod of the flat mop, so that the flat mop transmits the external force applied by the user to the sliding rod, the sliding rod rotates towards the cleaning device by taking the bottom of the sliding rod as a fulcrum, the flat mop on the sliding rod is close to the cleaning device and is mutually extruded with the cleaning device, the user lifts the flat mop back and forth to enable the flat mop to slide back and forth along the length direction of the sliding rod, and the flat mop is extruded and scraped with the cleaning device during the back and forth sliding of the flat mop, so that dehydration is realized. The user controls the dewatering and drying degree by controlling the pulling force of the flat mop.

As an example, referring to fig. 2 (a) and 2 (b), the guide unit 200 includes a first guide subunit 210 and a second guide subunit 220; the distance between the second guiding subunit 220 and the cleaning device can be changed under the action of external force, the second guiding subunit 220 is slidably connected with the first guiding subunit 210, the second guiding subunit 220 can slide reciprocally along the first guiding subunit 210, and the second guiding subunit 220 can be detachably connected with the flat mop. In comparison with the previous example, the second guiding sub-unit 220 is detachably connected to the flat mop in this example, and then the second guiding sub-unit 220 is slid along the first guiding sub-unit 210, so that the structure of the conventional flat mop does not need to be modified. For example, the second guiding sub-unit 220 is provided with a clamping groove and a buckle, and when the flat mop is inserted into the clamping groove, the flat mop is locked by the buckle, so that the detachable connection is realized.

As an example, referring to fig. 2 (a), the first guide subunit 210 may be two slide bars, and the lower end of each slide bar is hinged to the bottom of the tub. Correspondingly, sliding pieces capable of sliding back and forth along the sliding rod are arranged on the left side and the right side of the two guiding sub-units, for example, insertion holes matched with the sliding rod in the direction of the sliding rod can be formed in the two sides of the second guiding sub-unit 220, and the second guiding sub-unit 220 is inserted into the sliding rod through the insertion holes and can slide back and forth along the length direction of the sliding rod. Or each sliding rod is provided with a sliding groove, and the left side and the right side of the second guiding subunit 220 are provided with pulleys sliding along the sliding grooves as the sliding pieces. A stopper 230 may be provided at the top end of the slide bar for restricting the second guide sub-unit 220 from continuing to slide forward when the second guide sub-unit 220 slides to the end of the slide bar. For example, the stop 230 may be a stop.

As an example, referring to fig. 2 (b), the first guiding subunit 210 may be a bar-shaped column, the lower end of the bar-shaped column is hinged to the bottom of the tub, the bar-shaped column may rotate back and forth with the lower end as a pivot under the action of an external force, and the bar-shaped column is closer to the cleaning device when the bar-shaped column rotates forward. The left and right sides of the bar-shaped column body are provided with sliding grooves, correspondingly, the left and right sides of the two guiding sub-units are provided with sliding pieces capable of sliding back and forth along the sliding grooves of the bar-shaped column body, for example, the two sides of the second guiding sub-unit 220 are provided with sliding blocks or rolling wheels matched with the sliding grooves in the opposite directions, and the sliding pieces can slide along the sliding grooves. The foremost end of the bar-shaped column may be provided with a stopper 230 for restricting the second guide subunit 220 from continuing to slide forward when the second guide subunit 220 slides to the end of the bar-shaped column. For example, the stop 230 may be a stop.

As an example, referring to fig. 2 (c), the first guiding sub-unit 210 may also be a chute provided on the inner wall of the tub. Correspondingly, one end of the second guiding subunit 220 is hinged in the sliding slot, and the hinge point of the second guiding subunit 220 can slide along the sliding slot. When the mop is used, after the flat mop is detachably connected with the second guiding subunit 220, the mop rod is pulled, so that the second guiding subunit 220 rotates towards the direction close to the cleaning device, the flat mop and the cleaning device are further mutually extruded, then the second guiding subunit 220 slides along the first guiding subunit 210, and further the flat mop and the cleaning device are mutually scraped, so that dehydration is realized.

It should be understood that the specific structure of the first guiding sub-unit 210 and the second guiding sub-unit 220 is not limited to the above examples, which should not be construed as limiting the present invention. For example, the first guiding sub-unit 210 may also be a telescopic rod with a bottom end hinged to the bottom of the tub, and the second guiding sub-unit 220 is fixedly disposed on top of the telescopic rod.

As an example, referring to fig. 3, the second guiding subunit 220 may specifically include an upper frame 222, a left frame 223, a lower frame 224, and a right frame 225 that are connected to form a square frame, where sliding members capable of sliding vertically along the first guiding unit 210 are disposed on the left frame 223 and the right frame 225; the upper frame 222 is provided with a limit groove 226 for clamping the mop rod of the flat mop, when the mop rod of the flat mop is clamped into the limit groove 226, the lower surface of the upper frame 222 is abutted against the upper edge of the mop plate of the flat mop, and the upper surface of the lower frame 226 is abutted against the lower edge of the mop plate of the flat mop.

As an example, referring to fig. 1 (a) and 1 (b), the lower end of the guide unit 200 is hinged, the guide unit 200 may swing toward the cleaning device 300 under the external force to reduce the distance between the cleaning device 300 and the flat mop 400, and the flat mop 400 may reciprocate on the guide unit 200 after the flat mop 400 is detachably coupled to the guide unit 200. In this example, the guide unit 200 may press the flat mop 400 and the cleaning device 300 with each other by an external force by rotating to change the distance between the flat mop 400 and the cleaning device 300. In addition, when the flat mop 400 reciprocates on the guide unit 200, the mutual scraping between the flat mop 400 and the cleaning device 300 is achieved. In use, a user can rotate the guide unit 200 by pulling the mop rod 410 to press the flat mop 400 and the cleaning device 300 against each other, and the use method is simple and labor-saving.

It should be appreciated that the guide unit may also be adapted to change the distance between the flat mop and the cleaning device by means of translation. For example, the bottom of the cylinder is provided with a chute along which the guiding unit can translate. When the guide unit is translated, the distance between the flat mop connected thereto and the cleaning device can be changed.

As an example, referring to fig. 1 (a) and 1 (b), the mop bucket further includes a foot pedal 500, and the foot pedal 500 is disposed at the bottom of the bucket body 100 and protrudes forward beyond the sidewall of the bucket body 100. By providing the foot pedal 500, when the mop rod 410 is pulled in the direction indicated by the arrow in fig. 1 (a) and 1 (b), the foot pedal 500 can be stepped on by a foot, preventing the mop bucket from being fallen down. Specifically, the foot pedal 500 may be integrally formed with the tub 100, or may overlap with the tub 100, and the overlapping portion may be connected to the tub 100 by a bolt.

As an example, referring to fig. 4, the tub may be divided into a fresh water storage area 110 and a sewage receiving area 120, and the fresh water storage area 110 is located above the sewage receiving area 120; the clean water storage area 110 comprises a first storage area 111 and a second storage area 112, the second storage area 112 is located at the bottom of the first storage area 111, the volume of the second storage area 112 is smaller than that of the first storage area 111, at least one water outlet hole is formed in the side wall and/or the bottom of the second storage area 112, a first switch device 114 is arranged between the first storage area 111 and the second storage area 112, and the first switch device 114 is used for controlling the communication state between the first storage area 111 and the second storage area 112. When the mop bucket is used, the plurality of drain holes 113 or the strip-shaped drain holes 113 can be controlled through only one first switch device 114, and the control method is simple and convenient.

The specific structure of the first switching device 114 may be selected in many ways, which is not limited by the present invention. For example, as shown in fig. 4, the first switch device 114 may include a control rod 114-1, a portion of the control rod 114-1 is provided with a screw thread, a handle 114-2 is provided at an upper end of the control rod 114-1, a deformable plug 114-3 is provided at a lower end of the control rod 114-1, a mounting plate is provided on an inner sidewall of the first storage region 111, and a screw hole matching the screw thread of the control rod 114-1 is provided on the mounting plate. When the handle 114-2 is rotated in the forward direction, the control lever 114-1 is lifted upward, and the stopper 114-3 opens the passage 115 between the first storage area 111 and the second storage area 112, so that the first storage area 111 is discharged to the second storage area 112, and the second storage area 112 supplies clean water to the flat mop through the drain hole 113. When the flat mop is rotated in the reverse direction, the control lever 114-1 is lowered downward and the stopper ball 114-3 blocks the passage 115 between the first storage region 111 and the second storage region 112.

As an example, referring to fig. 5, the second storage area 112 has a vertical partition 131 therein, the vertical partition 131 divides the second storage area 112 into a front portion and a rear portion, which are respectively a front side sub-storage area 132 and a rear side sub-storage area 133, the rear side sub-storage area 133 is communicated with the first storage area 111 through the first switch device 114, and at least one row of drain holes 113 is provided on a side wall and/or a bottom of the front side sub-storage area 132; a communication hole 134 is formed in the vertical partition plate 131, a second switch device 135 is arranged at the communication hole 134, a through hole 136 is formed in the front wall of the front side sub-storage area 132, and a part of the second switch device 135 extends out of the front side sub-storage area 132 through the through hole 136; when the flat mop and the cleaning device scrape each other, the flat mop can abut against the second switch device 135, the second switch device 135 moves into the front side sub-storage area 132 and opens the communication hole 134; when the flat mop is removed from the cleaning device, the second switching device 135 is reset and closes the communication hole 134.

When the mop bucket provided by the present example is used, when the flat mop 400 needs to be cleaned, the first switch device 114 is turned on, and then the mop rod 410 is pulled to scrape the flat mop 400 and the cleaning device 300 against each other, the flat mop 400 abuts against the second switch device 135, and after the second switch device 135 moves inward toward the front side sub-storage area 132, the communication hole 134 is opened, so that clean water is discharged from the drain hole 113 to wet the flat mop 400, and the flat mop 400 is rinsed. When it is desired to dewater the flat mop 400, the first switching means 114 is turned off, and at this time, even if the flat mop 400 is abutted against the second switching means 135 while being scraped by the cleaning device 300, the drain hole 113 is not discharged with water because the first switching means 114 is turned off, and the dewatering is not affected.

As an example, referring to fig. 6, the second switching device may specifically include a tube 141, an abutment 142, a cone 143, and a spring 144. Wherein, the pipe body 141 is provided with a plurality of outflow holes 145, the abutting body 142 is arranged at the front end of the pipe body 141, and the abutting body 142 extends out of the penetration holes; the cone 143 is disposed at the rear end of the tube 141, the spring 144 is disposed on the bottom surface of the cone 143, one end of the spring 144 abuts against the bottom surface of the cone 143, the other end of the spring 144 abuts against the inner wall of the rear sub-storage area, and the spring 144 is always pressed. When the abutting body 142 is abutted by the flat mop, the whole second switch device moves into the front side sub-storage area, and the conical body 143 opens the communication hole, so that clean water in the rear side sub-storage area can flow into the front side sub-storage area through the communication hole. When the flat mop leaves the abutting body 142142, the whole second switch device is reset by the rebound force of the spring 144, and the conical body 143 blocks the communication hole.

As an example, any existing cleaning device, such as a scraping bar, a scraping plate, or a roller, may be used as the cleaning device, and the specific structure of the cleaning device is not limited in the present invention.

Example 2:

referring to fig. 1 (b), the present embodiment provides a cleaning tool kit including a flat mop and the mop bucket according to any one of the embodiments 1, wherein the flat mop includes a mop rod 410 and a mop plate 420, and the mop rod 410 and the mop plate 420 are foldable in parallel with each other.

In use, a user may apply an external force to the mop rod 410 of the flat mop 400, and the flat mop 400 transmits the external force to the guide unit 200, thereby causing the guide unit 200 to change the distance between the flat mop 400 and the cleaning device 300, i.e., change the pressing force therebetween. For example, when the distance between the flat mop 400 and the cleaning device 300 is short, the pressing force therebetween is large, and when the distance between the flat mop 400 and the cleaning device 300 is long, the pressing force therebetween is small. Because the flat mop 400 is drier after being dehydrated when the pressing force is large, and the flat mop 400 is more moist after being dehydrated when the pressing force is small. So that the dehydration dryness and humidity can be conveniently controlled when the flat mop 400 is dehydrated using the mop bucket. The arrow shown in fig. 1 (b) indicates a direction in which a user pulls the mop rod 410 of the flat mop 400, so that the flat mop 400 transmits an external force applied by the user to the guide unit 200, and thus the guide unit 200 changes the distance between the flat mop 400 and the cleaning device 300, and the flat mop 400 approaches the cleaning device 300 and presses against the cleaning device 300.

As an example, referring to fig. 7 (a) and 7 (b), the present embodiment shows a schematic structural view of a guide unit different from that of fig. 1 (b). The guiding unit comprises a first guiding subunit and a second guiding subunit; the distance between the second guiding subunit and the cleaning device can be changed under the action of external force, the second guiding subunit is in sliding connection with the first guiding subunit, the second guiding subunit can slide back and forth along the first guiding subunit, and the second guiding subunit can be detachably connected with the flat mop. As shown in fig. 7 (a) and 7 (b), the second guiding subunit 220 includes a cylinder 241, and a mounting groove 242 penetrating through the cylinder wall is formed on the cylinder wall of the cylinder 241; a rotating member 243 is disposed in the mounting groove 242, a first end of the rotating member 243 is located inside the cylinder 241, a second end of the rotating member 243 is located outside the cylinder 241, and an elastic body 244 is disposed between the first end of the rotating member 243 and the cylinder wall of the cylinder 241; the mop rod 410 of the flat mop 400 is provided with a receptacle 411 that mates with the first end of the rotating member 243. As shown in fig. 7 (a), the first end of the rotating member 243 is in sliding contact with the surface of the mop rod 410, and the elastic member is pressed during the insertion of the mop rod 410 of the flat mop 400 folded in a parallel state into the cylinder 241; when the mop rod 410 of the flat mop 400 is inserted to a predetermined position, the elastic member pushes the first end of the rotating member 243 into the insertion hole 411 to achieve the detachable connection between the flat mop 400 and the second guide subunit 220. As shown in fig. 7 (b), when the second end of the rotating member 243 is pressed, the rotating member 243 rotates, so that the second end of the rotating member 243 is pulled away from the insertion hole 411, and the elastic member is pressed.

When the cleaning tool set provided in this example is used, the mop rod 410 of the flat mop 400 may be pulled back when the flat mop 400 needs to be detached from the second guiding subunit 220, the first guiding subunit 210 rotates backward, so that the second end of the rotating member 243 of the second guiding subunit 220 abuts against any point of the tub body, the second end of the rotating member 243 is pressed, the rotating member 243 rotates, and the second end of the rotating member 243 is pulled away from the insertion hole 411, thereby the mop rod 410 may be pulled out from the tub body 241. The cleaning tool kit provided by the present example is more convenient to use, and the flat mop 400 and the second guide subunit 220 are not connected or detached by a human hand.

As shown in fig. 8, the second guide subunit 220 performs sliding along the first guide subunit 210 by the upper and lower sets of sliding members a and B. The sliding member a may slide to the top end of the first guide sub-unit 210, and the sliding member B may slide to the bottom end of the first guide sub-unit 210.

Embodiment III:

the embodiment provides a dehydration method of a flat mop, which is applied to a mop bucket, wherein the mop bucket comprises a bucket body, a guide unit and a cleaning device. The barrel body, the guide unit and the cleaning device can be any of the barrel body, the guide unit and the cleaning device in the first embodiment or the second embodiment. The method comprises the following steps: the guide unit is detachably connected with the flat mop; the guide unit receives the action of external force, so that the guide unit and the flat mop connected with the guide unit move towards or away from the cleaning device; the guiding unit receives the action of external force, so that the flat mop connected with the guiding unit can reciprocate on the guiding unit, and the flat mop connected with the guiding unit and the cleaning device scrape each other.

In the description provided herein, numerous specific details are set forth. However, it is understood that embodiments of the invention may be practiced without these specific details. In some instances, well-known methods, structures and techniques have not been shown in detail in order not to obscure an understanding of this description.

Similarly, it should be appreciated that in the foregoing description of exemplary embodiments of the invention, various features of the invention are sometimes grouped together in a single embodiment, figure, or description thereof for the purpose of streamlining the disclosure and aiding in the understanding of one or more of the various inventive aspects. However, the disclosed method should not be construed as reflecting the intention that: i.e., the claimed invention requires more features than are expressly recited in each claim. Rather, as the following claims reflect, inventive aspects lie in less than all features of a single foregoing disclosed embodiment. Thus, the claims following the detailed description are hereby expressly incorporated into this detailed description, with each claim standing on its own as a separate embodiment of this invention.

Those skilled in the art will appreciate that the modules in the apparatus of the embodiments may be adaptively changed and disposed in one or more apparatuses different from the embodiments. The modules or units or components of the embodiments may be combined into one module or unit or component and, furthermore, they may be divided into a plurality of sub-modules or sub-units or sub-components. Any combination of all features disclosed in this specification (including any accompanying claims, abstract and drawings), and all of the processes or units of any method or apparatus so disclosed, may be used in combination, except insofar as at least some of such features and/or processes or units are mutually exclusive. Each feature disclosed in this specification (including any accompanying claims, abstract and drawings), may be replaced by alternative features serving the same, equivalent or similar purpose, unless expressly stated otherwise.

Furthermore, those skilled in the art will appreciate that while some embodiments described herein include some features but not others included in other embodiments, combinations of features of different embodiments are meant to be within the scope of the invention and form different embodiments. For example, in the claims, any of the claimed embodiments may be used in any combination.

It should be noted that the above-mentioned embodiments illustrate rather than limit the invention, and that those skilled in the art will be able to design alternative embodiments without departing from the scope of the appended claims. In the claims, any reference signs placed between parentheses shall not be construed as limiting the claim. The word "comprising" does not exclude the presence of elements or steps not listed in a claim. The word "a" or "an" preceding an element does not exclude the presence of a plurality of such elements. The invention may be implemented by means of hardware comprising several distinct elements, and by means of a suitably programmed computer. In the unit claims enumerating several means, several of these means may be embodied by one and the same item of hardware. The use of the words first, second, third, etc. do not denote any order. These words may be interpreted as names.

Claims (10)

1. The mop bucket is characterized by comprising a bucket body, a guide unit and a cleaning device;

the guide unit is arranged in the barrel body, the guide unit is detachably connected with the flat mop, and the flat mop can move along the surface of the cleaning device in a friction way after being detachably connected with the guide unit; the user applies external force to the mop rod of the flat mop, the flat mop transmits the external force to the guide unit, and the guide unit can change the distance between the flat mop and the cleaning device under the action of the external force;

the guiding unit comprises a first guiding subunit and a second guiding subunit; the second guiding subunit can change the distance between the second guiding subunit and the cleaning device under the action of external force, the second guiding subunit is in sliding connection with the first guiding subunit, and the second guiding subunit can slide back and forth along the first guiding subunit.

2. The mop bucket of claim 1, wherein the second guiding subunit is removably attached to the flat mop.

3. The mop bucket of claim 2, wherein the first guiding subunit is a side wall of a sliding rod, a sliding chute or a bucket body, and a limiting piece is arranged on the first guiding subunit and used for limiting the second guiding subunit to continue sliding forwards when the second guiding subunit slides to the end part of the first guiding subunit; and sliding pieces capable of sliding back and forth along the first guiding unit are arranged on the left side and the right side of the second guiding subunit.

4. The mop bucket according to claim 1, wherein the lower end of the guide unit is hinged, and the guide unit swings toward the cleaning device under the action of the external force to reduce the distance between the guide unit and the cleaning device, and the flat mop is reciprocally movable on the guide unit after the flat mop is detachably connected to the guide unit.

5. The mop bucket of claim 1, further comprising a foot pedal disposed at a bottom of the bucket body and extending forward beyond a side wall of the bucket body.

6. The mop bucket of claim 1, wherein the bucket body is divided into a clean water storage area and a sewage containing area, the clean water storage area being located above the sewage containing area;

the clean water storage area comprises a first storage area and a second storage area, the second storage area is located at the bottom of the first storage area, the volume of the second storage area is smaller than that of the first storage area, at least one water outlet hole is formed in the side wall and/or the bottom of the second storage area, a first switch device is arranged between the first storage area and the second storage area, and the first switch device is used for controlling the communication state between the first storage area and the second storage area.

7. The mop bucket according to claim 6, wherein a vertical partition plate is arranged in the second storage area and divides the second storage area into a front storage area and a rear storage area, wherein the front storage area and the rear storage area are respectively a front side sub-storage area and a rear side sub-storage area, the rear side sub-storage area is communicated with the first storage area through the first switch device, and at least one row of water outlets are arranged on the side wall and/or the bottom of the front side sub-storage area;

a communication hole is formed in the vertical partition plate, a second switching device is arranged at the communication hole, a penetrating hole is formed in the front wall of the front side sub-storage area, and a part of the second switching device extends out of the front side sub-storage area through the penetrating hole; when the flat mop and the cleaning device scrape each other, the flat mop can abut against the second switch device, the second switch device moves into the front side sub-storage area and opens the communication hole; when the flat mop is removed from the cleaning device, the second switch device is reset and closes the communication hole.

8. A cleaning kit comprising a flat mop and a mop bucket according to any one of claims 1 to 7, wherein the flat mop comprises a mop rod and a mop plate, and wherein the mop rod and the mop plate are foldable in a parallel state with respect to each other.

9. The cleaning kit of claim 8 wherein the guide unit comprises a first guide subunit and a second guide subunit; the second guiding subunit can change the distance between the second guiding subunit and the cleaning device under the action of external force, the second guiding subunit is in sliding connection with the first guiding subunit, the second guiding subunit can slide back and forth along the first guiding subunit, and the second guiding subunit can be detachably connected with the flat mop;

the second guiding subunit comprises a cylinder body, and a mounting groove penetrating through the cylinder wall is formed in the cylinder wall of the cylinder body; a rotating piece is arranged in the mounting groove, a first end of the rotating piece is positioned inside the cylinder, a second end of the rotating piece is positioned outside the cylinder, and an elastomer is arranged between the first end of the rotating piece and the cylinder wall of the cylinder;

the mop rod of the flat mop is provided with a jack matched with the first end of the rotating piece, and when the mop rod of the flat mop folded into a parallel state is inserted into the cylinder, the first end of the rotating piece is in sliding contact with the surface of the mop rod, and the elastic piece is pressed; when the mop rod of the flat mop is inserted to a preset position, the elastic piece pushes the first end of the rotating piece into the insertion hole so as to realize detachable connection between the flat mop and the second guiding subunit; when the second end of the rotating member is pressed, the rotating member rotates, so that the first end of the rotating member is pulled away from the insertion hole, and the elastic member is pressed.

10. A method of dehydrating a flat mop, applied to a mop bucket including a bucket body, a guide unit, and a cleaning device, the method comprising:

the guide unit is detachably connected with the flat mop;

the user applies external force to the mop rod of the flat mop, the flat mop transmits the external force to the guide unit, and the guide unit receives the external force to enable the guide unit and the flat mop connected with the guide unit to move towards or away from the cleaning device;

the guiding unit receives the action of external force, so that the flat mop connected with the guiding unit can reciprocate on the guiding unit, and the flat mop connected with the guiding unit and the cleaning device scrape each other.