CN111973102A

CN111973102A - Horizontal squeezing mop bucket kit

Info

Publication number: CN111973102A
Application number: CN202010907486.2A
Authority: CN
Inventors: 曲秀芹
Original assignee: Individual
Current assignee: Individual
Priority date: 2020-09-02
Filing date: 2020-09-02
Publication date: 2020-11-24

Abstract

The invention discloses a transverse squeezing mop bucket kit, which comprises a mop and a bucket body; the mop comprises a mop head and a mop rod which is rotationally connected to the mop head; the bucket body comprises a squeezing area for squeezing the mop head and a water storage area for cleaning the mop head; the squeezing area is internally provided with a squeezing component for squeezing the mop head; a water collecting box for receiving water extruded by the mop head is longitudinally and slidably connected in the extrusion area; a water outlet channel with an opening facing the water storage area is arranged on the water collecting box; when the water collecting box is positioned at the first position, the water collecting box collects the water squeezed out by the mop head; when the water collecting box is positioned at the second position, the water in the water collecting box flows into the water storage area through the water outlet channel.

Description

Horizontal squeezing mop bucket kit

Technical Field

The invention belongs to the technical field of daily supplies, and particularly relates to a transverse squeezing mop bucket kit.

Background

Chinese patent document No. CN209236062U discloses a collodion mop wringing barrel, which is characterized in that a cleaning barrel is divided into a cleaning part and a wringing part which are independent from each other, clear water is filled in the cleaning part, a mop extends into the cleaning part and moves up and down, the mop repeatedly contacts with the clear water to achieve the cleaning purpose, then the mop extends into the wringing part and moves up and down, and the mop wrings from a roller of a telescopic wringing roller assembly at the port of the wringing part to achieve the wringing purpose, wherein the telescopic wringing roller assembly can rotate in the barrel and reset through a torsion spring. The collodion mop squeezing barrel is convenient to carry, can be used for cleaning and squeezing a mop at any time and any place, is time-saving and labor-saving, is high in efficiency, and can be used for cleaning hair and dirt at the bottom of the mop particularly easily.

In the above-mentioned patent, will remain the water of being extruded in the wringing portion, because the hydroscopicity of glued membrane is great, through crowded dry back many times, will lead to the water in crowded cadre too much, wets the glued membrane secondary.

Disclosure of Invention

The technical problem to be solved by the invention is as follows: aiming at the defects in the prior art, the transverse squeezing mop bucket kit which can guide the water in the squeezing area into the water storage area is provided.

In order to realize the purpose of the invention, the following technical scheme is adopted for realizing the purpose: a transverse squeezing mop barrel kit comprises a mop and a barrel body; the mop comprises a mop head and a mop rod which is rotationally connected to the mop head; the bucket body comprises a squeezing area for squeezing the mop head and a water storage area for cleaning the mop head; and a squeezing component for squeezing the mop head is arranged in the squeezing area.

A water collecting box for receiving water extruded by the mop head is longitudinally and slidably connected in the extrusion area; the water collecting box is provided with a water outlet channel with an opening facing the water storage area.

When the water collecting box is positioned at the first position, the water collecting box collects the water squeezed out by the mop head.

When the water collecting box is positioned at the second position, the water in the water collecting box flows into the water storage area through the water outlet channel.

As an optimization scheme: the squeezing assembly comprises squeezing plates which are symmetrically connected in the barrel body in a sliding manner along the width direction of the barrel body and used for squeezing the mop head, and a driving frame which is longitudinally connected in a sliding manner and used for driving the squeezing plates to move in a squeezing area.

The mop rod is connected with a sliding sleeve which drives the driving frame to move in a sliding mode.

When the mop is positioned at the limit position in the squeezing area, the sliding sleeve moves to drive the driving frame to move.

And a tension spring for driving the extrusion plate to reset is arranged in the extrusion area.

As an optimization scheme: the extrusion area and the water storage area are separated by a water-stop sheet; and one end of the water outlet channel, which is far away from the center of the water collecting box, is a water outlet parallel to the water-stop sheet.

The water collecting box is rotatably connected with a sealing plate which can be in sealing and abutting contact with the water outlet; the upper end of the sealing plate can rotate towards the direction of the water storage area and can extend to the upper part of the water storage area.

When the sealing plate is aligned with the water-stop plate, the water-stop plate makes the sealing plate and the water outlet seal and abut against each other.

When the sealing plate is positioned above the water-stop plate, water in the water collection box pushes the sealing plate away.

As an optimization scheme: a mop positioning table for preventing a mop from contacting water in the water collecting box is formed at the bottom in the water collecting box; the mop positioning table is provided with a clamping head extending to the upper part of the water collecting box.

The mop head is provided with an elastic clamping plate which can be clamped with the clamping head.

When the mop is located at the limit position in the squeezing area, the clamping head is clamped with the elastic clamping plate, and the mop can drive the water collecting box to move upwards.

As an optimization scheme: the upper part of the barrel body is fixedly connected with a positioning seat used for preventing the water collecting box from moving upwards.

An extrusion inserting opening for a mop to pass through is formed above the extrusion area on the positioning seat; and the lower end of the positioning seat is positioned on the periphery of the extrusion socket and is provided with an extrusion lower convex ring extending towards the extrusion area.

The upper end of the inner periphery of the extrusion lower convex ring is formed with an inner convex ring which can be abutted against the upper end of the water collecting box so as to prevent the water collecting box from moving upwards.

The lower extrusion convex ring is uniformly and fixedly connected with a plurality of positioning magnets in the circumferential direction; the upper part of the side wall of the water collecting box is evenly and fixedly connected with a plurality of water collecting box magnets which can be mutually attracted with the positioning magnets.

When the upper end of the water collecting box is abutted against the lower end of the inner convex ring, the positioning magnet and the water collecting box magnet are tightly attracted with each other, the sealing plate is positioned above the water-stop sheet at the moment, and the water collecting box is positioned at the second position.

As an optimization scheme: a cleaning socket extending to the lower part of the water-stop sheet is formed on the positioning seat above the water storage area; the inner periphery of the cleaning socket is uniformly and fixedly connected with a hairbrush.

As an optimization scheme: the bottom in the water collecting box is a flow guide wall which is obliquely arranged towards the direction of the water outlet channel.

Compared with the prior art, the invention has the beneficial effects that: under the initial state, the water collection box is located the second position, and location magnet and water collection box magnet are inhaled each other tightly, and the closing plate separates with the delivery port, and the closing plate offsets with the water-stop sheet upper end, and the closing plate is kept away from the one end of water collection box and is located directly over the water storage district.

When the water storage device is used, water is added into the water storage area, so that the water level in the water storage area is lower than the height of the water-stop sheet.

The mop rod is held, the mop head is rotated, the length direction of the mop head is parallel to the mop rod, then the mop is inserted into the water storage area through the cleaning socket, the mop is moved longitudinally in a reciprocating mode, the collodion on the mop head is soaked, and meanwhile, the brush can scrape dirt on the collodion.

When the mop is extruded, the mop rod is held, the mop is inserted into the extrusion socket, when the mop is just inserted into the extrusion socket, the lower end of the mop head is abutted to the mop positioning table in the water collection box, the water collection box is forced to move downwards, then the water collection box magnet is separated from the positioning magnet, and the water collection box moves into the water collection box containing groove (namely, the first position) under the action of self gravity.

In the process that the mop head is inserted into the extrusion area, the lower pressing table on the sliding sleeve is abutted against the driving block on the driving frame, and the user holds the mop rod at the moment, so that the sliding sleeve cannot continuously move downwards, and the mop rod and the mop head continuously move towards the bottom in the extrusion area.

When the mop head moves to the upper end of the mop positioning table, the clamping head is clamped with the elastic clamping plate, so that the water collecting box and the mop head are relatively fixed.

Then the sliding sleeve is held and pushed downwards, so that the sliding sleeve drives the driving frame to move downwards, the two extrusion plates are driven to move oppositely, the collodion is extruded, water in the collodion is extruded, and the extruded water flows into the water collecting box.

When the sliding sleeve moves downwards until the sliding sleeve cannot move downwards continuously, the sliding sleeve moves upwards or is loosened, and the tension spring drives the two extrusion plates to reset.

After the collodion is extruded, holding the mop rod, lifting the mop upwards, and taking the mop out of the extrusion area, wherein in the process, the mop head drives the water collecting box to move upwards together due to the clamping of the clamping head and the elastic clamping plate; when the water collecting box moves to be abutted against the inner convex ring, the water collecting box can not move continuously, the mop moves upwards continuously at the moment, the clamping head is forced to be separated from the elastic clamping plate, and the water collecting box is positioned at the second position due to the fact that the positioning magnet and the water collecting box magnet are tightly attracted.

When the water collecting box moves to the second position, water in the water collecting box generates thrust on the sealing plate to push the sealing plate away, the water in the water collecting box flows into the water storage area under the guide of the sealing plate, and meanwhile, the barrel body is restored to the initial state, so that the water collecting box is convenient to use next time.

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 cross-sectional view of the barrel of the present invention.

Fig. 4 is a schematic view of the construction of the sump case according to the present invention.

Fig. 5 is a schematic structural diagram of the positioning seat of the present invention.

Fig. 6 is a schematic view of the present invention in a second position.

Fig. 7 is a schematic view of the present invention in a first position.

Fig. 8 is a schematic exploded view of the mop of the present invention.

FIG. 9 is an enlarged view of portion A of FIG. 1 according to the present invention.

1. A mop; 11. a mop rod; 12. a sliding sleeve; 121. pressing down the platform; 122. a positioning opening of the sliding sleeve; 13. a mop head; 131. an elastic clamping and connecting plate;

2. a barrel body; 20. a handle; 21. an extrusion zone; 211. a first guide rail; 212. the water collecting box is provided with a groove; 213. an upper boss; 2131. a stripper plate guide rail;

22. a water storage area; 23. a water-stop sheet; 231. a second guide rail;

3. positioning seats; 31. extruding the socket; 32. cleaning the socket; 321. a brush; 33. extruding the lower convex ring; 331. positioning a magnet; 332. an inner convex ring;

4. a pressing plate; 41. extruding the wall; 42. a tension spring positioning block;

5. a driving frame; 51. a drive wall; 52. a drive block;

6. a water collection box; 60. a flow guide wall; 61. a water collection box guide groove; 62. a water collection box magnet; 63. a mop positioning table; 64. clamping a head; 65. a water outlet channel; 66. and (7) sealing the plate.

Detailed Description

Example 1

Referring to fig. 1 to 9, the lateral squeezing mop bucket kit of the present embodiment includes a mop 1, a bucket body 2; the mop comprises a mop head 13 and a mop rod 11 which is rotationally connected to the mop head; the mop head comprises a mop plate and collodion fixedly connected to the mop plate; the bucket body comprises a squeezing area 21 for squeezing the mop head and a water storage area 22 for cleaning the mop head; and a squeezing component for squeezing the mop head is arranged in the squeezing area.

A water collecting box 6 for receiving water extruded by the mop head is longitudinally connected in the extrusion area in a sliding manner; the water collecting box is provided with a water outlet channel 65 with an opening facing the water storage area.

The squeezing assembly comprises squeezing plates 4 which are symmetrically connected in the barrel body in a sliding manner along the width direction of the barrel body and are used for squeezing the mop head, and a driving frame 5 which is longitudinally connected in the squeezing area in a sliding manner and drives the squeezing plates to move.

An upper boss 213 is respectively formed at the bottom of the extrusion region along the two sides of the width direction of the barrel body; a water collecting box containing groove for containing the water collecting box is formed between the two upper bosses; when the water collecting box is positioned in the water collecting box containing groove, the upper end of the upper boss is higher than or equal to the upper end of the water collecting box, and the water collecting box is positioned at the first position.

Two extrusion plate guide rails 2131 arranged in the width direction of the barrel body are formed on the upper boss; the extrusion plate is positioned between the two extrusion plate guide rails, so that the extrusion plate can only slide along the width direction of the barrel body.

An obliquely arranged extrusion wall 41 is formed at the upper part of one end of the extrusion plate, which is far away from the center of the barrel body; one end of the driving frame close to the center of the barrel body is formed with a driving wall 51 which is obliquely arranged and is abutted against the extrusion wall.

The mop rod is connected with a sliding sleeve 12 which drives the driving frame to move in a sliding way.

The lower end of the outer wall of the sliding sleeve is provided with symmetrically arranged lower pressing platforms 121; a driving block 52 which can be abutted against the lower pressing platform is formed on the driving frame; when the mop is positioned in the squeezing area, the lower pressing table is abutted to the driving block, the sliding sleeve is moved downwards at the moment, the lower pressing table generates thrust on the driving block, the driving frame is further driven to move downwards, and the two squeezing plates move oppositely to squeeze the mop head.

The lower end of the side wall of the sliding sleeve is provided with a sliding sleeve positioning opening 122 which can enable the lower end of the sliding sleeve to move to the lower part of the mop rod.

A tension spring positioning block 42 fixedly connected with one end of a tension spring is formed at the lower part of the side wall of the extrusion plate; the other end of the tension spring is fixedly connected to the inner wall of the extrusion area; when the sliding sleeve pushes the driving frame to move downwards and the two extrusion plates move oppositely to extrude the mop head, the tension spring is lengthened; when the sliding sleeve moves upwards, the two extrusion plates move towards the outer side of the barrel body under the action of the tension spring, and the driving frame moves upwards.

The extrusion area is separated from the water storage area by a water-stop sheet 23; and one end of the water outlet channel, which is far away from the center of the water collecting box, is a water outlet parallel to the water-stop sheet.

The water-stop sheet is formed in the barrel body and arranged along the width direction of the barrel body.

A first guide rail 211 which is longitudinally arranged is formed on the side wall of the water-stop sheet close to the extrusion area; a second guide rail 231 which is longitudinally arranged is formed on the side wall of the extrusion area far away from the water-stop sheet; the outer wall of the water collecting box is provided with a water collecting box guide groove 61 which is respectively connected with the first guide rail and the second guide rail in a longitudinal sliding mode, so that the water collecting box can only slide longitudinally in the extrusion area.

The water collecting box is rotatably connected with a sealing plate 66 which can be in sealing contact with the water outlet; the upper end of the sealing plate can rotate towards the direction of the water storage area and can extend above the water storage area; and a sealing plate rotating shaft which is rotatably connected with the water collecting box is formed at the lower parts of the two sides of the sealing plate along the width of the barrel body.

The water collecting box longitudinally moves in the extrusion area, when the lower end of the water collecting box is not higher than the upper end of the water-stop sheet, the sealing plate and the water-stop sheet are in a state of right alignment, and the water-stop sheet generates thrust to the sealing plate at the moment so that the sealing plate is sealed and abutted against the water outlet.

As shown in fig. 6, when the water collecting box moves upwards to the second position, the lower end of the sealing plate is higher than the upper end of the water stop plate, the sealing plate is separated from the water stop plate, and water in the water collecting box can push the sealing plate away and flows into the water storage area along the sealing plate.

When the water collecting box moves downwards from the second position, the sealing plate automatically rotates upwards under the pushing of the water-stop sheet to reset, and when the water collecting box moves to be aligned with the water-stop sheet, the sealing plate is abutted with the water outlet in a sealing mode again.

A mop positioning table 63 for preventing a mop from contacting water in the water collecting box is formed at the bottom in the water collecting box; a clamping head 64 extending to the upper part of the water collecting box is formed on the mop positioning table.

An elastic clamping plate 131 capable of being clamped with the clamping head is formed on the mop head; the elastic clamping and connecting plate is R-shaped.

The upper part of the barrel body is fixedly connected with a positioning seat 3 used for preventing the water collecting box from moving upwards.

A squeezing socket 31 for a mop to pass through is formed above the squeezing area on the positioning seat; and the lower end of the positioning seat is positioned on the periphery of the extrusion socket and is provided with an extrusion lower convex ring 33 extending towards the extrusion area.

An inner convex ring 332 which can abut against the upper end of the water collecting box and further prevent the water collecting box from moving upwards is formed at the upper end of the inner periphery of the extruding lower convex ring.

The lower extrusion convex ring is uniformly and fixedly connected with a plurality of positioning magnets 331 in the circumferential direction; the upper part of the side wall of the water collecting box is evenly and fixedly connected with a plurality of water collecting box magnets 62 which can be tightly attracted with the positioning magnets.

A cleaning socket 32 extending to the lower part of the water-stop sheet is formed above the water storage area by the positioning seat; the inner periphery of the cleaning socket is uniformly and fixedly connected with a brush 321.

The bottom in the water collecting box is a flow guide wall 60 which is obliquely arranged towards the direction of the water outlet channel.

A handle 20 convenient for moving the barrel body is rotatably connected on the barrel body.

As shown in fig. 6, in the initial state, the water collecting box is located at the second position, the positioning magnet and the water collecting box magnet are tightly attracted, the sealing plate is separated from the water outlet, the sealing plate abuts against the upper end of the water-stop plate, and one end, far away from the water collecting box, of the sealing plate is located right above the water storage area.

Then holding the sliding sleeve and pushing the sliding sleeve downwards to drive the driving frame to move downwards so as to drive the two extrusion plates to move oppositely to extrude the collodion and extrude the water in the collodion, wherein the extruded water flows into the water collecting box (as shown in fig. 7).

After the water squeezing is completed, the water collecting box can be driven to move upwards by pulling the mop upwards, so that water in the water collecting box can flow into the water storage area again finally, the water in the water storage area can not be obviously reduced, residual water does not exist in the squeezing area, and the phenomenon that water squeezed out for many times is accumulated in the squeezing area to cause the collodion to be soaked for the second time is avoided.

According to the invention, the extrusion plate can be driven to extrude the collodion cotton by pressing the sliding sleeve downwards, and the elastic clamping plate can be clamped with the water collecting box, so that the water collecting box is conveniently driven to move upwards, and the extruded water is discharged.

In the invention, when the water collecting box moves to the second position, water in the water collecting box can automatically burst the sealing plate and flow into the water storage area under the guidance of the sealing plate, and when the water collecting box moves downwards from the second position under the push of the mop, the water-stop plate can generate thrust to the sealing plate to tightly seal the sealing plate and the water collecting box, so that extruded water is prevented from flowing out from the sealing plate.

Claims

1. A transverse squeezing mop barrel kit comprises a mop and a barrel body; the mop comprises a mop head and a mop rod which is rotationally connected to the mop head; the bucket body comprises a squeezing area for squeezing the mop head and a water storage area for cleaning the mop head; the method is characterized in that: the squeezing area is internally provided with a squeezing component for squeezing the mop head;

a water collecting box for receiving water extruded by the mop head is longitudinally and slidably connected in the extrusion area; a water outlet channel with an opening facing the water storage area is arranged on the water collecting box;

when the water collecting box is positioned at the first position, the water collecting box collects the water squeezed out by the mop head;

2. A lateral squeeze mop bucket kit as defined in claim 1 wherein: the squeezing assembly comprises squeezing plates which are symmetrically connected in the barrel body in a sliding manner along the width direction of the barrel body and are used for squeezing the mop head, and a driving frame which is longitudinally connected in a sliding manner and drives the squeezing plates to move in a squeezing area;

the mop rod is connected with a sliding sleeve which drives the driving frame to move in a sliding manner;

when the mop is positioned at the limit position in the squeezing area, the sliding sleeve moves to drive the driving frame to move;

3. A lateral squeeze mop bucket kit as defined in claim 1 wherein: the extrusion area and the water storage area are separated by a water-stop sheet; one end of the water outlet channel, which is far away from the center of the water collecting box, is a water outlet parallel to the water-stop sheet;

the water collecting box is rotatably connected with a sealing plate which can be in sealing and abutting contact with the water outlet; the upper end of the sealing plate can rotate towards the direction of the water storage area and can extend above the water storage area;

when the sealing plate is aligned with the water-stop plate, the water-stop plate enables the sealing plate to be sealed and abutted against the water outlet;

4. A lateral squeeze mop bucket kit as defined in claim 3 wherein: a mop positioning table for preventing a mop from contacting water in the water collecting box is formed at the bottom in the water collecting box; a clamping head extending to the upper part of the water collecting box is formed on the mop positioning table;

an elastic clamping and connecting plate capable of being clamped with the clamping head is formed on the mop head;

5. A lateral squeeze mop bucket kit as defined in claim 3 wherein: the upper part of the barrel body is fixedly connected with a positioning seat used for preventing the water collecting box from moving upwards;

an extrusion inserting opening for a mop to pass through is formed above the extrusion area on the positioning seat; the lower end of the positioning seat is positioned on the periphery of the extrusion socket and is provided with an extrusion lower convex ring extending towards the extrusion area;

an inner convex ring which can abut against the upper end of the water collecting box to prevent the water collecting box from moving upwards is formed at the upper end of the inner periphery of the extrusion lower convex ring;

the lower extrusion convex ring is uniformly and fixedly connected with a plurality of positioning magnets in the circumferential direction; the upper part of the side wall of the water collecting box is uniformly and fixedly connected with a plurality of water collecting box magnets which can be mutually attracted with the positioning magnets;

6. A lateral squeeze mop bucket kit as defined in claim 5 wherein: a cleaning socket extending to the lower part of the water-stop sheet is formed on the positioning seat above the water storage area; the inner periphery of the cleaning socket is uniformly and fixedly connected with a hairbrush.

7. A lateral squeeze mop bucket kit as defined in claim 1 wherein: the bottom in the water collecting box is a flow guide wall which is obliquely arranged towards the direction of the water outlet channel.