CN110946521A - Crawler-type electric mop - Google Patents

Abstract

The invention discloses a crawler-type electric mop, which comprises a mop seat and a mop rod rotationally connected to the mop seat; the mop seat is provided with a wiping object which is connected with the head end and the tail end; one part of the wiping material is positioned at the lower end of the mop seat and can be contacted with the ground; a driving component for driving the wiper to rotate is arranged in the mop seat; the mop seat is provided with a squeezing part which can be squeezed with the wiping object. The acting force of the squeezing part on the wiping object in the squeezing state is larger than that of the squeezing part on the wiping object in the mopping state, and the squeezing part occupies smaller space and gravity and is convenient to move.

Description

Crawler-type electric mop

Technical Field

The invention belongs to the technical field of electric mops, and particularly relates to a crawler-type electric mop.

Background

Chinese patent document No. CN202714811U discloses a mop with self-cleaning function, wherein when the mop is pushed forward manually, the crawler-type mop is at a static state, and at this time, the crawler-type mop generates dynamic friction with the ground, i.e. cleans the ground, when the mop is pulled back, the crawler-type mop generates static friction with the ground, the crawler-type mop starts to rotate, and along with repeated pushing and pulling of the mop manually, the crawler-type mop rotates periodically, the area on the crawler-type mop wiped against the ground will rotate into the water storage tank, and contact with the water and the brush in the water storage tank, and along with the rotation of the crawler-type mop, the dirt on the area is scrubbed in the water storage tank, the scrubbed area then passes through between the squeeze roller and the deflection roller, the squeeze roller and the deflection roller squeeze the area, excess water on the area is squeezed out, and finally the area rotates back to the contact point with the ground again, the floor is wiped again, so that the work of cleaning the floor and self-cleaning is completed in a cycle.

Among the above-mentioned patent, be provided with the storage water tank on the mop, need add water in the storage water tank, lead to the holistic weight of mop to increase, inconvenient removal to squeeze roller produces the extrusion to the mop all the time when the mop rotates, increases the resistance of motion process.

Disclosure of Invention

The technical problem to be solved by the invention is as follows: aiming at the defects in the prior art, the electric mop which can extrude the wiping object slightly when mopping the floor and extrude the wiping object greatly and is convenient to move when squeezing water is provided.

In order to realize the purpose of the invention, the following technical scheme is adopted for realizing the purpose: a crawler-type electric mop comprises a mop seat and a mop rod which is rotatably connected with the mop seat; the mop seat is provided with a wiping object which is connected with the head end and the tail end; one part of the wiping material is positioned at the lower end of the mop seat and can be contacted with the ground; the mop seat is internally provided with a driving component for driving the wiper to rotate.

The mop seat is provided with a squeezing part which can be squeezed with the wiping object;

the acting force of the squeezing part on the wiping object in the squeezing state is larger than that of the squeezing part on the wiping object in the mopping state; the squeezing part is positioned at one end far away from the contact end of the wiper with the ground.

As an optimization scheme: the squeezing part is driven by a mop rod.

As an optimization scheme: the squeezing portion is driven by the wiper rotating in the reverse direction.

As an optimization scheme: the extrusion part is connected to the mop seat in a sliding manner.

As an optimization scheme: a first suction part is fixedly connected to the position, close to the mop seat, of the mop rod; the mop seat is fixedly connected with a second suction part which can be mutually sucked with the first suction part.

When the mop seat is in a water squeezing state, the first suction part and the second suction part are sucked tightly, and the squeezing part squeezes the wiper.

As an optimization scheme: the first and second suction parts are two magnets which are mutually sucked tightly.

Or,

one of the first and second suction parts is a magnet, and the other is a magnetizer.

As an optimization scheme: the driving component comprises a driving roller which is rotatably connected in the mop seat and drives the wiper to rotate, a sealing barrel which is fixedly connected in the mop seat, and a motor which is arranged in the sealing barrel in a sealing mode and drives the driving roller to rotate.

Compared with the prior art, the invention has the beneficial effects that: when mopping, press the switch, the motor drives the wiper and rotates, and the wiper of mop seat lower extreme cleans subaerial spot, and the user holds the mop pole for the mop seat does not take place to remove, and then the wiper can be to the lasting cleaning of ground, has the contained angle between mop pole and the last mop seat up end this moment, and the mop is in mopping state, above-mentioned in-process, and extrusion portion produces the extrusion to the wiper under self action of gravity, and extrusion portion is less to the effort of wiper this moment.

After the use, the switch is pressed again, and the motor stops working.

When the mop is cleaned, the mop rod is rotated, so that the mop is in a water squeezing state, the mop rod is vertically placed, one side of the mop seat, which is far away from the driving roller, is placed into water, the switch is pressed down, the wiper continuously rotates, and the wiper is soaked.

After the wiper is soaked, the user moves the mop seat, so that the mop seat is separated from the water surface, the wiper continues to rotate, the extrusion part extrudes water on the wiper, the extruded water flows out of the mop seat through the flow guide wall, and then the wiper is extruded to be dry, and in the process, the extrusion force of the extrusion part on the wiper is greater than that of the extrusion part on the wiper in a mopping state.

Drawings

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

Fig. 2 is a schematic exploded view of the present invention.

FIG. 3 is a schematic view of the upper mop base of the present invention.

FIG. 4 is a schematic view of the structure of the lower mop base of the present invention.

Fig. 5 is a schematic view of the structure of the pressing part of the present invention.

Fig. 6 is an exploded view of the drive assembly of the present invention.

Fig. 7 is a schematic sectional view showing the wringing state of the present invention.

Fig. 8 is a schematic sectional structure diagram of embodiment 2 of the present invention.

Fig. 9 is a schematic structural view of the pressing portion in embodiment 2 of the present invention.

1. A mop base; 11. an upper mop seat; 111. the extrusion part penetrates through the groove; 112. a pressing part sliding plate; 1121. a sliding groove; 113. a second suction portion; 12. a lower mop seat; 121. a wiper rotating roller;

2. a mop rod; 21. a first suction section;

3. a drive assembly; 31. a drive roller; 311. a containing groove; 32. a sealing cylinder; 33. a motor;

4. a wipe; 5. a pressing section; 51. pressing down the driving groove; 52. a pressing part sliding rod; 53. and a flow guide wall.

Detailed Description

Example 1

Referring to fig. 1 to 7, the crawler-type electric mop of the present embodiment includes a mop base 1, a mop rod 2 rotatably connected to the mop base; the mop seat is provided with a wiping object 4 connected with the head end and the tail end; one part of the wiping material is positioned at the lower end of the mop seat and can be contacted with the ground; the mop seat is internally provided with a driving component for driving the wiper to rotate.

The mop seat is provided with a squeezing part 5 which can be squeezed with the wiping object.

The force of the squeezing part on the wiping object in the squeezing state is larger than the force of the squeezing part on the wiping object in the mopping state. The squeezing part is positioned at one end far away from the contact end of the wiper with the ground.

The squeezing part is driven by a mop rod.

The extrusion part is connected to the mop seat in a sliding manner.

A first suction part 21 is fixedly connected to the position, close to the mop seat, of the mop rod; the mop seat is fixedly connected with a second suction part 113 which can be mutually sucked with the first suction part.

When the mop seat is in a water squeezing state, the first suction part and the second suction part are sucked tightly, and the squeezing part squeezes the wiper.

The first and second suction parts are two magnets which are mutually sucked tightly.

Or,

one of the first and second suction parts is a magnet, and the other is a magnetizer (an iron block or a stainless steel block, etc.).

The driving component comprises a driving roller 31 which is rotatably connected in the mop seat and drives the wiper to rotate, a sealing barrel 32 which is fixedly connected in the mop seat, and a motor 33 which is arranged in the sealing barrel and drives the driving roller to rotate.

A containing groove 311 for containing a sealing cylinder is formed at one end part of the driving roller; and an output shaft of the motor penetrates through the sealing barrel to be fixedly connected with the driving roller.

The mop seat comprises a lower mop seat 12 and an upper mop seat 11 which is detachably connected with the upper end of the lower mop seat; and a part of the wiping object is positioned at the lower end of the lower mop seat.

The driving roller is rotationally connected to one side of the lower mop seat; a wiping material rotating roller 121 contacted with the wiping material is rotatably connected to one side of the lower mop seat far away from the driving roller; the wiper is sleeved between the driving roller and the wiper rotating roller.

One end of the sealing cylinder, which is far away from the output shaft of the motor, is fixedly connected with the side wall of the lower mop seat.

A squeezing part through groove 111 is formed at the upper end of the upper mop seat and close to the driving roller; the upper end of the upper mop seat is positioned at the left end and the right end of the extrusion part through groove and is respectively and fixedly connected with an extrusion part sliding plate 112 extending upwards; the left and right sides of the extrusion part are respectively formed with extrusion part sliding rods 52 which are longitudinally and slidably connected with the extrusion part sliding plates.

A lower pressing driving groove 51 which can be abutted against the mop rod is formed at the upper end of the extrusion part; the mop rod is rotated in the direction of the squeezing part, after the mop rod is contacted with the pressing driving groove, the mop rod pushes the squeezing part to move towards the direction of the wiping object, when the first sucking part and the second sucking part are sucked tightly, the squeezing part is located at the limit position below, the squeezing part squeezes the wiping object, and the mop is in a water squeezing state at the moment.

Alternatively, the pressing portion presses the wiper against the driving roller when the pressing portion is located at the lower limit position.

And one end of the extrusion part, which is close to the extrusion part through groove, is formed with a flow guide wall 53 which is obliquely arranged.

As shown in fig. 7, when the mop is in a water squeezing state, the wiper rotates, the squeezing part squeezes out water on the wiper and flows to the flow guide wall, and then the outflow water flows out of the mop seat through the flow guide wall and the squeezing part through groove.

A storage battery is arranged in the mop rod; the mop rod is provided with a button.

When mopping, press the switch, the motor drives the wiper and rotates, and the wiper of mop seat lower extreme cleans subaerial spot, and the user holds the mop pole for the mop seat does not take place to remove, and then the wiper can be to the lasting cleaning of ground, has the contained angle between mop pole and the last mop seat up end this moment, and the mop is in mopping state, above-mentioned in-process, and extrusion portion produces the extrusion to the wiper under self action of gravity, and extrusion portion is less to the effort of wiper this moment.

After the use, the switch is pressed again, and the motor stops working.

When the mop is cleaned, the mop rod is rotated to enable the mop to be in a water squeezing state, the mop rod is vertically placed (as shown in fig. 7), then one side, away from the driving roller, of the mop seat is placed into water, the switch is pressed, the wiper continuously rotates, and the wiper is soaked.

After the wiper is soaked, the user moves the mop seat, so that the mop seat is separated from the water surface, the wiper continues to rotate, the extrusion part extrudes water on the wiper, the extruded water flows out of the mop seat through the flow guide wall, and then the wiper is extruded to be dry, and in the process, the extrusion force of the extrusion part on the wiper is greater than that of the extrusion part on the wiper in a mopping state.

Example 2

As shown in fig. 8 to 9, the present embodiment is different from embodiment 1 in that: the squeezing portion is driven by the wiper rotating in the reverse direction.

A sliding groove 1121 which is obliquely arranged is formed on the side wall of the extrusion part sliding plate, which is opposite to the extrusion part; the extrusion part sliding rod is connected in the sliding groove in a sliding mode.

When the wiper is driven by the motor to rotate in the forward direction (in the figure 8, the wiper rotates clockwise), the mop is in a mopping state, the wiper generates friction force on the squeezing portion, the squeezing portion moves in the direction away from the wiper along the sliding groove, the squeezing portion and the wiper are only in contact with each other, the action force of the squeezing portion on the wiper is small, and the wiper can clean the ground.

When the wiper is driven by the motor to rotate in the reverse direction (in the figure 8, the wiper rotates anticlockwise), the mop is in a water squeezing state, the wiper generates friction force on the squeezing portion, the squeezing portion moves towards the direction close to the wiper along the sliding groove, and then the squeezing portion squeezes the wiper.

A controller is arranged in the mop rod; the motor, the storage battery and the button are respectively and electrically connected with the controller.

Example 3

The present embodiment makes the following improvements on the basis of embodiment 1: a spring for driving the squeezer to move towards the upper part of the mop seat is arranged between the squeezing part and the mop seat; when the mop is in a mopping state, the squeezer is separated from the wiper under the action of the spring, and the force of the squeezer on the wiper is zero because the squeezer is not in contact with the wiper.

The mop rod is rotated towards the squeezer, and finally the mop is in a water squeezing state, at the moment, the squeezer squeezes the wiper, the wiper rotates, and then the squeezer squeezes out water on the wiper.

Claims (7)

1. A crawler-type electric mop comprises a mop seat and a mop rod which is rotatably connected with the mop seat; the method is characterized in that: the mop seat is provided with a wiping object which is connected with the head end and the tail end; a portion of the wipe is contactable with a ground surface; a driving component for driving the wiper to rotate is arranged in the mop seat;

the mop seat is provided with a squeezing part which can be squeezed with the wiping object;

the acting force of the squeezing part on the wiping object in the squeezing state is larger than that of the squeezing part on the wiping object in the mopping state;

the squeezing part is positioned at one end far away from the contact end of the wiper with the ground.

2. The tracked electric mop according to claim 1, wherein: the squeezing part is driven by a mop rod.

3. The tracked electric mop according to claim 1, wherein: the squeezing portion is driven by the wiper rotating in the reverse direction.

4. A tracked electric mop according to claim 2 or 3 wherein: the extrusion part is connected to the mop seat in a sliding manner.

5. A tracked electric mop according to claim 2 or 3 wherein: a first suction part is fixedly connected to the position, close to the mop seat, of the mop rod; the mop seat is fixedly connected with a second suction part which can be sucked with the first suction part;

when the mop seat is in a water squeezing state, the first suction part and the second suction part are sucked tightly, and the squeezing part squeezes the wiper.

6. The tracked electric mop according to claim 5, wherein: the first and second suction parts are two magnets which are mutually sucked tightly;

or,

one of the first and second suction parts is a magnet, and the other is a magnetizer.

7. The tracked electric mop according to claim 1, wherein: the driving component comprises a driving roller which is rotatably connected in the mop seat and drives the wiper to rotate, a sealing barrel which is fixedly connected in the mop seat, and a motor which is arranged in the sealing barrel in a sealing mode and drives the driving roller to rotate.

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