CN215424476U - Rotary mop kit - Google Patents

Abstract

The utility model discloses a rotary mop kit, which comprises a mop barrel and a mop, wherein the mop comprises a mop head with wiping materials and a mop rod movably connected to the upper end of the mop head; the mop barrel is internally provided with a supporting part which can be detachably connected with the mop head; the mop bucket is also internally provided with a spray head for spraying water to the wiping matters and a water pumping mechanism for delivering the water in the mop bucket to the spray head, and the mop head can directly or indirectly drive the water pumping mechanism to work when rotating; the mop rod is provided with a rotary driving mechanism for driving the mop head to rotate; a valve body for controlling the on-off of the pipeline is arranged on the water inlet pipeline or the water outlet pipeline of the water pumping mechanism; the mop head is connected with the supporting part, and when the rotary driving mechanism drives the mop head to rotate at a first rotating speed, the valve body is in a conducting state, and the spray head can spray water; the mop head is connected with the supporting part, and when the rotary driving mechanism drives the mop head to rotate at a second rotating speed, the valve body is in a closed state, and the spray head does not spray water.

Description

Rotary mop kit

Technical Field

The utility model belongs to the field of cleaning tools, and particularly relates to a rotary mop and a mop bucket structure matched with the rotary mop.

Background

The chinese patent application with publication number CN111657802A discloses a mop is from lift burnisher, including mop and mop bucket, the mop head of mop includes fixed disk and lifter plate, and the fixed disk is connected in the mop pole, the lifter plate connect in the fixed disk, the clearance has between lifter plate and the fixed disk, just the clearance certainly the center of lifter plate reduces to the periphery gradually, be equipped with the driving piece in the clearance, when the driving piece is located the great one end in clearance, the lifter plate is located the low level, when the mop head is rotatory, the driving piece is moved towards the periphery under the effect of centrifugal force, and the drive the clearance increases, thereby makes the lifter plate rises to the high level. The lifting of the mop head is controlled by adjusting the rotating speed of the mop head, the mop can be automatically operated to switch cleaning or dewatering operation in the mop barrel, operations such as lifting and pulling are not needed, seamless switching is achieved, and the mop is very convenient.

The advantage of above-mentioned scheme is that need not lift the mop pole when the mop washs and dewaters, only need can control the mop head through the rotational speed of adjustment mop head and go up and down, and then control the mop head whether with the suction pump transmission to whether the control suction pump surface of water sprays water. The mop head has the defects that the structure of the mop head is complex, so that the mop head is more in parts, and the thickness of the mop head is large, so that the mop head is not beneficial to cleaning the lower parts of furniture such as beds, sofas, cabinets and the like during mopping.

SUMMERY OF THE UTILITY MODEL

The technical problem to be solved by the utility model is as follows: aiming at the defects in the prior art, the rotary mop kit is more simplified in structure, less in parts and simple in structure of the mop head part.

In order to realize the purpose of the utility model, the following technical scheme is adopted for realizing the purpose: a rotary mop kit comprises a mop barrel and a mop, wherein the mop comprises a mop head with wiping materials and a mop rod movably connected to the upper end of the mop head;

a supporting part is arranged in the mop bucket and can be detachably connected with the mop head;

the mop bucket is also internally provided with a spray head for spraying water to the wiping objects and a water pumping mechanism for sending the water in the mop bucket to the spray head, and the mop head can directly or indirectly drive the water pumping mechanism to work when rotating; the mop rod is provided with a rotary driving mechanism for driving the mop head to rotate;

a valve body for controlling the on-off of the pipeline is arranged on the water inlet pipeline or the water outlet pipeline of the water pumping mechanism;

the mop head is connected with the supporting part, and when the rotary driving mechanism drives the mop head to rotate at a first rotating speed, the valve body is in a conducting state, and the spray head can spray water; the mop head is connected with the supporting part, and when the rotary driving mechanism drives the mop head to rotate at a second rotating speed, the valve body is in a closed state, and the spray head does not spray water.

Preferably, the method comprises the following steps: the valve body comprises a water inlet pipe section, a water outlet pipe section and a valve core movably arranged between the water inlet pipe section and the water outlet pipe section, and when the valve core is positioned at an initial position, the valve body is in a conducting state; when the valve core is abutted against the water outlet pipe section, the valve body is in a closed state.

Preferably, the method comprises the following steps: the valve body is vertically arranged, the water outlet pipe section is positioned above the water inlet pipe section, and the valve core is positioned at an initial position by means of self gravity; when the water flow thrust on the lower end of the valve core is larger than the self gravity, the valve core moves upwards to be abutted against the water outlet pipe section, so that the valve body is in a closed state.

Preferably, the method comprises the following steps: a spring is arranged between the valve body and the water outlet pipe section, and the spring enables the valve body to be in an initial position when not influenced by other external forces; when the mop head rotates at a second rotating speed, the spring is compressed to the valve core to be abutted against the water outlet pipe section by the water pressure generated by the water pumping mechanism, so that the valve body is in a closed state.

Preferably, the method comprises the following steps: the mop bucket is internally provided with a partition board, the mop bucket is internally positioned at two sides of the partition board to form an independent clear water area and a sewage area, and the water pumping mechanism is arranged in the clear water area.

Preferably, the method comprises the following steps: a blocking cover is arranged above the clear water area, and a brush and the spray head are arranged on the blocking cover; when the mop head is connected with the supporting component, water falling from the wiping matter is guided into the sewage area by the blocking cover.

Preferably, the method comprises the following steps: the supporting part is rotationally connected with the mop barrel, and when the mop head is connected with the supporting part, the supporting part is circumferentially fixed relative to the mop head, so that the mop head can drive the water pumping mechanism to work through the supporting part;

or a linkage part coaxially arranged with the support part is rotationally arranged in the mop bucket and is connected with the water pumping mechanism; after the mop head is connected with the supporting part, the mop head is connected with the linkage part, so that the mop head can drive the pumping mechanism to work through the linkage part.

Preferably, the method comprises the following steps: a positioning column is vertically arranged in the mop barrel, and the supporting part or/and the linkage part are/is rotatably sleeved on the positioning column; and the lower part of the supporting component or the linkage component is coaxially provided with a driving gear which is in transmission connection with the water pumping mechanism.

Preferably, the method comprises the following steps: the water pumping mechanism is a gear pump; a pump shell is arranged at the bottom in the mop bucket, a pump cover is connected to the upper end of the pump shell, a pump cavity is formed between the pump shell and the pump cover, two pump water gears which are meshed with each other are rotatably arranged in the pump cavity, and the pump cavity and the two pump water gears form the gear pump; one water pumping gear is coaxially connected with a driven gear, and the driven gear is meshed with the driving gear;

or the water pumping mechanism is a vortex pump; the mop bucket is characterized in that a pump shell is arranged at the bottom in the mop bucket, a pump cover is connected to the upper end of the pump shell, a pump cavity is formed between the pump shell and the pump cover, a water pumping gear is arranged in the pump cavity in a rotating mode, the water pumping gear is coaxially connected with a driven gear, and the driven gear is meshed with the driving gear and connected with the driving gear.

Preferably, the method comprises the following steps: the rotary driving mechanism is a hand-press type rotary mop rod or a motor.

Compared with the prior art, the utility model has the beneficial effects that: according to the utility model, the valve body is arranged on the pipeline of the water pumping mechanism, and the on-off of the valve body is controlled by the rotating speed of the mop head, so that whether the spray head sprays water or not can be selected according to the cleaning or spin-drying requirement. Therefore, the mop head and the water pumping mechanism are always in a transmission state, and the mop head does not need to be lifted to control the spray head to discharge water. In contrast, the simple valve body replaces a lifting mechanism which is complex in a mop head and needs a plurality of parts to work in a matching way in the background art, and the material and manual assembly cost can be obviously reduced under the condition of the same operation mode.

Drawings

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

FIG. 2 is a schematic cross-sectional view of a mop bucket of the present invention.

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

Fig. 4 is a schematic view of one construction of the pumping mechanism within the mop bucket of the present invention.

Fig. 5 is a schematic structural view of the valve body in the conducting state.

Fig. 6 is a schematic structural view of the valve body in a closed state.

Fig. 7 is another structural schematic diagram of the valve body.

Fig. 8 is a schematic view of the structure of the cover, the brush, and the head portion.

Fig. 9 is a schematic structural view of a brush unit in which a spray head and a brush are integrated.

FIG. 10 is a schematic structural view of embodiment 2.

Fig. 11 is an exploded view schematically showing embodiment 2.

1. A mop bucket; 11. a clear water zone; 12. a sewage area; 13. a lid portion; 14. a handle; 15. a positioning column; 16. a partition plate; 2. a blocking cover; 21. a water trough; 22. a scrubbing member; 23. a water inlet joint; 24. perforating; 3. a support member; 31. a drive gear; 4. a brush; 5. a spray head; 6. a mop head; 61. a wipe; 7. a mop rod; 8. a water pumping mechanism; 81. a pump housing; 811. a water inlet; 812. a water outlet; 82. a water pumping gear; 83. a driven gear; 84. a pump cover; 85. a water inlet pipe section; 86. a water outlet pipe section; 87. a valve core.

Detailed Description

Example 1

Referring to fig. 1 to 6, the present embodiment is a rotary mop kit comprising a mop bucket 1 and a mop, wherein the mop comprises a mop head 6 with a wipe 61, and a mop rod 7 movably connected to the upper end of the mop head. The wipe is typically designed to be removably attached to a mop head to facilitate replacement of the wipe.

The mop bucket is internally provided with a supporting part 3 which can be detachably connected with the mop head. A positioning column 15 is vertically arranged in the mop barrel, and the supporting part is rotatably sleeved on the positioning column.

The mop bucket is also internally provided with a spray head 5 for spraying water to the wiping matters and a water pumping mechanism 8 for delivering the water in the mop bucket to the spray head, and the mop head can drive the water pumping mechanism to work through the supporting component when rotating; the mop rod is provided with a rotary driving mechanism for driving the mop head to rotate; the rotary driving mechanism is an existing hand-press type rotary mop rod, or a motor is arranged on the mop rod, and the mop head is driven to rotate relative to the mop rod through the motor.

And a valve body for controlling the on-off of the pipeline is arranged on the water outlet pipeline of the water pumping mechanism. In other embodiments, the valve body is connected to the water inlet line of the water pumping mechanism. The valve body comprises a water inlet pipe section 85, a water outlet pipe section 86 and a valve core 87 movably arranged between the water inlet pipe section and the water outlet pipe section, and when the valve core is positioned at an initial position, the valve body is in a conducting state; when the valve core is abutted against the water outlet pipe section, the valve body is in a closed state.

The mop head is connected with the supporting part, and when the rotary driving mechanism drives the mop head to rotate at a first rotating speed, the valve body is in a conducting state, and the spray head can spray water; the mop head is connected with the supporting part, and when the rotary driving mechanism drives the mop head to rotate at a second rotating speed, the valve body is in a closed state, and the spray head does not spray water. Preferably, the second rotational speed is greater than first rotational speed, when wasing the mop promptly, earlier through mop pole control mop head low-speed rotatory, the valve body is in the on-state this moment, and the water that the mechanism of drawing water pumped is spouted from the shower nozzle and is washd the wiper, afterwards, controls the mop head high-speed rotatory through the mop pole, and the suction pump produces great water pressure and makes the valve body closed, and the shower nozzle is no longer gone out water, and the wiper is spin-dried after the mop head high-speed rotatory a period.

The first rotating speed, the second rotating speed, the high speed and the low speed are only relative, and have no absolute rotating speed value, and the opening and closing pressure values of the valve body can be influenced by the water pumping mechanisms with different structural forms and sizes and the specific structural forms and sizes of the valve body, namely the sizes and critical values of the first rotating speed and the second rotating speed can be realized by adjusting specific parameters of the water pumping mechanisms and the valve body according to requirements.

It should be noted that, when the mop head needs to be spin-dried after being cleaned, the rotating speed of the mop head needs to be increased to close the valve body, at the moment, whether the mop head continuously throws water outwards can be judged by observing the mop head, namely, when the mop head still throws water outwards and the throwing amount is not obviously reduced, the valve body can be explained to be not closed, at the moment, the rotating speed of the mop head needs to be increased, when the mop head is observed, the outward throwing speed is obviously reduced, the rotating speed of the mop head is explained to be fast enough, and the water pressure generated by the water pumping mechanism is enough to close the valve body.

Similarly, the valve body is required to be in a conducting state when the mop head is cleaned, and if the rotating speed of the mop head is too high, the valve body is closed, so that the rotating speed of the mop head is properly reduced.

Further, with reference to fig. 2, 5 and 6, the valve body is vertically arranged, the water outlet pipe 86 is located above the water inlet pipe section 85, and the valve core 87 is located at the initial position shown in fig. 5 by virtue of the self gravity; when the water flow thrust on the lower end of the valve core is larger than the self gravity, the valve core moves upwards to be abutted against the water outlet pipe section, so that the valve body is in a closed state shown in fig. 6.

In the valve body structure shown in fig. 5 and 6, the valve core can be maintained at the initial position or reset to the initial position by the self gravity, and a reset member such as a spring is not required to be installed, so that the pressure value of the valve core which rises to the closed state can be adjusted by adjusting the weight of the valve core or the size of a gap between the valve core and the inner wall of the water inlet pipe section, and the range of the first rotating speed and the second rotating speed can be adjusted.

More specifically, a guide frame is arranged in the water inlet pipe section, a guide rod is arranged at the lower end of the valve core, and the guide rod is connected with the guide frame in a sliding mode along the vertical direction.

In other embodiments, as shown in fig. 7, a spring 88 is provided between the valve body and the outlet pipe section, and the spring makes the valve body in an initial position when the valve body is not subjected to other external forces; when the mop head rotates at a second rotating speed, the spring is compressed to the valve core to be abutted against the water outlet pipe section by the water pressure generated by the water pumping mechanism, so that the valve body is in a closed state. In this embodiment, the water pressure required for switching the valve body from the on state to the off state can be adjusted by adjusting the biasing force of the spring, the thickness of the spring, and the like. The valve body is particularly suitable for the situation that the valve body is not vertically installed.

The mop bucket is internally provided with a partition 16, the mop bucket is internally positioned at two sides of the partition to form a clean water area 11 and a sewage area 12 which are independent, and the water pumping mechanism is arranged in the clean water area.

A blocking cover 2 is arranged above the clear water area, and a brush 4 and the spray head 5 are arranged on the blocking cover; when the mop head is connected with the supporting component, water falling from the wiping matter is guided into the sewage area by the blocking cover.

Specifically, a water trough 21 is arranged on the blocking cover, a water inlet joint 23 is connected to the lower end of the water trough, and the water inlet joint 23 is directly communicated with a water outlet pipe section of the valve body or is communicated with the water outlet pipe section through a water conveying pipe. The upper end of the water trough is connected with a brushing part 22, and the brush is connected to the brushing part or integrally formed at the upper end of the brushing part. The through hole arranged on the brushing piece forms the spray head.

Further, when the mop head is connected with the supporting part, the supporting part is circumferentially fixed relative to the mop head, so that the mop head can drive the water pumping mechanism to work through the supporting part. Specifically, the periphery of the supporting part is provided with a positioning outer bulge, and the lower part in the middle of the mop head is provided with a plug-in port which is matched and plugged with the positioning outer bulge. In addition, the middle of the lower part of the mop head is also fixedly connected with the supporting part temporarily through an elastic buckle or a detachable connecting part such as a magnet and the like.

In other embodiments, a linkage component which is coaxially arranged with the supporting component is arranged in the mop bucket in a rotating way, and the linkage component is connected with the water pumping mechanism; after the mop head is connected with the supporting part, the mop head is connected with the linkage part, so that the mop head can drive the pumping mechanism to work through the linkage part. For example, the linkage part is arranged below the supporting part and is rotationally connected with the supporting part or the positioning column, and after the mop head is connected with the supporting part, the transmission is realized between the lower end of the mop head and the linkage part through the clamping teeth, the non-circular insertion part, the sleeve joint part, the magnet and the like which are arranged in a matched mode.

Further, a driving gear 31 which is in transmission connection with the water pumping mechanism is coaxially arranged at the lower part of the supporting component or the linkage component.

Referring to fig. 3 and 4, the water pumping mechanism is a gear pump; a pump shell 81 is arranged at the bottom in the mop bucket, a pump cover 84 is connected to the upper end of the pump shell, a pump cavity is formed between the pump shell and the pump cover, two pump water gears 82 which are meshed with each other are rotatably arranged in the pump cavity, and the pump cavity and the two pump water gears form the gear pump;

one of the water pumping gears is coaxially connected with a driven gear 83, and the driven gear is meshed with the driving gear.

Referring to fig. 4, the right side of the pump housing is provided with a water inlet 811, and the right side of the pump housing is provided with a water outlet 812. When the mop head drives the supporting component to rotate clockwise, the driving gear drives the water pumping gear meshed with the driving gear to rotate anticlockwise, and the other water pumping gear rotates clockwise, so that water in the clear water area is sucked from the water inlet 811 and then is sprayed out from the water outlet 812, and flows through the valve body connected to the upper end of the pump cover and then is sprayed out from the spray head to clean the wiping materials.

In addition, the inner periphery or the outer periphery of the upper end of the mop bucket is connected with a cover body part 13, and the handle 14 is connected with the cover body part or the bucket opening of the mop bucket.

Example 2

As shown in fig. 10 and 11, the water pumping mechanism is a vortex pump; the mop bucket is characterized in that a pump shell 81 is arranged at the bottom in the mop bucket, a pump cover 84 is connected to the upper end of the pump shell, a pump cavity is formed between the pump shell and the pump cover, a water pumping gear 82 is arranged in the pump cavity in a rotating mode, the water pumping gear is coaxially connected with a driven gear 83, and the driven gear is meshed with the driving gear.

When the mop head rotates clockwise, the driving gear which also rotates clockwise drives the driven gear and the water pumping gear to simultaneously rotate anticlockwise. According to the working principle of the vortex pump, water in the mop bucket is sucked into the pump cavity from the water inlet 811, is pumped out from the water outlet 812 under the driving of the water pumping gear, and then flows through the valve body and is sprayed out from the spray head on the baffle cover to clean the wiping materials.

Claims (10)

1. A rotary mop kit, comprising: comprises a mop bucket and a mop, wherein the mop comprises a mop head with wiping materials and a mop rod movably connected to the upper end of the mop head; a supporting part is arranged in the mop bucket and can be detachably connected with the mop head; the mop bucket is also internally provided with a spray head for spraying water to the wiping objects and a water pumping mechanism for sending the water in the mop bucket to the spray head, and the mop head can directly or indirectly drive the water pumping mechanism to work when rotating; the mop rod is provided with a rotary driving mechanism for driving the mop head to rotate; a valve body for controlling the on-off of the pipeline is arranged on the water inlet pipeline or the water outlet pipeline of the water pumping mechanism; the mop head is connected with the supporting part, and when the rotary driving mechanism drives the mop head to rotate at a first rotating speed, the valve body is in a conducting state, and the spray head can spray water; the mop head is connected with the supporting part, and when the rotary driving mechanism drives the mop head to rotate at a second rotating speed, the valve body is in a closed state, and the spray head does not spray water.

2. A rotary mop kit as recited in claim 1, further comprising: the valve body comprises a water inlet pipe section, a water outlet pipe section and a valve core movably arranged between the water inlet pipe section and the water outlet pipe section, and when the valve core is positioned at an initial position, the valve body is in a conducting state; when the valve core is abutted against the water outlet pipe section, the valve body is in a closed state.

3. A rotary mop kit as recited in claim 2, further comprising: the valve body is vertically arranged, the water outlet pipe section is positioned above the water inlet pipe section, and the valve core is positioned at an initial position by means of self gravity; when the water flow thrust on the lower end of the valve core is larger than the self gravity, the valve core moves upwards to be abutted against the water outlet pipe section, so that the valve body is in a closed state.

4. A rotary mop kit as claimed in claim 2 or 3, wherein: a spring is arranged between the valve body and the water outlet pipe section, and the spring enables the valve body to be in an initial position when not influenced by other external forces; when the mop head rotates at a second rotating speed, the spring is compressed to the valve core to be abutted against the water outlet pipe section by the water pressure generated by the water pumping mechanism, so that the valve body is in a closed state.

5. A rotary mop kit as recited in claim 1, further comprising: the mop bucket is internally provided with a partition board, the mop bucket is internally positioned at two sides of the partition board to form an independent clear water area and a sewage area, and the water pumping mechanism is arranged in the clear water area.

6. The rotary mop kit of claim 5, wherein: a blocking cover is arranged above the clear water area, and a brush and the spray head are arranged on the blocking cover; when the mop head is connected with the supporting component, water falling from the wiping matter is guided into the sewage area by the blocking cover.

7. A rotary mop kit as recited in claim 1, further comprising: the supporting part is rotationally connected with the mop barrel, and when the mop head is connected with the supporting part, the supporting part is circumferentially fixed relative to the mop head, so that the mop head can drive the water pumping mechanism to work through the supporting part; or a linkage part coaxially arranged with the support part is rotationally arranged in the mop bucket and is connected with the water pumping mechanism; after the mop head is connected with the supporting part, the mop head is connected with the linkage part, so that the mop head can drive the pumping mechanism to work through the linkage part.

8. The rotary mop kit of claim 7, wherein: a positioning column is vertically arranged in the mop barrel, and the supporting part or/and the linkage part are/is rotatably sleeved on the positioning column; and the lower part of the supporting component or the linkage component is coaxially provided with a driving gear which is in transmission connection with the water pumping mechanism.

9. The rotary mop kit of claim 8, wherein: the water pumping mechanism is a gear pump; a pump shell is arranged at the bottom in the mop bucket, a pump cover is connected to the upper end of the pump shell, a pump cavity is formed between the pump shell and the pump cover, two pump water gears which are meshed with each other are rotatably arranged in the pump cavity, and the pump cavity and the two pump water gears form the gear pump; one water pumping gear is coaxially connected with a driven gear, and the driven gear is meshed with the driving gear; or the water pumping mechanism is a vortex pump; the mop bucket is characterized in that a pump shell is arranged at the bottom in the mop bucket, a pump cover is connected to the upper end of the pump shell, a pump cavity is formed between the pump shell and the pump cover, a water pumping gear is arranged in the pump cavity in a rotating mode, the water pumping gear is coaxially connected with a driven gear, and the driven gear is meshed with the driving gear and connected with the driving gear.

10. A rotary mop kit as recited in claim 1, further comprising: the rotary driving mechanism is a hand-press type rotary mop rod or a motor.

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