CN111345754A - Spraying and squeezing integrated electric mop bucket - Google Patents

Abstract

The invention discloses a spraying and squeezing integrated electric mop bucket which comprises a bucket body, wherein the bucket body comprises a squeezing area, a water storage area and a mounting area; a water squeezing seat capable of squeezing the wiping materials on the mop plate mutually is arranged in the water squeezing area in a longitudinal sliding mode. The front end of the water squeezing seat is provided with a water outlet which sprays water in the water storage area on the wiping object. The water-through seats communicated with the water storage area are fixedly connected to the left side and the right side of the water squeezing seat in the water squeezing area respectively; the periphery of each water-through seat is connected with a driving belt which drives the water squeezing seat to move longitudinally in a sealing and rotating way. The water through seat is uniformly formed with water through holes opposite to the driving belt along the circumferential direction; the driving belt is provided with a driving belt water outlet for communicating the water through hole with the water outlet; when the driving belt rotates, the water outlet of the driving belt is communicated with the water through hole at any time. The bucket body is internally provided with a lifting driving component for driving the driving belt to rotate and a gating component for controlling the opening and closing of the water outlet. The invention can continuously spray the water which drives the water storage area to be free from dirt on the wiping object.

Description

Spraying and squeezing integrated electric mop bucket

Technical Field

The invention belongs to the technical field of mops, and particularly relates to a spraying and squeezing integrated electric mop bucket.

Background

Chinese patent document No. CN108478133A discloses a one-way electric cleaning and water squeezing cleaning barrel for a flat mop, which comprises a barrel cover, a barrel body, a cleaning mechanism and a driving mechanism, wherein the driving mechanism comprises a motor, a transmission mechanism and a screw rod, the motor is fixed on the barrel cover, and the screw rod is arranged on screw rod connecting seats at the left side and the right side of the barrel cover; the cleaning mechanism comprises a cleaning support, a cleaning device and a water squeezing device, a stepped cleaning support seat and a water squeezing support seat which correspond to the cleaning device and the water squeezing device are arranged on the barrel body, and when the motor drives the cleaning support to horizontally move left and right through the screw rod, the cleaning device or the water squeezing device cleans or squeezes the flat mop placed on the cleaning support seat or the water squeezing support seat. After adopting above-mentioned structure, have simple structure reasonable, electric operation, intensity of labour is little, work efficiency is high, clean advantage such as effectual.

In the above-mentioned patent, mop washing and water storage are all in a bucket for the foul on the mop will be detained in the bucket, and when washing next time, the foul that detained before hangs again on the mop, causes secondary pollution, and if the foul hung on the mop different from the lateral wall of wiping thing, then need the user to take out it manually, increases user's extra work.

Disclosure of Invention

The technical problem to be solved by the invention is as follows: aiming at the defects existing in the prior art, the spraying and squeezing integrated electric mop bucket for cleaning the mop by using the continuous dirt-free water is provided.

In order to realize the purpose of the invention, the following technical scheme is adopted for realizing the purpose: a spraying and squeezing integrated electric mop bucket comprises a bucket body, wherein the bucket body comprises a water squeezing area, a water storage area and a mounting area; and a water squeezing seat capable of squeezing the wiping materials on the mop plate mutually is longitudinally and slidably arranged in the water squeezing area.

The front end of the water squeezing seat is provided with a water outlet which sprays water in the water storage area onto the wiping object.

The water-through seats communicated with the water storage area are fixedly connected to the left side and the right side of the water squeezing seat in the water squeezing area respectively; the periphery of each water passing seat is connected with a driving belt which drives the water squeezing seat to move longitudinally in a sealing and rotating way.

The water through seat is uniformly formed with water through holes opposite to the driving belt along the circumferential direction; the driving belt is provided with a driving belt water outlet for communicating the water through hole with the water outlet; when the driving belt rotates, the water outlet hole of the driving belt is communicated with the water through hole all the time.

And a lifting driving assembly for driving the driving belt to rotate and a gating assembly for controlling the opening and closing of the water outlet are arranged in the barrel body.

When the flat mop is positioned at the first position, water is discharged from the water outlet, and a distance is reserved between the wiping object and the water squeezing seat.

When the flat mop is at the second position, water cannot be discharged from the water outlet, and the wiping object is abutted against the water squeezing seat.

As an optimization scheme: the gating assembly comprises a gating shell fixedly connected in the mounting area and a valve plate hermetically and slidably connected in the gating shell.

And the side wall of the gating shell is provided with a gating water inlet joint communicated with the water storage area and a water passing seat joint communicated with the water passing seat.

When the flat mop is located at the first position, the valve plate is separated from the water through seat joint, and the water inlet joint is communicated with the water through seat joint.

When the flat mop is at the second position, the valve plate plugs the water through seat joint, and the water inlet joint is not communicated with the water through seat joint.

As an optimization scheme: the gating assembly further comprises a connecting rod and a driving plate, wherein one end of the connecting rod is fixedly connected to the valve plate, the other end of the connecting rod extends into the water squeezing area, and the driving plate is longitudinally connected to the water squeezing area in a sliding mode and drives the connecting rod to move.

As an optimization scheme: a water pump with a water inlet end communicated with the water storage area is fixedly connected in the mounting area; the water outlet end of the water pump is communicated with the gating water inlet joint.

As an optimization scheme: the lifting driving assembly comprises a driving shell which is arranged in the mounting area and communicated with the water outlet end of the water pump, an impeller which is rotatably connected in the driving shell and driven by water flow generated by the water pump, and a driving ring which is rotatably connected to the periphery of the driving shell and rotates synchronously with the impeller through magnetic force.

The driving ring is in transmission connection with a driving belt.

As an optimization scheme: a reduction gear set is fixedly connected in the mounting area; one end of the reduction gear set is in transmission connection with the driving ring, and the other end of the reduction gear set is in transmission connection with the driving belt.

As an optimization scheme: the left side and the right side of the water squeezing seat are respectively provided with a connecting seat.

The driving belt is fixedly connected with a water squeezing seat connecting part; the water outlet of the driving belt is formed on the connecting part of the water squeezing seat.

A driving joint which is rotatably connected with the connecting part of the wringing seat is connected in the connecting seat in a sliding manner along the horizontal direction; the driving joint is communicated with the water outlet of the driving belt.

As an optimization scheme: the lower part of the water squeezing area is fixedly connected with a filter seat.

And a sewage port communicated with the lower part of the filter seat is formed on the side wall of the barrel body.

Compared with the prior art, the invention has the beneficial effects that: when the mop is used, a user puts the mop plate on the upper end of the filtering seat, the mop plate presses the driving plate downwards, the valve plate moves in the reverse direction towards the gating water inlet joint, finally, the lower end of the mop plate abuts against the filtering seat, the valve plate plugs the backflow joint, and at the moment, a space exists between the wiping object and the water squeezing seat.

Then the button is pressed down, the water pump works, water flow generated by the water pump drives the impeller to rotate, and the impeller is driven to rotate through transmission of the driving ring and the reduction gear set, so that the water squeezing seat is driven to reciprocate to lift.

Meanwhile, the water pump sprays the water in the water storage area into the water passing seat through the water passing seat joint, flows into the water passing groove through the water passing hole communicated with the water outlet hole of the driving belt, and finally is sprayed out of the water outlet and sprayed on the wiping object to impact dirt on the wiping object and soak the wiping object.

And then moving the mop plate, abutting one end of the mop plate, which is far away from the wiping object, against the mop positioning bulge, abutting the wiping object on the water squeezing seat, and enabling the wiping object to be always abutted against the water squeezing seat by a user holding the mop rod with hands.

Meanwhile, the valve plate moves under the impact of water flow of the water pump, the water passing base connector is blocked by the valve plate, the water inlet connector is communicated with the backflow connector, water flow generated by the water pump directly returns to the water storage area through the backflow connector, the water pump only drives the impeller to rotate in the process, the water squeezing base moves, and then the water squeezing base squeezes out water on the wiping object.

After the wipe is squeezed, the button is pressed again and the pump stops working.

The process can be carried out in a toilet, and then the water in the water squeezing area can directly flow out through the sewage port.

The invention can control the water pump to work, so that the water squeezing seat can move longitudinally and the water outlet can spray water.

The invention switches the mop between the water spraying and squeezing states by changing the position of the flat mop.

The water passing seat is arranged, so that the water outlet can be communicated with the water passing seat no matter the driving belt moves to any position.

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 structure of the present invention.

FIG. 4 is a schematic structural view of the bucket body of the present invention.

Fig. 5 and 6 are schematic structural views of the water squeezing seat of the invention.

FIG. 7 is a schematic view showing the structure of the driving belt and the water passing base of the present invention.

Fig. 8 is an exploded view of the gating assembly of the present invention.

Fig. 9 is an exploded view of the lift drive assembly of the present invention.

Fig. 10 is a schematic view of the present invention in a first position.

Fig. 11 is a schematic view of the present invention in a second position.

1. A barrel body; 10. a rear cover; 11. a water squeezing zone; 111. an upper positioning seat; 112. a lower positioning seat; 12. a water storage area; 13. an installation area; 14. a filter base; 141. a drive plate sliding port; 142. a mop positioning bulge; 143. a water squeezing seat sliding strip;

2. a water squeezing seat; 21. a connecting seat; 22. a drive joint runner; 23. a water trough; 231. a water outlet; 24. a drive joint; 25. a water squeezing seat chute;

3. a flat mop;

41. a drive belt; 411. a wringing seat connecting part; 4111. driving a water outlet hole; 42. a water-passing seat; 421. a water through hole; 422. a water pipe; 43. an upper synchronizing roller; 44. a lower synchronizing roller; 441. a drive gear;

5. a gating component; 51. a drive plate; 511. a drive wall; 52. a connecting rod; 53. a valve plate; 531. a valve plate water through hole; 54. a gating housing; 541. a return joint; 542. a water passing seat joint; 543. a water inlet joint is gated;

6. a lift drive assembly; 61. a drive housing; 62. an impeller; 621. a first magnet; 63. a drive ring; 631. a second magnet; 632. a transmission gear;

71. a water pump; 72. a reduction gear set.

Detailed Description

Example 1

Referring to fig. 1 to 11, the spray drying integrated electric mop bucket of the present embodiment includes a bucket body 1 and a flat mop 3, wherein the bucket body includes a water squeezing area 11, a water storage area 12, and a mounting area 13.

The flat mop comprises a mop plate and a mop rod.

A water squeezing seat 2 capable of squeezing the wiping matters on the mop plate mutually is longitudinally and slidably arranged in the water squeezing area.

The front end of the water squeezing seat is provided with a water outlet 231 for pouring water in the water storage area on the wiping object.

The water passing seats 42 communicated with the water storage area are fixedly connected to the left side and the right side of the water squeezing seat in the water squeezing area respectively; the periphery of each water passing seat is connected with a driving belt 41 which drives the water squeezing seat to move longitudinally in a sealing and rotating way.

The water through seat is uniformly formed with water through holes 421 opposite to the driving belt along the circumferential direction; the driving belt is provided with a driving belt water outlet 4111 for communicating the water through hole with the water outlet; when the driving belt rotates, the water outlet hole of the driving belt is communicated with the water through hole all the time.

And a lifting driving component 6 for driving the driving belt to rotate and a gating component 5 for controlling the opening and closing of the water outlet are arranged in the barrel body.

When the flat mop is positioned at the first position, water is discharged from the water outlet, and a distance is reserved between the wiping object and the water squeezing seat.

When the flat mop is at the second position, water cannot be discharged from the water outlet, and the wiping object is abutted against the water squeezing seat.

The gate assembly includes a gate housing 54 fixedly attached within the mounting area, and a valve plate 53 sealingly slidably attached within the gate housing.

The side wall of the gating shell is provided with a gating water inlet joint 543 communicated with the water storage area and a water passing seat joint 542 communicated with the water passing seat.

When the flat mop is located at the first position, the valve plate is separated from the water through seat joint, and the water inlet joint is communicated with the water through seat joint.

When the flat mop is at the second position, the valve plate plugs the water through seat joint, and the water inlet joint is not communicated with the water through seat joint.

The gating assembly further comprises a connecting rod 52 with one end fixedly connected to the valve plate and the other end extending into the water squeezing area, and a driving plate 51 longitudinally connected to the water squeezing area in a sliding mode and driving the connecting rod to move.

The lower end of the driving plate is provided with a driving wall 511 which is obliquely arranged and is abutted against the connecting rod; when the drive plate moves downward, the drive wall pushes the drive rod to move.

A water pipe 422 for communicating the inside of the water base with the joint of the water base is formed on the water base.

A water pump 71 with a water inlet end communicated with the water storage area is fixedly connected in the mounting area; the water outlet end of the water pump is communicated with the gating water inlet joint.

The lifting driving assembly comprises a driving shell 61 which is arranged in the mounting area and communicated with the water outlet end of the water pump, an impeller 62 which is rotatably connected in the driving shell and driven by water flow generated by the water pump, and a driving ring 63 which is rotatably connected on the periphery of the driving shell and rotates synchronously with the impeller through magnetic force.

The driving ring is in transmission connection with a driving belt.

As shown in fig. 8, a backflow connector 541 is formed on the sidewall of the gating housing to communicate with the water storage region; the side wall where the backflow joint and the water passing seat joint are located is perpendicular to the side wall where the gating water inlet joint is located, and the backflow joint is close to the gating water inlet joint relative to the water passing seat joint.

The motion direction of the valve plate is vertical to the side wall where the gating water inlet joint is located; and a valve plate water through hole 421 is formed in the middle of the side wall parallel to the side wall where the gating water inlet joint is positioned on the valve plate.

When the flat mop is located at the first position, the mop plate pushes the drive plate to move downwards, so that the connecting rod drives the valve plate to move towards the gating water inlet joint, finally the backflow joint is blocked by the valve plate, the gating water inlet joint is communicated with the water base joint through the valve plate water through hole, the water pump works at the moment, the water pump sprays water in the water storage area onto a wiping object from the water outlet, and meanwhile, the water pump drives the impeller to rotate, and further, the drive belt is driven to move.

When the flat mop is located at the second position, the mop plate is separated from the drive plate, the water pump works at the moment, water entering through the gating water inlet joint generates thrust on the valve plate, the valve plate moves towards the direction far away from the gating water inlet joint, finally the valve plate is blocked towards the water through seat joint, then the water entering through the gating water inlet joint enters the water storage area from the backflow joint, and meanwhile, the water pump drives the impeller to rotate so as to drive the drive belt to move.

In the process that the valve plate moves towards the direction far away from the gating water inlet connector, the valve plate drives the connecting rod to move, and the connecting rod pushes the drive plate to move upwards.

Furthermore, a spring for driving the valve plate to move towards the direction far away from the gating water inlet connector is fixedly connected in the barrel body.

The connection relation among the water pump, the gating shell and the driving shell is as follows: the water outlet end of the water pump is communicated with the water inlet end of the driving shell, and the water outlet end of the driving shell is communicated with the gating water inlet joint.

A reduction gear set 72 is fixedly connected in the mounting area; one end of the reduction gear set is in transmission connection with the driving ring, and the other end of the reduction gear set is in transmission connection with the driving belt.

A transmission gear 632 in meshing transmission connection with the reduction gear set is formed on the periphery of the driving ring.

A lower synchronous roller 44 which drives the two driving belts to rotate is rotationally connected in the water squeezing area; the side wall of the lower synchronous roller is fixedly connected with a driving gear 441 which is in transmission connection with the reduction gear set.

The side wall of the wringing area is fixedly connected with a lower positioning seat 112 which is rotationally connected with the lower synchronous stick; an upper synchronous roller 43 which is rotationally connected with a driving belt is rotationally connected above the lower synchronous roller in the water squeezing area; the side wall of the water squeezing area is fixedly connected with an upper positioning seat 111 which is rotationally connected with the upper synchronous rod.

A plurality of first magnets 621 are uniformly and fixedly connected to the periphery of the impeller; a second magnet 631 attracted to the first magnet is fixedly connected to the driving ring along the circumferential direction.

When the water pump works, the impeller is driven to rotate by water flow, the driving ring rotates through the magnetic force between the first magnet and the second magnet, the lower synchronous rod is driven to rotate after the water pump is transmitted through the reduction gear set, the lower synchronous rod drives the driving belt to rotate, and the water squeezing seat is further driven to move.

The left side and the right side of the wringing seat are respectively provided with a connecting seat 21.

The driving belt is fixedly connected with a water squeezing seat connecting part 411; the water outlet of the driving belt is formed on the connecting part of the water squeezing seat.

A driving joint 24 which is rotatably connected with the connecting part of the wringing seat is connected in the connecting seat in a sliding manner along the horizontal direction; the driving joint is communicated with the water outlet of the driving belt; the side wall of the connecting base close to the driving belt is formed with a driving joint sliding groove 22 which is connected with the driving joint in a sliding way.

A water trough 23 communicated with the water outlet is formed on the water squeezing seat; the water trough is communicated with the driving joint through a corrugated pipe.

A water squeezing seat sliding strip 143 which is longitudinally arranged is fixedly connected in the water squeezing area; the water squeezing seat is formed with a water squeezing seat sliding groove 25 which is in sliding connection with the water squeezing seat sliding strip, so that the water squeezing seat can only longitudinally slide and can not move along the horizontal plane direction.

When the driving belt rotates, the connecting part of the water squeezing seat moves along a track in the shape of a runway, when the connecting part of the water squeezing seat moves to be close to the upper end and the lower end of the water through seat, the connecting part of the water squeezing seat moves along a circular arc track, and at the moment, the connecting part of the water squeezing seat drives the driving joint to move along the sliding groove of the driving joint, so that the water squeezing seat only moves longitudinally.

When the driving joint moves along the driving joint sliding groove, the corrugated pipe stretches or contracts, so that the driving joint is always communicated with the water passing groove.

The lower part of the water squeezing area is fixedly connected with a filter seat 14.

And a sewage port communicated with the lower part of the filter seat is formed on the side wall of the barrel body.

The water sprayed on the wiper through the water outlet washes dirt on the wiper down, flows to the lower part of the filter seat through the filter seat and flows to the outer side of the barrel body through the sewage port.

A driving plate sliding port 141 connected with the driving plate in a sliding manner is formed in the filter seat; mop positioning bulges 142 capable of abutting against the mop plate are formed on two sides of the upper end of the filter seat; when one end of the mop plate far away from the wiping object is abutted against the mop positioning bulge, the wiping object is abutted against the water squeezing seat.

The position of the barrel body in the installation area is fixedly connected with a rear cover 10.

A button is arranged on the barrel body; a controller and a storage battery are arranged in the mounting area; the motor and the button are respectively and electrically connected with the controller.

When the mop is used, a user puts the mop plate on the upper end of the filtering seat, the mop plate presses the driving plate downwards, the valve plate moves in the reverse direction towards the gating water inlet joint, finally, the lower end of the mop plate abuts against the filtering seat, the valve plate plugs the backflow joint, and at the moment, a space exists between the wiping object and the water squeezing seat.

Then the button is pressed down, the water pump works, water flow generated by the water pump drives the impeller to rotate, and the impeller is driven to rotate through transmission of the driving ring and the reduction gear set, so that the water squeezing seat is driven to reciprocate to lift.

Meanwhile, the water pump sprays the water in the water storage area into the water passing seat through the water passing seat joint, flows into the water passing groove through the water passing hole communicated with the water outlet hole of the driving belt, and finally is sprayed out of the water outlet and sprayed on the wiping object to impact dirt on the wiping object and soak the wiping object.

And then moving the mop plate, abutting one end of the mop plate, which is far away from the wiping object, against the mop positioning bulge, abutting the wiping object on the water squeezing seat, and enabling the wiping object to be always abutted against the water squeezing seat by a user holding the mop rod with hands.

Meanwhile, the valve plate moves under the impact of water flow of the water pump, the water passing base connector is blocked by the valve plate, the water inlet connector is communicated with the backflow connector, water flow generated by the water pump directly returns to the water storage area through the backflow connector, the water pump only drives the impeller to rotate in the process, the water squeezing base moves, and then the water squeezing base squeezes out water on the wiping object.

After the wipe is squeezed, the button is pressed again and the pump stops working.

The process can be carried out in a toilet, and then the water in the water squeezing area can directly flow out through the sewage port.

The invention can control the water pump to work, so that the water squeezing seat can move longitudinally and the water outlet can spray water.

The invention switches the mop between the water spraying and squeezing states by changing the position of the flat mop.

The water passing seat is arranged, so that the water outlet can be communicated with the water passing seat no matter the driving belt moves to any position.

Example 2

The present embodiment is different from embodiment 1 in that: a piston pump is arranged in the water squeezing area; the water inlet end of the piston pump is communicated with the lower part of the filter base, and the water outlet end of the piston pump is communicated with the water storage area.

The piston pump is directly controlled by the controller.

Or the piston pump is driven by the wringing seat, and when the wringing seat moves up and down, the wringing seat drives the piston in the piston pump to move up and down, so that the piston pump is driven to work.

The piston pump works to re-pump the water filtered by the filter base in the water squeezing area into the water storage area, so that no water accumulation exists in the water squeezing area, and the water utilization rate can be increased.

Claims (8)

1. A spraying and squeezing integrated electric mop bucket comprises a bucket body, wherein the bucket body comprises a water squeezing area, a water storage area and a mounting area; the method is characterized in that:

a water squeezing seat capable of squeezing the wiping matters on the mop plate mutually is longitudinally and slidably arranged in the water squeezing area;

the front end of the water squeezing seat is provided with a water outlet for pouring water in the water storage area on the wiper;

the water-through seats communicated with the water storage area are fixedly connected to the left side and the right side of the water squeezing seat in the water squeezing area respectively; the periphery of each water passing seat is hermetically and rotatably connected with a driving belt for driving the water squeezing seat to longitudinally move;

the water through seat is uniformly formed with water through holes opposite to the driving belt along the circumferential direction; the driving belt is provided with a driving belt water outlet for communicating the water through hole with the water outlet; when the driving belt rotates, the water outlet hole of the driving belt is communicated with the water through hole at any time;

a lifting driving component for driving the driving belt to rotate and a gating component for controlling the opening and closing of the water outlet are arranged in the barrel body;

when the flat mop is positioned at the first position, water is discharged from the water outlet, and a distance is reserved between the wiping object and the water squeezing seat;

when the flat mop is at the second position, water cannot be discharged from the water outlet, and the wiping object is abutted against the water squeezing seat.

2. The spray wringing integrated electric mop bucket of claim 1, wherein: the gating assembly comprises a gating shell fixedly connected in the mounting area and a valve plate hermetically and slidably connected in the gating shell;

the side wall of the gating shell is provided with a gating water inlet joint communicated with the water storage area and a water through seat joint communicated with the water through seat;

when the flat mop is positioned at the first position, the valve plate is separated from the water through seat joint, and the water inlet joint is communicated with the water through seat joint;

when the flat mop is at the second position, the valve plate plugs the water through seat joint, and the water inlet joint is not communicated with the water through seat joint.

3. The spray wringing integrated electric mop bucket of claim 2, wherein: the gating assembly further comprises a connecting rod and a driving plate, wherein one end of the connecting rod is fixedly connected to the valve plate, the other end of the connecting rod extends into the water squeezing area, and the driving plate is longitudinally connected to the water squeezing area in a sliding mode and drives the connecting rod to move.

4. The spray wringing integrated electric mop bucket of claim 2, wherein: a water pump with a water inlet end communicated with the water storage area is fixedly connected in the mounting area; the water outlet end of the water pump is communicated with the gating water inlet joint.

5. The spray wringing integrated electric mop bucket of claim 4, wherein: the lifting driving assembly comprises a driving shell which is arranged in the mounting area and is communicated with the water outlet end of the water pump, an impeller which is rotationally connected in the driving shell and is driven by water flow generated by the water pump, and a driving ring which is rotationally connected to the periphery of the driving shell and synchronously rotates with the impeller through magnetic force;

the driving ring is in transmission connection with a driving belt.

6. The spray wringing integrated electric mop bucket of claim 5, wherein: a reduction gear set is fixedly connected in the mounting area; one end of the reduction gear set is in transmission connection with the driving ring, and the other end of the reduction gear set is in transmission connection with the driving belt.

7. The spray wringing integrated electric mop bucket of claim 1, wherein: the left side and the right side of the wringing seat are respectively provided with a connecting seat;

the driving belt is fixedly connected with a water squeezing seat connecting part; the water outlet of the driving belt is formed on the connecting part of the water squeezing seat;

a driving joint which is rotatably connected with the connecting part of the wringing seat is connected in the connecting seat in a sliding manner along the horizontal direction; the driving joint is communicated with the water outlet of the driving belt.

8. The spray wringing integrated electric mop bucket of claim 1, wherein: the lower part of the water squeezing area is fixedly connected with a filtering seat;

and a sewage port communicated with the lower part of the filter seat is formed on the side wall of the barrel body.

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