CN216454846U - Dust collection base station and cleaning system - Google Patents

Abstract

The application discloses collection dirt basic station and clean system for retrieve the rubbish in the cleaning machines people dirt box, the collection dirt basic station includes: the base station comprises a base station body, a dust collecting cavity and negative pressure equipment communicated with the dust collecting cavity, wherein a garbage suction inlet butted with a dust suction port of the cleaning robot is arranged at the bottom end part of the base station body, and the garbage suction inlet is communicated with the dust collecting cavity through a conveying channel; the dust collection barrel is detachably arranged in the dust collection cavity and comprises a barrel body with a cover body, a negative pressure suction port formed on the dust collection barrel, a dust collection chamber formed in the barrel body and a cyclone assembly arranged in the barrel body, wherein the negative pressure suction port is communicated with a garbage inlet on the barrel body; the cyclone component is provided with a transverse cyclone separating mechanism communicated with the garbage inlet and a longitudinal cyclone separating mechanism communicated with the negative pressure suction port, and the longitudinal cyclone separating mechanism is provided with an inner chamber independent of the dust collecting chamber.

Description

Dust collection base station and cleaning system

Technical Field

The application relates to the field of robots, in particular to a dust collecting base station and a cleaning system.

Background

With the development of science and technology and the improvement of living standard, the sweeping robot is widely applied. A cleaning robot, namely an automatic sweeper, an intelligent dust collector, an autonomous cleaner and the like, is one of intelligent household appliances and can complete the work of cleaning, dust collection, floor wiping and the like. The floor sweeping robot can be controlled by a person (an operator holds a remote controller) or automatically complete floor cleaning work in a room according to a certain set rule, and can clean hair, dust, debris and other floor impurities on the floor.

Because the dust box arranged in the existing cleaning robot cannot contain more garbage due to small volume, a user is further required to frequently clear the garbage in the dust box, so that not only is the operation of the user troublesome, but also secondary pollution to the environment is easily caused by manual cleaning of the garbage in the dust box by the user; therefore, a dust collecting base station for automatically collecting dust is provided in the related art, so that the dust in a dust box of the dust collecting base station can be automatically discharged after a cleaning robot finishes cleaning or detects that the dust in the dust box is fully loaded, but the volume of the dust collecting base station cannot reach a satisfactory state due to the space design of the related dust collecting base station or the design of internal components of the related dust collecting base station, and although the labor of manually removing the dust by a user is reduced to a certain extent, the volume design of the dust collecting base station still has a larger lifting space; moreover, the existing dust collecting base station can not finish garbage classification through air duct design so as to improve dust collecting efficiency.

SUMMERY OF THE UTILITY MODEL

In view of the above-mentioned drawbacks of the related art, the present application aims to provide a dust collecting base station and a cleaning system for solving the technical problem of automatically recycling the garbage in the dust box of the cleaning robot.

To achieve the above and other related objects, a first aspect of the present disclosure provides a dust collection base station for recovering garbage in a dust box of a cleaning robot, including: the base station body is provided with a dust collecting cavity and negative pressure equipment communicated with the dust collecting cavity, the bottom end part of the base station body is provided with a garbage suction inlet butted with a dust suction port of the cleaning robot, and the garbage suction inlet is communicated with the dust collecting cavity through a conveying channel; the dust collecting barrel is detachably arranged in the dust collecting cavity and comprises a barrel body with a cover body, a garbage inlet formed on the barrel body, a negative pressure suction port communicated with the negative pressure equipment, a dust collecting chamber formed in the barrel body and a cyclone assembly arranged in the barrel body; the cyclone component is provided with a transverse cyclone separating mechanism communicated with the garbage inlet and a longitudinal cyclone separating mechanism communicated with the negative pressure suction port, and the longitudinal cyclone separating mechanism is provided with an inner chamber independent of the dust collecting chamber.

A second aspect of the disclosure provides a cleaning system comprising a cleaning robot and a dust collection base station as described in the first aspect above, the dust collection base station being configured to recycle waste in a dust box of the cleaning robot.

In summary, in the dust collecting base station of the cleaning system of the present application, the arrangement of the horizontal cyclone separating mechanism and the vertical cyclone separating mechanism optimizes the space inside the dust collecting barrel, obtains a larger volume to accommodate more collected garbage, and improves the dust collecting efficiency by the two-stage cyclone separation and the inner chamber independent from the dust collecting chamber in the dust collecting chamber.

Drawings

The specific features of the invention to which this application relates are set forth in the appended claims. The features and advantages of the invention to which this application relates will be better understood by reference to the exemplary embodiments described in detail below and the accompanying drawings. The brief description of the drawings is as follows:

fig. 1 is a schematic configuration diagram of the dust collecting base station according to an embodiment of the present invention.

Fig. 2 is a schematic view of an installation structure of the docking assembly of the dust collecting base station according to an embodiment of the present invention.

Fig. 3 is a schematic view illustrating a dust collecting base station without a dust collecting bucket according to an embodiment of the present invention.

Fig. 4 is a schematic view illustrating a relationship between a dust collecting base station and a dust collecting bucket according to an embodiment of the present invention.

Fig. 5 is an exploded view of the dust collecting barrel and the cover thereof according to an embodiment of the present disclosure.

Fig. 6 is a schematic view illustrating a dust collecting base station and a dust collecting bag according to an embodiment of the present invention.

Fig. 7 is a schematic cross-sectional view of a dust collecting bucket according to an embodiment of the present invention.

Fig. 8 is an exploded view of the dust collecting barrel according to an embodiment of the present invention.

FIG. 9 is a schematic cross-sectional view of one aspect of the longitudinal cyclonic separation mechanism of one embodiment of the present application.

FIG. 10 is a schematic view of the longitudinal cyclone assembly in one embodiment of the present application.

FIG. 11 is a schematic top view cross-section of a longitudinal cyclone assembly according to an embodiment of the present disclosure.

FIG. 12 is a schematic view of a cleaning robot according to an embodiment of the present disclosure.

Fig. 13 shows an exploded view of a cleaning robot and its mop plate assembly according to an embodiment of the present application.

FIG. 14 is an exploded view of a docking assembly according to one embodiment of the present application.

Fig. 15 and 16 are schematic views illustrating the operation of the driving mechanism of the parking lot assembly according to an embodiment of the present invention.

Fig. 17-19 show a schematic view of the operation of the mop plate removing mechanism according to an embodiment of the present invention.

FIG. 20 is a schematic view illustrating shapes of first and second engaging structures according to an embodiment of the present disclosure.

Fig. 21 is an exploded view of a cleaning robot and base station docking assembly according to another embodiment of the present disclosure.

Fig. 22-24 show a schematic view of the operation of the mop plate removing mechanism of the present application in another embodiment.

Detailed Description

The following description of the embodiments of the present application is provided for illustrative purposes, and other advantages and capabilities of the present application will become apparent to those skilled in the art from the present disclosure.

In the following description, reference is made to the accompanying drawings that describe several embodiments of the application. It is to be understood that other embodiments may be utilized and that mechanical, structural, electrical, and operational changes may be made without departing from the spirit and scope of the present disclosure. The following detailed description is not to be taken in a limiting sense, and the scope of embodiments of the present application is defined only by the claims of the issued patent. The terminology used herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the application. Spatially relative terms, such as "upper," "lower," "left," "right," "lower," "below," "lower," "above," "upper," and the like, may be used herein to facilitate describing one element or feature's relationship to another element or feature as illustrated in the figures. In the present application, the "transverse direction" refers to the vertical direction, i.e., the direction from top to bottom or from bottom to top; the "longitudinal direction" refers to a direction perpendicular to the "lateral direction".

Although the terms first, second, etc. may be used herein to describe various elements or parameters in some instances, these elements or parameters should not be limited by these terms. These terms are only used to distinguish one element or parameter from another element or parameter. For example, a first engagement structure may be referred to as a second engagement structure, and similarly, a second engagement structure may be referred to as a first engagement structure, without departing from the scope of the various described embodiments. The first and second engagement structures are each described as one engagement structure, but they are not the same engagement structure unless the context clearly dictates otherwise.

Also, as used herein, the singular forms "a", "an" and "the" are intended to include the plural forms as well, unless the context indicates otherwise. It will be further understood that the terms "comprises," "comprising," "includes" and/or "including," when used in this specification, specify the presence of stated features, steps, operations, elements, components, items, species, and/or groups, but do not preclude the presence, or addition of one or more other features, steps, operations, elements, components, species, and/or groups thereof. The terms "or" and/or "as used herein are to be construed as inclusive or meaning any one or any combination. An exception to this definition will occur only when a combination of elements, functions, steps or operations are inherently mutually exclusive in some way.

The robot can be used indoors or outdoors, can be used for industry or families, can be used for replacing security patrol, replacing people to clean the ground, and can also be used for family companions, auxiliary office work and the like. Taking the most common sweeping robot as an example, the sweeping robot is also called an automatic sweeping machine, an intelligent dust collector, an autonomous cleaner, or a cleaning robot, etc., is one of intelligent household appliances, and can complete cleaning, dust collection, floor wiping/mopping work. With the development of the technology, the visual navigation technology such as VSLAM technology becomes a positioning, mapping and navigation technology commonly used for cleaning robots, and is applied in the field of cleaning robots, for example, the positioning system and method disclosed in chinese patent CN107907131B or US10436590B2, or the navigation method and navigation system disclosed in CN108885459B or US10518414B 1.

Most of the existing cleaning robots are provided with rechargeable batteries, and when the sweeping robot needs to be charged, the sweeping robot is usually charged and docked by a recharging seat matched with the sweeping robot. In practical application, the sweeping robot can automatically find and retrieve the charging seat for charging and butting in various modes such as infrared positioning, Bluetooth positioning and radar positioning. Because infrared positioning accuracy is higher, most of sweeping robot systems all adopt the infrared positioning technology, namely through setting up infrared signal emitter on recharging seat, utilize the infrared signal that infrared signal receiving device on the robot of sweeping floor received to guide the robot of sweeping floor to seek recharging seat, realize with recharging seat charging butt joint, for example the robot system that patent CN210092906U disclosed.

In addition, current cleaning machines people also all has the dirt box for the dust and the rubbish that storage cleaning machines people collected through the limit brush, round brush and vacuum cleaning system, need the manual dust box of user to take out in order to empty dirt box rubbish from cleaning machines people after rubbish is fully loaded in the dirt box, because install the internal dirt box volume of robot limited, need the user to clean the rubbish in the dust box all need manual after finishing at every turn, this burden that has increased the user to a certain extent, for this reason, this application provides a collection dirt basic station, a rubbish in the dust box of recovery cleaning machines people.

In an embodiment, the garbage in the dust box is collected into the dust box through a dust collection port of a cleaning robot, the cleaning robot is provided with a dust collection device, in the process of collecting the garbage, a side brush and a rolling brush of the cleaning robot rotate to collect the garbage in a traveling path of the robot to the dust collection port, and negative pressure passing through the dust collection port is sent into the dust box, and the dust collection device is specifically a suction fan or a vacuum pump. Wherein the garbage includes but is not limited to: soft crumb, dough, noodles, hard crumb, and the like. Wherein, the soft crumbs include: paper dust, plastic pieces, dust, etc. Examples of the dough include: hair balls, plastic bags, etc. Examples of the strip include: wires, stubs, wires, strips, etc. Examples of the hard chips include: the debris often produced by residential and office environments such as rice grains, paper clips, stones, pens and the like, is not exhaustive, and it should be understood that various types of trash are typically smaller in size than the diameter of the dust extraction opening and can enter the air duct of the cleaning robot with the air stream.

Referring to fig. 1, which is a schematic structural view of an embodiment of the dust collecting base station of the present application, as shown in the figure, the dust collecting base station 1 includes a base station body 10 and a dust collecting bucket detachably disposed in the base station body 10.

The dust collection base station 1 of the present application further comprises a docking assembly 12 extendedly disposed at the bottom of the base station body 10, and the dust suction inlet 120 of the dust collection base station 1 is disposed on the docking assembly 12 and used for connecting with a dust suction inlet of the cleaning robot when the cleaning robot is parked.

Referring to fig. 2, it is a schematic view of an installation structure of the docking assembly of the dust collecting base station in an embodiment of the present invention, as shown in the figure, in this embodiment, the docking assembly 12 includes two parts that can be assembled and disassembled, namely, a docking body 121 and a slope member 122; the berth body 121 and the gradient piece 122 are assembled and disassembled through a clamping structure. As shown in fig. 2, hooks 1221 are symmetrically disposed on an edge of one side of the parking body 121 facing the slope member 122, correspondingly, a slot structure 1222 corresponding to the hook 1221 is disposed on one side of the slope member 122 opposite to the parking body 121, and the parking body 121 and the slope member 122 are assembled by the engagement of the hook 1221 and the slot 1222.

The berth assembly 12 further comprises a slope piece 122 connected with the berth body 121 in a clamping manner, and the slope piece 122 is symmetrically provided with a falling groove 1220 used for limiting the moving wheels of the cleaning robot. As shown in fig. 2, the slope member 122 is symmetrically provided with a left and a right landing slots 1220 for limiting the left and the right moving wheels of the cleaning robot, so that the cleaning robot can be positioned to avoid sliding down or sliding down when the cleaning robot is parked on the parking lot assembly 12; in order to facilitate the cleaning robot to stop at the parking position assembly 12, the slope member 122 is further provided with anti-slip stripes corresponding to the moving wheels of the cleaning robot.

The docking body 121 is provided with a mop cloth manipulation area 1210 corresponding to the mop cloth disc assembly, the cleaning robot is parked at the docking position, and the mop cloth disc assembly is located at the mop cloth manipulation area 1210.

In other embodiments, the mop swab handling area 1210 is further provided with a water spray mechanism (not shown) for delivering a flow of water through a waterway mechanism provided within the base station to clean mops located on a mop swab assembly of the mop swab handling area 1210.

In the dust collection base station of this application, still including setting up the subassembly 17 that charges of base station body 10 bottom is used for electric connection when cleaning machines people berths cleaning machines people charging circuit, in this embodiment, subassembly 17 that charges is including connecting internal power supply circuit's positive, negative contact electricity piece, positive, negative contact electricity piece correspond the contact electrode slice on the cleaning machines people body to realize the electric connection of the two.

Referring to fig. 3, which is a schematic view illustrating a dust collecting base station of the present application in a state without a dust collecting barrel in an embodiment of the present application, as shown in the figure, a base station body 10 of the dust collecting base station 1 is provided with a dust collecting chamber 100 and a negative pressure device (not shown) communicating with the dust collecting chamber 100, a bottom end portion of the base station body 10 is provided with a dust suction port 120 abutting against a dust suction port of the cleaning robot, and the dust suction port 120 communicates with the dust collecting chamber 100 through a conveying passage (not shown).

In an embodiment, the garbage suction inlet 120 includes a sealing member (not numbered) made of soft glue for sealing a gap between the garbage suction inlet and the cleaning robot when the cleaning robot is coupled to the dust suction inlet.

In an embodiment, the negative pressure device is a vacuum blower or a suction fan for generating a negative pressure airflow during operation, and the negative pressure airflow can convey the garbage at the garbage suction opening 120 into the conveying channel, which is a conveying pipe in an embodiment, and convey the garbage into the dust collecting bucket of the dust collecting chamber 100 through the conveying channel.

In the embodiment, the base station body is further movably provided with a top cover for covering the dust collecting cavity, as shown in fig. 3, the top cover 11 is movably connected to the top end of the base station body 10 in a hinged manner for covering the internal space of the base station body 10, and particularly for covering the dust collecting cavity 100 of the base station body 10. In a specific example, in order to make the cover 11 and the dust collecting chamber 100 in a better sealing state in a closed state, a sealing member such as a sealing strip may be provided at a top end edge of the cover or the base station body 10; alternatively, as shown in fig. 3, the top edges of the cover or the base station body 10 have mutually matched bevel designs.

Referring to fig. 4, which is a schematic view illustrating a dust collecting base station and a dust collecting bucket according to an embodiment of the present invention, as shown in the drawings, the dust collecting bucket 13 is detachably disposed in the dust collecting chamber 100, and the dust collecting bucket 13 includes a bucket body 130, a garbage inlet 135, a negative pressure suction port 136, a dust collecting chamber, and a cyclone assembly.

The bin body 130 is provided with a cover 134, and the cover 134 is movably or detachably arranged at the bottom of the bin body 130 so as to pour out the garbage in the bin body 130; in one example, the cover 134 is movably disposed at the bottom of the barrel 130 by a hinge; in another example, the cover 134 may be removably disposed on the bottom of the barrel 130 via a snap-fit mechanism.

In the embodiment, a handle 137 is provided at the top 132 of the dust collecting bucket 13 to facilitate the dust collecting bucket 13 to be placed in the dust collecting chamber 100 or to be taken out from the dust collecting chamber 100.

Referring to fig. 5, which is an exploded view of the dust collecting barrel and the cover thereof according to an embodiment of the present invention, as shown in the figure, the cover 134 of the barrel 130 of the dust collecting barrel 13 is movably disposed at the bottom of the barrel 130 through a hinge structure 1340 at one end, and the other end is engaged with the cover 134 through a locking mechanism, and the engagement with the bottom of the barrel is released by pressing a button structure to release the garbage in the dust collecting chamber. As shown in the figure, the fastening mechanism can be released by pressing a button 1341 to open the cover 134, as shown in the figure, one end of the button 1342 has a hook 1343 for fastening the cover 134 to the barrel 130, a spring member 1343 is further disposed between the button 1342 and the barrel 130 to provide elastic restoring force for the button 1342, and a sealing ring 1344 is further disposed between the barrel 130 and the cover 134 to strengthen the sealing property in the closed state.

Referring to fig. 4, the garbage inlet 135 of the bin 130 is formed on the sidewall of the dust collecting bin 130, the garbage inlet 135 is abutted to the outlet 101 of the conveying channel, as shown in fig. 4, the outlet 101 of the conveying channel is formed on the sidewall of the dust collecting chamber 100, and the outlet 101 is communicated with the garbage suction port 120 of the berth body 121 through the conveying channel.

A negative pressure suction port 136 for communicating the negative pressure device (not shown) is further formed on the sidewall of the garbage inlet 135 on the same side as the barrel body 130, correspondingly, the negative pressure suction port 136 is in butt joint with the airflow inlet 102 of the negative pressure device, as shown in fig. 4, the airflow inlet 102 is formed on the sidewall of the dust collecting chamber 100, and the airflow inlet 102 is communicated with the negative pressure device through a pipeline.

In the embodiment provided in fig. 4, the waste inlet 135 and the suction inlet 136 of the tub 130 are located at the same side wall of the tub 130 and are adjacently disposed; correspondingly, the outlet 101 of the conveying channel of the dust collecting cavity 100 and the airflow inlet 102 of the negative pressure device are positioned on the same side wall of the dust collecting cavity 100 and are arranged adjacently.

In an embodiment, a guide groove structure 1010 is disposed around the outlet 101 of the conveying channel, and correspondingly, a guide rail structure 1350 corresponding to the guide groove structure 1010 is disposed around the waste inlet 135 of the bin 130, so as to realize the docking and sealing of the outlet 101 of the conveying channel and the waste inlet 135 through the cooperation of the guide rail structure 1350 and the guide groove structure 1010, and meanwhile, due to the opposite relationship between the outlet 101 of the conveying channel of the dust collecting chamber 100 and the airflow inlet 102 of the vacuum apparatus, the docking of the outlet 101 of the conveying channel of the dust collecting chamber 100 and the airflow inlet 102 of the vacuum apparatus is also realized through the cooperation of the guide rail structure 1350 and the guide groove structure 1010.

Referring to fig. 6, which is a schematic view illustrating a dust collecting base station and a dust collecting bag according to an embodiment of the present invention, as shown in the figure, the present embodiment further includes a dust collecting bag 14 detachably disposed in the dust collecting chamber 100, and the dust collecting bag 14 includes a bag body 140 and a garbage inlet 141.

The dust bag 14 is adapted to receive an air flow with the dust from the outlet 101 of the conveying passage of the dust chamber 100 and to retain the dust in the dust bag 14. The dust bag 14 may be disposable and composed of paper or fabric, such as non-woven fabric, that allows air to pass through but traps the cleaned dust, such that the airflow with the dust is received through the dust bag 14 and discharged through the airflow inlet 102 of the dust chamber 100, the cleaned dust being retained within the dust bag 14.

In order to collect the cleaned garbage to the outlet 101, the dust bag 14 is provided with a guide rail structure 1410 corresponding to the guide groove structure 1010 clamped to the peripheral side of the outlet 101 of the conveying channel, so that the compatibility of the dust collection barrel 13 and the dust collection bag 14 is realized, i.e. the garbage can 14 can be directly used for recovering the garbage without using the dust collection barrel 13. The garbage inlet 141 has the same specification as the dust collecting barrel 13, that is, the garbage inlet 141 has a guide rail structure 1410 of the guide groove structure 1010 which can be assembled on the peripheral side of the outlet 101 of the conveying channel, and the guide rail structure 1410 is matched with the guide groove structure 1010 to realize the butt joint and sealing of the outlet 101 of the conveying channel and the garbage inlet 141. In this embodiment, the rail structure 1410 is a fixed card.

In this embodiment, the dust bag 14 may be disposable and composed of paper or fabric, such as an air permeable nonwoven fabric, that allows air to pass therethrough but traps the cleaned dust, such that the airflow with the dust is received by the disposable dust bag 14 and exits the cleaning airflow through the airflow inlet 102 of the dust chamber 100, the cleaned dust being retained within the dust bag 14.

Referring to fig. 7, which is a schematic cross-sectional view illustrating a dust collecting bin according to an embodiment of the present invention, as shown in the drawings, a dust collecting chamber 131 is formed in a bin body 130 of the dust collecting bin 13 for collecting the garbage fed through the garbage inlet 135.

The body 130 of the dust collecting tub 13 is provided with a cyclone assembly, which in this application includes a lateral cyclone separating mechanism 15 and a longitudinal cyclone separating mechanism 16. Wherein, the horizontal cyclone separating mechanism 15 is communicated with the garbage inlet 135, and the vertical cyclone separating mechanism 16 is communicated and arranged on the negative pressure airflow path between the horizontal cyclone separating mechanism 15 and the negative pressure suction port 136. The longitudinal cyclonic separating mechanism 16 has an inner chamber 1606 separate from the dirt collection chamber 131.

Referring to fig. 8 together with fig. 7, which is an exploded view of a dust collecting barrel according to an embodiment of the present invention, as shown, the horizontal cyclone separating mechanism 15 includes a horizontal cyclone cylinder 150 and a horizontal filter cylinder 151.

As shown in fig. 7 and 8, a rotational flow plate 1501 is disposed in the front end cylindrical body 1500 of the transverse cyclone 150, the rotational flow plate 1501 can generate a rotational flow by an airflow in the front end cylindrical body 1500, the rotational flow plate 1501 can also be referred to as a rotational flow blade, and a separation opening (not shown) facing the dust collecting chamber 131 is formed in a cylindrical wall of the front end cylindrical body 1500 of the transverse cyclone 150, and is configured to allow garbage passing through the front end cylindrical body 1500 of the transverse cyclone 150 to fall into the dust collecting chamber 131 from the separation opening through cyclone separation.

In an embodiment, as shown in FIG. 7, the first end of the front end cylindrical body 1500 of the lateral cyclone 150 abuts against the waste inlet 135, and to facilitate sealing at the interface between the front end cylindrical body 1500 of the lateral cyclone 150 and the waste inlet 135, a sealing ring/gasket 1502 may be applied at the junction of the two, as shown in FIG. 8.

As shown in fig. 7 and 8, the transversal filter cartridge 151 of the transversal cyclone 150 is coaxially disposed in the rear cylinder 1503 of the transversal cyclone 15, and the transversal filter cartridge 151 includes a closed front end 1510, an open rear end 1511, and a filter net 1512 surrounding the closed front end 1510 and the open rear end 1511. In one embodiment, the closed front end 1510 is connected to the open rear end 1511 by a bracket 1513, and the filter 1512 is enclosed by the bracket 1513.

In an embodiment, the closed front end 1510 is a closed end face of the front end of the transversal filter cartridge 151 to prevent the air flow from entering the inside of the cylinder of the transversal filter cartridge 151 from the end face, forcing the air flow to enter the inside of the cylinder thereof through the filter screen 1512 on the cylinder; the open rear end 1511 is an open end, and is intended to allow the airflow entering through the filter screen 1512 to pass from the open rear end 1511 to the next stage, i.e., the space of the longitudinal cyclonic separating apparatus 16. In this embodiment, a gasket 1514 may be applied in combination with the longitudinal cyclonic separating apparatus 16 in order to seal the interface of the transverse filter cartridges 151 with the inlet thereto tightly, as shown in figure 8.

In an embodiment, due to the arrangement of the filter screen 1512 of the transverse filter cylinder 151, the garbage with larger particles (or particle sizes) in the transverse cyclone cylinder 150 cannot enter the transverse filter cylinder 151 and is separated by cyclone, the garbage rotates at a high speed in the first layer of cyclone dust channel, the garbage is separated from the airflow by centrifugal force, and then falls into the dust collection chamber 131 along the wall by gravity, so as to realize the first garbage classification.

As shown in fig. 7 and 8, the longitudinal cyclone separating mechanism 16 includes a longitudinal inner barrel 160 and a longitudinal cyclone assembly 161.

The longitudinal inner barrel 160 includes an upper barrel body 1600 and a lower barrel body 1601, wherein the lower barrel body 1601 is spatially separated from the upper barrel body 1600, in this embodiment, the spatial separation of the lower barrel body 1601 and the upper barrel body 1600 is achieved through a partition plate 1602, specifically, the partition plate 1602 may be integrally formed on the lower barrel body 1601 or the upper barrel body 1600, or the partition plate 1602 may be disposed between the lower barrel body 1601 and the upper barrel body 1600 through a fixing member such as a screw, for facilitating the combination of the lower barrel body 1601 and the upper barrel body 1600, a gasket 1603 may be additionally disposed between the lower barrel body 1601 and the upper barrel body 1600, and a plurality of mounting holes (not shown) are opened on the partition plate 1602 so that the bottom end of the longitudinal cyclone assembly 161 can pass through to communicate with the lower barrel body 1601.

In an embodiment, the lower barrel 1601 of the longitudinal inner barrel 160 has a space reducing structure from top to bottom.

Referring to fig. 9, which is a schematic cross-sectional view of a longitudinal cyclone separation mechanism according to an embodiment of the present invention, as shown in the drawings, an opening 1604 is formed on a sidewall of the upper tub 160 for engaging with an open rear end 1511 of the transverse filter cartridge 151; the bottom opening 1605 of the lower barrel 1601 contacts the bottom of the dust collecting barrel 13 to form an inner chamber 1606 independent from the dust collecting chamber 131, the inner chamber 1606 is used for collecting the garbage with smaller particles (or particle size) which is filtered by the transverse filter cylinder 151, brought into the longitudinal cyclone assembly 161 by the airflow, and separated by the longitudinal cyclone assembly 161, thereby realizing the secondary garbage classification.

Referring to fig. 10 together with fig. 9, fig. 10 is a schematic structural diagram of a longitudinal cyclone assembly in an embodiment of the present invention, as shown in the drawings, the longitudinal cyclone assembly 161 is longitudinally disposed in the upper tub 1600, and includes a plurality of inner cyclone tubes 1610 which are distributed in an array and are spatially independent, a bottom opening 1611 of each inner cyclone tube 1610 extends to communicate with an inner space of the lower tub 1601, i.e., an inner chamber 1606 of the dust collecting chamber 131; the top end opening 1612 of each of the internal cyclone tubes communicates with the negative pressure suction port 136.

Referring to fig. 11, which is a schematic sectional view of the longitudinal cyclone assembly in an embodiment of the present invention, as shown in the drawings, in the embodiment, a total of 6 spatially independent internal cyclone tubes 1610 are arranged in an arc shape following the shape of the upper barrel body 1601 and are disposed in the upper barrel body 1600, and a vacant space 1607 is reserved between the upper barrel body 1600 and the vacant space 1607, and the vacant space 1607 is communicated with the opening 1604.

In an embodiment, the upper end portion of each internal cyclone pipe is provided with a dust inlet facing the transverse cyclone separation mechanism, and the dust inlet is isolated from the clean air channel space by the middle cover. As shown in fig. 9 to 11, each inner cyclone tube 1610 is a space-reduced structure (or a tapered tube structure) from top to bottom, that is, has a bottom opening 1611 with a smaller opening and a top opening 1612 with a larger opening, as shown in fig. 9, a dust inlet 1613 of the inner cyclone tube 1610 is disposed near the top end 1612 of each inner cyclone tube 1610, a spacer 1608 is disposed at the top end 1612 of the inner cyclone tube 1610, and the spacer 1608 is opened to facilitate the cyclone airflow in the inner cyclone tube 1610 to enter the clean air passage 139 through the opening of the spacer 1608. Due to the arrangement of the isolation gasket 1608, the negative pressure airflow entering the dust inlet 1613 does not directly flow out of the clean air passage 139, but first enters the inner cyclone tube 1610 for swirling flow and then enters the clean air passage 139 through the opening of the isolation gasket 1608. The dust inlet 1613 is communicated with the empty space 1607 of the upper tub 1600, so that the airflow passing through the transversal filter cartridge 151 enters the empty space 1607 of the upper tub 1600 through the open rear end 1511, and then enters each of the inner cyclone tubes 1610 through the airflow inlet 1613 of each of the inner cyclone tubes 1610 to generate a re-cyclone, so as to cyclone the garbage with smaller particles (or particle sizes) entering each of the inner cyclone tubes, so that the garbage falls into the inner chamber 1606 independent from the dust collecting chamber 131 through the bottom end opening 1611 of each of the inner cyclone tubes 1610.

In the embodiment, the dust collecting barrel 13 further comprises a middle cover 138 for spatially isolating the dust collecting chamber 133, and a clean air passage 139 for communicating a top end opening 1612 of each internal cyclone tube 1610 and the negative pressure suction port 136 is formed between the middle cover 138 and the top surface of the dust collecting barrel 13.

In order to further illustrate the inventive principle and efficacy of the present application, in the working state of the dust collecting base station of the present application, the cleaning robot is parked on the parking component 12, the dust suction port of the cleaning robot is in channel butt joint with the garbage suction port 120 of the dust collecting base station 1, the control device of the dust collecting base station controls the negative pressure device of the vacuum fan or the exhaust fan to work and generate negative pressure airflow, so that the garbage collected by the dust box in the cleaning robot is sucked into the garbage suction port 120 from the dust suction port, and then reaches the dust collecting barrel 13 in butt joint with the dust collecting cavity 100 from the garbage suction port 120 through the conveying channel, namely enters the garbage inlet 135 of the barrel body 130 and then enters the transverse cyclone separating mechanism 15, and passes through the cyclone generated by the front end barrel body 1500 of the transverse cyclone separating mechanism 15, the garbage in the front end barrel body 1500 is separated by the cyclone and falls into the dust collecting chamber 131 from the separating port, so as to realize the first garbage classification, the waste, which is now larger particles, is separated into the dust chamber 131, and due to the presence of the transverse filter cartridge 151, so that the garbage with smaller particles which are not separated passes through the filter screen 1512 of the transverse filter cylinder 151 and enters the vacant space 1607 of the longitudinal inner barrel 160 through the open rear end 1511, then enters the inner cyclone tube 1610 through the dust inlet 1613 of each inner cyclone tube 1610 to be separated again, the garbage with smaller particles (or particle sizes) entering the internal cyclone tubes is separated in a cyclone manner, the garbage can rotate from top to bottom along the inner walls of the internal cyclone tubes, the garbage particles are separated from the airflow under the action of centrifugal force, and fall into the inner chamber 1606 independent of the dust collecting chamber 131 along the bottom opening 1611 of each internal cyclone tube 1610 for collection under the action of gravity, so that secondary garbage classification is realized; at this time, due to the rotational flow generated by each internal cyclone 1610, the airflow will flow upward from the top opening 1612 of the internal cyclone along the rotation direction of the internal cyclone, and enter the negative pressure suction port 136 through the air cleaning passage 139, and then be discharged out of the dust collecting base station.

In the dust collection base station, the arrangement of the transverse cyclone separation mechanism and the longitudinal cyclone separation mechanism is adopted, so that the space in the dust collection barrel is optimized, a larger volume is obtained to accommodate more collected garbage, and the two stages of cyclone separation and the inner chamber independent of the dust collection chamber are arranged in the dust collection chamber, so that the two-stage separation improves the dust collection efficiency.

In addition, the dust collection base station of this application still compatible dust bag or disposable filter bag, and because the design of the same specification for the dust bag can directly set up in the dust collection intracavity, need not to set up the dust bag in the dust collection bucket, and then made things convenient for user's use.

The present application further provides a cleaning system comprising a cleaning robot and a dust collection base as described above with respect to any of the embodiments of fig. 1-11 for recycling debris within a dust box of the cleaning robot.

In the related art, the cleaning robot has not only undertaken the tasks of cleaning and vacuum cleaning, and in some situations, the cleaning robot needs to carry a mop device to wipe a cleaning surface, such as a floor, for example, a water tank and a water spraying mechanism are arranged on a chassis of the cleaning robot, a mop device is arranged on the lower side of the water tank, water in the water tank is sprayed or permeated on the mop device through the water spraying mechanism, and a mop/mop cloth installed on the mop device is wiped on the ground through the movement of the robot to achieve the function of wiping the ground.

Referring to fig. 12 and 13, fig. 12 is a schematic view of a cleaning robot according to an embodiment of the present invention, and fig. 13 is an exploded schematic view of the cleaning robot and a mop plate assembly thereof according to an embodiment of the present invention, as shown in the drawings, a mop device mounted on a chassis 20 of the cleaning robot 2 according to the present invention is a mop plate assembly 21, a mop 211 is mounted on the mop plate assembly 21, and the rotation of the mop plate assembly 21 is controlled by the cleaning robot 2 to wipe the floor surface with the mop 211 mounted thereon, thereby completing the function of wiping the floor surface. Specifically, as shown in fig. 13, the mop plate assembly 21 is mounted on a water tank assembly 24 provided on the chassis 20 of the cleaning robot 2, which supplies water to the mop 211 on the mop plate assembly 21 by way of water, hereinafter collectively defined as the mop plate assembly 21 is detachably mounted on the chassis 20 of the cleaning robot 2 for the convenience of the following description.

The application provides a mop plate loading and unloading mechanism, which is applied to a cleaning system comprising a cleaning robot and a base station, wherein the base station is the dust collection base station. The mop plate loading and unloading mechanism comprises: a mop plate assembly 21 and a docking assembly 12.

The mop swab assembly 21 is detachably mounted on the bottom chassis 20 of the cleaning robot 2, and includes a tray body 210 and a mop swab 211 disposed on a lower surface of the tray body 210; a first magnetic member 212 is disposed at a central portion of a lower surface of the disc body 210.

The chassis 20 of the cleaning robot 2 is provided with a rotating shaft which is driven by a driving mechanism inside the chassis of the robot, a control system of the cleaning robot controls the driving mechanism to rotate the rotating shaft, and when the mop cloth disc assembly 21 is installed on the rotating shaft, the mop cloth disc assembly 21 can be driven to rotate through the rotation of the rotating shaft.

In one embodiment, the mop plate assembly 21 is detachably mounted on the chassis 20 of the cleaning robot 2 in a snap-fit manner, such as removably mounting the mop plate assembly 21 to the chassis 20 of the cleaning robot 2 by a physical configuration snap fit of an interference fit, the interference fit structure, such as a slot or a protrusion, specifically, for example, an annular protrusion is provided on the rotating shaft, a groove structure matched with the annular bulge is arranged in the corresponding rotary hole of the mop plate component 21, the mounting of the mop disc assembly 21 on the spindle is thus achieved, it being understood that the mounting of the mop disc assembly 21 on the spindle can be achieved without the aid of additional force, such as, in the present application, it can be placed on the spindle by simply applying a force to the mop plate assembly 21 towards the spindle; or an opposing force may be applied to remove the mop plate assembly 21 from the spindle.

In another embodiment, the mop plate assembly 21 is detachably mounted on the chassis 20 of the cleaning robot 2 in a magnetic attraction manner. In this embodiment, the magnetic attraction is a magnetic attraction of a magnet pair made of iron, cobalt, or nickel or an alloy material including any of iron, cobalt, and nickel. In this embodiment, the chassis 20 of the cleaning robot 2 is provided with a magnetic attraction rotating shaft 22 correspondingly combined with the mop plate assembly 21, and the magnetic attraction rotating shaft 22 is driven to rotate by a driving mechanism 23 arranged on the chassis 20 of the cleaning robot 2. Wherein the driving mechanism is, for example, a gear assembly driven by a motor, and the gear assembly includes a plurality of gears, and the gears are engaged with each other to transmit the power output by the motor to the magnetic attraction rotating shaft 22. In this embodiment, the magnetic attraction rotating shaft is made of iron, cobalt, or nickel, or an alloy material containing any one of iron, cobalt, and nickel.

The mop swab assembly further comprises a catch arrangement 213 and a third magnetic element 214. The slot structure 213 is formed on the upper surface of the disk body for the magnetic rotation shaft 22 to be inserted into, and the magnetic rotation shaft 22 can drive the disk body to rotate when rotating. In this embodiment, in order to facilitate the magnetic rotary shaft 22 is conveniently inserted into the clamping groove structure 213, the shaft head part of the magnetic rotary shaft 22 is designed to be of an inverted trapezoidal structure with an axial cross section, the radial cross section of the magnetic rotary shaft 22 is hexagonal, correspondingly, the clamping groove structure 213 conforms to the appearance structure of the magnetic rotary shaft 22 is also hexagonal, the longitudinal cross section of the clamping groove structure is of an inverted trapezoidal structure, the side wall of the inner space thereof is also designed to conform to the hexagonal shape of the magnetic rotary shaft 22, and further the magnetic rotary shaft 22 is driven to rotate the mop disc assembly 21.

In order to retain the entire mop plate assembly 21 on the chassis 20 of the cleaning robot 2, or the entire mop plate assembly 21 on the magnetic rotation shaft 22, when the magnetic rotation shaft 22 is inserted into the slot structure 213, the bottom of the slot structure 213 is provided with a third magnetic member 214. In this embodiment, the third magnetic member is a permanent magnet or an electromagnet, and is used for attracting the magnetic attraction rotating shaft 22 made of iron, cobalt, or nickel, or an alloy material containing any one of iron, cobalt, and nickel, so as to hold the whole mop plate assembly 21 on the chassis 20 of the cleaning robot 2.

A first magnetic member 212 is disposed at a central portion of the lower surface of the disc body 210. In some embodiments, the first magnetic member 212 is made of iron, cobalt, or nickel, or an alloy material including any of iron, cobalt, and nickel, and in this embodiment, the first magnetic member 212 is an iron sheet or an iron alloy sheet. Specifically, the first magnetic member 212, which is an iron sheet or an iron alloy sheet, is circular and is disposed at the center of the disc body 210; since the first magnetic member 212 is disposed on the lower surface of the disc body 210, the third magnetic member 214 is disposed on the bottom of the slot structure, and the slot structure 213 is disposed on the upper surface of the disc body 210, the plastic material of the disc body is disposed between the third magnetic member 214 and the first magnetic member 212, and the magnetic force possibly generated between the third magnetic member 214 and the first magnetic member 212 is weakened to be negligible.

In this embodiment, the first magnetic member 212, which is a circular iron or iron alloy sheet, is disposed at the axial center of the tray body 210 and exposed from the lower surface of the tray body 210, a mop cloth 211 is disposed around the first magnetic member 212, and the mop cloth 211 is of an annular structure and is held on the tray body 210 by an adhesive material or an adhesive structure, such as a barbed felt.

The berthing component 12 is disposed at the bottom of the base station 1, and includes a berthing body 121 provided with a berthing position and a second magnetic member 123 disposed on the berthing body 121 and capable of moving up and down to approach or depart from the first magnetic member 212; in this embodiment, the second magnetic member 123 is an electromagnet, and is configured to generate a magnetic force when the electromagnet is powered on to attract the first magnetic member 212, and to remove the magnetic force when the electromagnet is powered off.

In this application, the third magnetic member 214 and the magnetic attraction force between the rotating shafts 22 is smaller than the attraction force between the first magnetic member 212 and the second magnetic member 123, so that the mop plate assembly 21 originally held on the chassis 20 of the cleaning robot 2 can be detached from the chassis 20 of the cleaning robot 2. The magnetic force of the second magnetic member 123, which is an electromagnet, can be set by testing the output magnetic power thereof in advance, and it should be understood that the output power of the second magnetic member 123 can also be adjusted by controlling the base station 1 through power adjustment in practical applications.

Wherein, in a state that the cleaning robot 2 is parked at the parking position of the parking position assembly 12, the second magnetic member 123 ascends to approach or contact the first magnetic member 212 and attracts the first magnetic member 212 in a state that a magnetic force is generated, and the second magnetic member 123 detaches the mop plate assembly 21 from the chassis 20 of the cleaning robot 2 according to the attracting force when descending; or, the second magnetic member 123 lifts up the mop plate assembly 21 by lifting to be mounted on the chassis 20 of the cleaning robot 2, and lowers the second magnetic member 123 away from the first magnetic member 212 in a state that the magnetic force of the second magnetic member 123 is turned off, thereby completing the mounting of the mop plate assembly 21 on the water tank assembly 24 of the chassis 20 of the cleaning robot 2.

Referring to fig. 1 and 2, the docking assembly 12 is extendedly disposed at the bottom of the base station 1, the docking assembly 12 includes a mop cloth manipulation region 1210 corresponding to the mop cloth tray assembly 21, and the cleaning robot 2 is parked at the docking position with the mop cloth tray assembly 21 located at the mop cloth manipulation region 1210. In this embodiment the mop handle 1210 is an opposed depression in which means are provided for capturing a mop plate assembly 21 on the chassis 20 of the cleaning robot 2. In other embodiments, the mop swab handling area 1210 is further provided with a water spray mechanism (not shown) for delivering a flow of water through a waterway mechanism provided within the base station 1 to clean mops 211 located on the mop swab assembly 21 of the mop swab handling area 1210.

Referring to fig. 14, an exploded view of the docking assembly of an embodiment of the present application is shown, wherein the docking assembly further includes: a limiting groove 124, a lifting piece 125 and a driving mechanism 126.

The limit groove 124 is formed on the parking body 121, as shown in fig. 13, the limit groove 124 is integrally formed on the lower surface of the housing of the parking body 121, the limit groove 124 is used for installing the lifting member 125, and a long hole structure 1240 is formed on the side wall of the limit groove 124, so as to facilitate the passing of the linkage portion of the driving mechanism 126 for driving the lifting member 124.

The lifting piece 125 is arranged in the limiting groove 124 in a lifting motion manner, and the lifting piece 125 is used for accommodating and arranging the second magnetic piece 123; the lifting member 125 can move up and down along the limiting groove 124 relative to the housing of the parking body 121 under the action of the driving mechanism 126, so as to drive the second magnetic member 123 therein to move up and down. In this embodiment, the lifting member 125 is a cylindrical structure.

The driving mechanism 126 is connected to the lifting member 125, and is configured to drive the lifting member 125 to perform a lifting or lowering motion. The drive mechanism includes 126: a swing member 1260 and a drive motor 1261.

The swing member 1260 comprises a swing arm 1262 and a connecting rod 1263 vertically arranged at a first end of the swing arm 1262, and the connecting rod 1263 is inserted into the lifting member 125 through the long hole structure 1240 and is used for driving the lifting member 125 to do ascending or descending movement in the limiting groove 124 when the swing arm 1262 swings.

The driving motor 1261 is fixed on the berth body 121, and an output shaft thereof is vertically connected to a second end of the swing arm 1262, and is used for providing swing power for the swing arm 1262 in a working state. In this embodiment, the driving motor 1261 is fixed to the parking body 121 by a motor support 1264, and the driving motor 1261 is a speed reduction motor.

Referring to fig. 15 and 16, which are schematic views illustrating the operation of the driving mechanism of the parking lot assembly according to an embodiment of the present invention, as shown in the drawings, fig. 15 and 16 are views from the bottom of the object of the base station 1; when the driving motor 1261 receives a work command, the output shaft of the driving motor 1261 rotates to drive the swing arm 1262 to swing, the link 1263 arranged at the first end of the swing arm 1262 is also moved in the long hole structure 1240 in a linkage manner, because the link 1263 is inserted on the lifting piece 125 through the long hole structure 1240, the link 1263 swings upwards to drive the second magnetic piece 123 arranged on the lifting piece 125 to move upwards, and the link 1263 swings downwards to drive the second magnetic piece 123 arranged on the lifting piece 125 to move downwards.

In another embodiment, the lifting member may also be a sleeve (not shown) with an internal thread, and the sleeve is driven to perform a lifting or lowering motion by lifting and lowering. In this embodiment, the drive mechanism includes a rotary member, a second toothed disc, and a drive motor.

The stud comprises an external thread corresponding to the internal thread of the shaft sleeve, and the axis of the first fluted disc and the stud are coaxial; the stud is in threaded connection with the shaft sleeve and is used for driving the shaft sleeve to move up or down when rotating.

The second fluted disc is meshed with the first fluted disc and is used for driving the first fluted disc to rotate when rotating; the axis of the first gear disc is perpendicular to the axis of the second gear disc, and in the embodiment, the first gear disc and the second gear disc are designed as tapered teeth, so that the first gear disc and the second gear disc complete right-angle power transmission and rotational linkage.

The driving motor is fixed on the berth body, an output shaft of the driving motor is coaxially connected with the second fluted disc and used for driving the second fluted disc to move when the driving motor rotates, the second fluted disc is then linked with the first fluted disc to further drive the coaxial stud to rotate in the shaft sleeve, when the stud is limited to move up and down, the shaft sleeve can be driven to move up and down due to the rotation of the stud, and the second magnetic piece is arranged at the top end of the shaft sleeve to further drive the second magnetic piece to move up and down.

To further illustrate the idea and effect of the present invention, please refer to fig. 17-19, which are schematic views illustrating the working process of the mop plate loading and unloading mechanism in an embodiment of the present invention, as shown in fig. 17, the chassis 20 of the cleaning robot 2 is provided with a magnetic attraction rotating shaft 22 correspondingly combined with the mop plate assembly 21, the magnetic attraction rotating shaft 22 is inserted into the slot structure 213, and the entire mop plate assembly 21 is retained on the chassis 20 of the cleaning robot 2 due to the magnetic attraction of the magnetic attraction rotating shaft 22 and the third magnetic member 214 disposed at the bottom of the slot structure 213.

In a state where the cleaning robot 2 is parked at the parking position of the parking position assembly 12, the second magnetic member 123 is located below and corresponds to the first magnetic member 212; when the driving motor 1261 receives a lifting operation command, the output shaft of the driving motor 1261 rotates to drive the swing arm 1262 to swing, and the link 1263 arranged at the first end of the swing arm 1262 is also moved in the slot 1240 in a linkage manner, and since the link 1263 is inserted on the lifting member 125 through the slot 1240, the link 1263 swings upwards to drive the second magnetic member 123 arranged on the lifting member 125 to move upwards to enable the second magnetic member 123 to approach or contact the first magnetic member 212 on the lower surface of the mop plate assembly 21, and in the process, the second magnetic member 123 is electrified to generate magnetic force to attract the first magnetic member 212, so that the purpose of capturing the mop plate assembly 21 is achieved, as shown in fig. 18.

When the driving motor 1261 receives a descending operation command, the output shaft of the driving motor 1261 rotates reversely, and then drives the swing arm 1262 to swing reversely, so that the link 1263 arranged at the first end of the swing arm 1262 is also linked to move reversely in the long hole structure 1240, because the link 1263 is inserted into the lifting member 125 through the long hole structure 1240, the link 1263 swings downwards and drives the second magnetic member 123 arranged on the lifting member 125 to move downwards, the attraction force between the third magnetic member 214 and the magnetic attraction rotating shaft 22 is smaller than that between the first magnetic member 212 and the second magnetic member 123, so that the magnetic attraction rotating shaft 22 is separated from the slot structure 213, and the mop disc assembly 21 originally held on the chassis 20 of the cleaning robot 2 can be detached from the chassis 20 of the cleaning robot 2, that is shown in fig. 19.

In the process of installing the mop head assembly 21 on the bottom plate 20 of the cleaning robot 2, please refer to fig. 19, fig. 18 and fig. 17 in sequence, which is a reverse process, that is, when the base station 1 receives a command to install the mop head assembly 21, the mop head assembly 21 pre-placed or attached to the second magnetic member is rotated, and when the driving motor 1261 receives a lifting operation command, the output shaft of the driving motor 1261 rotates to drive the swinging arm 1262 to swing, the connecting rod 1263 provided at the first end of the swinging arm 1262 is also moved in the slot structure 1240 in a linkage manner, since the connecting rod 1263 is inserted on the lifting member 125 through the slot structure 1240, the connecting rod 1263 swings upward to drive the second magnetic member 123 installed on the lifting member 125 to move upward so that the second magnetic member 123 moves upward to make the lower surface of the mop head assembly 21 close to the magnetic attraction rotation shaft 22 on the bottom plate 20 of the cleaning robot 2 until the catching groove structure 213 is completely inserted, in the process, the second magnetic member 123 is powered off to eliminate the magnetic force and no longer attract the first magnetic member 212, and the whole mop plate assembly 21 is attracted to the chassis 20 of the cleaning robot 2 due to the magnetic attraction of the magnetic attraction rotating shaft 22 and the third magnetic member 214 arranged at the bottom of the slot structure 213; then, when the driving motor 1261 receives a descending operation command, the output shaft of the driving motor 1261 rotates reversely, and further drives the swing arm 1262 to swing reversely, so that the link 1263 provided at the first end of the swing arm 1262 is also moved reversely in the slot 1240 in an interlocking manner, since the link 1263 is inserted into the lifter 125 through the slot 1240, the link 1263 swings downward and drives the second magnetic member 123 installed on the lifter 125 to move downward, since the second magnetic member 123 has no magnetic force, that is, the second magnetic member 123 is descended away from the first magnetic member 212 in a state that the magnetic force of the second magnetic member 123 is turned off, and further the mop plate assembly 21 is installed on the chassis 20 of the cleaning robot 2.

The mop plate assembly and disassembly mechanism is characterized in that a plurality of magnetic force pieces are arranged in the mop plate assembly and disassembly mechanism, the mop plate assembly is arranged on a chassis of the cleaning robot in a magnetic attraction mode, and a lifting structure carrying an electromagnet is arranged in a parking position assembly of the base station to drive the electromagnet to be close to the magnetic attraction piece and to be magnetized, so that the whole mop plate assembly is pulled off from the chassis of the cleaning robot; otherwise, the lifting structure lifts the mop cloth disc assembly so that the magnetic attraction rotating shaft of the cleaning robot is inserted into the clamping groove structure in the mop cloth disc assembly, then the magnetic force in the lifting structure is cut off, the magnetic attraction action in the magnetic attraction rotating shaft and the clamping groove structure is used for installing the mop cloth disc assembly on the chassis of the cleaning robot, and therefore the automatic loading and unloading process of the mop cloth disc can be completed, and the manual operation is further omitted.

The present application further provides a cleaning system comprising: a mobile robot and a base station.

In the embodiment shown in fig. 12, a mop cloth disc assembly is detachably mounted on a chassis of the mobile robot, and comprises a disc body and a mop cloth arranged on the lower surface of the disc body; a first magnetic piece is arranged at the central part of the lower surface of the disc body;

in the embodiment shown in fig. 13-19, a berthing assembly is disposed at the bottom of the base station, and the berthing assembly includes a berthing body provided with a berthing position and a second magnetic member disposed on the berthing body and capable of moving up and down to approach or depart from the first magnetic member; wherein, in a state that the cleaning robot is parked at the parking place, the second magnetic member ascends to approach or contact the first magnetic member and attracts the first magnetic member in a state that a magnetic force is generated, and the second magnetic member detaches the mop plate assembly from the cleaning robot chassis according to the attracting force when descending; or the second magnetic member ascends to jack up the mop plate assembly to be mounted on the chassis of the cleaning robot, and descends away from the first magnetic member in a state that the second magnetic member turns off the magnetic force.

According to the cleaning system, the corresponding magnetic force pieces are arranged on the mop cloth disc assembly and the base station respectively, the mop cloth disc assembly is arranged on the chassis of the cleaning robot in a magnetic attraction mode, and the magnetic attraction iron sheet is arranged on the lower surface, facing the base station, of the mop cloth disc assembly, so that the lifting structure carrying the electromagnet is arranged in the parking position assembly of the base station, and the whole mop cloth disc assembly is pulled off from the chassis of the cleaning robot under the condition that the electromagnet is driven to be close to the magnetic attraction iron sheet and is electrified; otherwise, the lifting structure lifts the mop cloth disc assembly so that the magnetic attraction rotating shaft of the cleaning robot is inserted into the clamping groove structure in the mop cloth disc assembly, then the magnetic force in the lifting structure is cut off, the magnetic attraction action in the magnetic attraction rotating shaft and the clamping groove structure is used for installing the mop cloth disc assembly on the chassis of the cleaning robot, and therefore the automatic loading and unloading process of the mop cloth disc can be completed, and the manual operation is further omitted.

The present application further provides a mop swab loading and unloading mechanism for use in a cleaning system comprising a cleaning robot and a base station, such as the aforementioned dust collection base station. The mop plate loading and unloading mechanism comprises: a mop plate assembly 21 and a docking assembly 12.

Referring to fig. 12 again, as shown in the drawings, the mop plate assembly 21 is detachably mounted to the chassis 20 of the cleaning robot 2, and includes a plate body 210 and a mop 211 disposed on a lower surface of the plate body 210; a first engaging structure 215 is disposed at a central portion of the lower surface of the disc body 210.

The chassis 20 of the cleaning robot 2 is provided with a rotating shaft, the rotating shaft is driven by a driving mechanism inside the chassis of the robot, a control system of the cleaning robot controls the driving mechanism to enable the rotating shaft to rotate, and when the mop cloth disc assembly 21 is installed on the rotating shaft, the mop cloth disc assembly 21 can be driven to rotate through the rotation of the rotating shaft.

In one embodiment, the mop plate assembly 21 is detachably mounted on the chassis 20 of the cleaning robot 2 in a snap-fit manner, such as removably mounting the mop plate assembly 21 to the chassis 20 of the cleaning robot 2 by a physical configuration snap fit of an interference fit, the interference fit structure, such as a snap groove or a protrusion (not shown), specifically, for example, an annular protrusion is provided on the rotating shaft, a groove structure matched with the annular bulge is arranged in the corresponding rotary hole of the mop plate component 21, the mounting of the mop disc assembly 21 on the spindle is thus achieved, it being understood that the mounting of the mop disc assembly 21 on the spindle can be achieved without the aid of additional force, such as, in the present application, it can be placed on the spindle by simply applying a force to the mop plate assembly 21 towards the spindle; or an opposing force may be applied to remove the mop plate assembly 21 from the spindle.

In another embodiment, the mop plate assembly 21 is detachably mounted on the chassis 20 of the cleaning robot 2 in a magnetic attraction manner. In this embodiment, the magnetic attraction is a magnetic attraction of a magnet pair made of iron, cobalt, or nickel or an alloy material including any of iron, cobalt, and nickel. In this embodiment, the chassis 20 of the cleaning robot 2 is provided with a magnetic attraction rotating shaft 22 correspondingly combined with the mop plate assembly 21, and the magnetic attraction rotating shaft 22 is driven to rotate by a driving mechanism 23 arranged on the chassis 20 of the cleaning robot 2. The driving mechanism 23 is, for example, a gear assembly driven by a motor, and the gear assembly includes a plurality of gears, and the gears are engaged with each other to transmit power output by the motor to the magnetic attraction rotating shaft 22. In this embodiment, the magnetic attraction rotating shaft is made of iron, cobalt, or nickel, or an alloy material containing any one of iron, cobalt, and nickel.

The mop plate assembly further comprises a catch formation 213 and a third magnetic member 214. The slot structure 213 is formed on the upper surface of the disk body for the magnetic rotation shaft 22 to be inserted into, and the magnetic rotation shaft 22 can drive the disk body to rotate when rotating. In this embodiment, in order to facilitate the magnetic rotary shaft 22 is conveniently inserted into the clamping groove structure 213, the shaft head part of the magnetic rotary shaft 22 is designed to be of an inverted trapezoidal structure with an axial cross section, the radial cross section of the magnetic rotary shaft 22 is hexagonal, correspondingly, the clamping groove structure 213 conforms to the appearance structure of the magnetic rotary shaft 22 is also hexagonal, the longitudinal cross section of the clamping groove structure is of an inverted trapezoidal structure, the side wall of the inner space thereof is also designed to conform to the hexagonal shape of the magnetic rotary shaft 22, and further the magnetic rotary shaft 22 is driven to rotate the mop disc assembly 21.

In order to retain the entire mop plate assembly 21 on the chassis 20 of the cleaning robot 2, or the entire mop plate assembly 21 on the magnetic rotation shaft 22, when the magnetic rotation shaft 22 is inserted into the slot structure 213, the bottom of the slot structure 213 is provided with a third magnetic member 214. In this embodiment, the third magnetic member is a permanent magnet or an electromagnet, and is used for attracting the magnetic attraction rotating shaft 22 made of iron, cobalt, or nickel, or an alloy material containing any one of iron, cobalt, and nickel, so as to hold the whole mop plate assembly 21 on the chassis 20 of the cleaning robot 2.

Referring to fig. 20, which is a schematic shape diagram of the first and second engaging structures in an embodiment of the present application, as shown in the figure, a first engaging structure 215 is disposed at a central portion of the lower surface of the disc body 210. The first engaging structure 215 is circular, is disposed at the axial center of the disc body 210 and exposed out of the lower surface of the disc body 210, the circumferential side of the first engaging structure 215 is annularly provided with a mop 211, the mop 211 is of an annular structure, and is held on the disc body 210 by a sticking material or a sticking structure such as an agnail felt or magic tape.

In one embodiment, the first engaging structure 215 is formed on the rotary slot of the lower surface of the disc body 210, and includes a groove body 2150, a plurality of locking spaces 2151 formed along a sidewall of the groove body 2150 and corresponding to the plurality of latches, and a releasing space 2152 located outside the plurality of locking spaces. In this embodiment, the locking space 2151 is defined by a one-way groove 2153 formed in the groove body 2150 and the bottom and side surfaces of the groove body 2150, and the one-way groove 2153 includes a first blocking piece 2154 horizontally disposed at the edge of the opening of the groove body and parallel to the bottom surface of the groove body, and a second blocking piece 2155 connecting the first blocking piece 2154 and the bottom surface of the groove body 2150.

The berth component 12 is disposed at the bottom of the base station 1, and includes a berth body 121 provided with a berth, and a second engaging structure 127 disposed on the berth body 121 and capable of rotating and lifting for capturing the first engaging structure 215; wherein, in the state that the cleaning robot 2 is parked at the parking position, the second engaging structure 127 is lifted and engages with the first engaging mechanism 215 in the state that the tray body 210 rotates in the first direction, and the second engaging structure 127 drives the mop tray assembly 21 to be detached from the chassis 20 of the cleaning robot 2 when being lowered; or the second engaging structure 127 is installed on the chassis 20 of the cleaning robot 2 by being lifted up to jack up the mop plate assembly 21, releases the engagement with the first engaging structure 215 in a state where the plate body 210 is rotated in the second direction, and is separated from the first engaging structure 215 when being lowered.

Referring to fig. 21, an exploded view of a cleaning robot and a base station docking assembly according to another embodiment of the present disclosure is shown, wherein the docking assembly further includes: a mounting slot 128, a lifting mechanism 129, and a drive mechanism 126.

The mounting groove 128 is formed on the berth body 121; as shown in fig. 21, the mounting groove 128 is integrally formed on the lower surface of the housing of the parking space body 121, and the side wall of the mounting groove 128 is provided with a long buckle 1280 for limiting the rotation of the lifting mechanism 129, so that the lifting mechanism 129 is forced to only perform lifting movement in the mounting groove 128 without performing rotation movement.

The lifting mechanism 129 is disposed in the mounting groove 128 in a lifting manner, and the second engaging structure 127 is sleeved on the top end of the lifting mechanism 129 and passively rotates relative to the axis of the lifting mechanism 129 when receiving a rotational force; in this embodiment, the second engaging structure 127 is a buckle having a plurality of latches 1270, specifically, the latches 1270 are uniformly distributed in 3 numbers, that is, each two adjacent latches 1270 form an included angle of 120 °.

The second engaging structure 127 is sleeved on the top end of the lifting mechanism 129 and passively rotates relative to the axis of the lifting mechanism 129 when receiving a rotational force, which means that the second engaging structure 127 can rotate relative to the lifting mechanism 129 when receiving an external force, but the lifting mechanism 129 cannot rotate along with the rotation because the lifting mechanism 129 is limited by the long buckle 1280 in the mounting groove 128. It should be understood that the sleeve is a rotatable movable arrangement, but the second engaging structure 127 and the lifting mechanism 129 cannot be separated due to the vertical engaging relationship when a vertical force is applied, in other words, the second engaging structure 127 can rotate on the lifting mechanism 129 but cannot be removed.

In this embodiment, the lifting mechanism 129 includes a lifting rod 1290, a first gear 1291, and a second gear 1294.

As mentioned above, the lifting rod 129 is non-rotatably limited in the mounting groove 128, and the specific implementation manner is that a long buckle 1280 is disposed on a side wall of the mounting groove 128, a fixture block 1295 correspondingly clamped in the long buckle 1280 is disposed on the peripheral side of the lifting rod 129, and due to the mutual fit relationship between the long buckle 1280 and the fixture block 1295, the lifting rod 129 is non-rotatably limited in the mounting groove 128.

In this embodiment, the lifting rod 129 is a bushing structure, and the inner wall of the bushing structure has an internal thread.

The first gear 1291 comprises a stud 1292 and a first fluted disc 1293, wherein the stud 1292 has an external thread corresponding to the internal thread of the lifting rod 129, so that the stud 1292 can be screwed into the lifting rod 129 which is in a bushing structure, and the bottom end of the stud 1292 is integrally formed with the first fluted disc 1293 which is coaxial with the stud; the stud 1292 is in threaded connection with the lifting rod 129 in a shaft sleeve structure and is used for driving the lifting rod 129 to move up or down in the mounting groove 128 when rotating.

The second gear disc 1294 is meshed with the first gear disc 1291 and is used for driving the first gear disc 1291 to rotate when rotating; the axis of the first gear 1291 is perpendicular to the axis of the second gear 1294, and in the embodiment, the first gear 1294 and the second gear 1294 are designed as tapered teeth, so that the first gear 1291 and the second gear 1294 perform a power transmission and a rotational linkage in a perpendicular relationship.

The driving mechanism 126 is connected to the lifting mechanism 129 and is used for driving the lifting mechanism 129 to perform ascending or descending movement. In this embodiment, the driving motor 126 is fixed on the parking space body 121, an output shaft of the driving mechanism 126, which is a driving motor, is coaxially connected to the second gear disc 1294, and is configured to drive the second gear disc 1294 to move when the driving motor rotates, the second gear disc 1294 is further linked with the first gear disc 1291, so as to drive the coaxial stud 1292 to rotate in the lifting rod 129, which is a shaft sleeve structure, and when the stud 1292 is limited to move up and down and the lifting rod 129, which is a shaft sleeve structure, is limited to rotate, the lifting rod 129 can be driven to move up and down in the mounting groove 128 due to the rotation of the stud 1292, and the second engaging structure 127 is disposed at the top end of the lifting rod 129, so as to move up and down therewith.

In the state that the cleaning robot 2 is parked at the parking position, the second engaging structure 127 is lifted and is engaged with the first engaging mechanism 215 in the state that the tray body 210 is rotated in the first direction, and the second engaging structure 127 drives the mop tray assembly 21 to be detached from the chassis 20 of the cleaning robot 2 when being lowered; or the second engaging structure 127 is lifted up to jack up the mop disc assembly 21 to be mounted on the chassis 20 of the cleaning robot 2, releases the engagement with the first engaging structure 215 in a state that the disc body 210 rotates in the second direction, and is separated from the first engaging structure 215 when descending, thereby realizing the process of detaching and mounting the mop disc assembly 21.

To further illustrate the idea and function of the present invention, please refer to fig. 22 to 24, which are schematic views illustrating the working process of the mop plate loading and unloading mechanism in another embodiment of the present invention, as shown in fig. 22, the chassis 20 of the cleaning robot 2 is provided with a magnetic attraction rotating shaft 22 correspondingly combined with the mop plate assembly 21, the magnetic attraction rotating shaft 22 is inserted into the slot structure 213, and the entire mop plate assembly 21 is retained on the chassis 20 of the cleaning robot 2 due to the magnetic attraction of the magnetic attraction rotating shaft 22 and the third magnetic member 214 disposed at the bottom of the slot structure 213.

When the cleaning robot 2 is parked at the parking position of the parking lot assembly 12, the second engaging structure 127 is located below the first engaging structure 215, and at this time, the cleaning robot 2 controls the mop plate assembly 21 to rotate at a certain speed and in a first direction, and when the base station 1 receives a command to detach the mop plate assembly 21, the base station controls the driving mechanism 126 to output power to drive the second gear 1294 coaxially connected to the output shaft thereof to rotate, because the second gear 1294 is engaged with the first gear 1291, the first gear 1291 also rotates and links the stud 1292 to rotate, and further drives the coaxial stud 1292 to rotate within the lifting rod 129 in the bushing structure, and when the stud 1292 is limited to move up and down and the lifting rod 129 in the bushing structure is limited to rotate, the lifting rod 129 can be driven to move up and down in the mounting groove 128 due to the rotation thereof, the second engaging structure 127 is disposed at the top end of the lifting rod 129 and then moves upward; when the second engaging structure 127 approaches the first engaging mechanism 215, because the mop disc assembly 21 keeps rotating at a certain speed and in a first direction, the second engaging structure 127 is also driven to rotate and keep rotating at a certain speed and in a first direction, in this embodiment, the first direction is, for example, a clockwise direction, and because the rotation of the second engaging structure 127 is passive, the latch 1270 thereof enters the latch space 2151 of the first engaging structure 215 along with the rotation of the second engaging structure 127, so that the first engaging structure 215 and the second engaging structure 127 are engaged, and the purpose of capturing the mop disc assembly 21 of the cleaning robot 2 is achieved, as shown in fig. 23.

Then, the base station 1 controls the driving mechanism 126 thereof to output reverse power to drive the second gear disc 1294 coaxially connected with the output shaft thereof to rotate reversely, since the second gear disc 1294 is engaged with the first gear disc 1291, the first gear disc 1291 also rotates reversely and is linked with the stud 1292 to rotate reversely, so as to drive the coaxial stud 1292 to rotate reversely in the lifting rod 129 in the shaft sleeve structure, when the stud 1292 is restricted from moving up and down and the lifting rod 129 in the shaft sleeve structure is restricted from rotating reversely, the lifting rod 129 can be driven to move down in the mounting groove 128 due to the reverse rotation thereof, and at this time, since the second engaging structure 127 has engaged the first engaging structure 215, the second engaging structure 127 drives the disc assembly 21 to detach it from the chassis 20 of the cleaning robot 2 when moving down, so that the magnetic attraction rotation shaft 22 is disengaged from the engaging structure 213, it is further possible to detach the mop plate assembly 21, which is originally held on the chassis 20 of the cleaning robot 2, from the chassis 20 of the cleaning robot 2, that is, to take a state as shown in fig. 24.

In the process of installing the mop plate assembly 21 on the chassis 20 of the cleaning robot 2, please refer to fig. 24, 23 and 22 in turn, which is a reverse process, that is, when the base station 1 receives a command for installing the mop plate assembly 21, it controls the driving mechanism 126 to output power to drive the second toothed disc 1294 coaxially connected to the output shaft thereof to rotate, since the second toothed disc 1294 is engaged with the first toothed disc 1291, the first toothed disc 1291 also rotates and links the stud 1292 to rotate, thereby driving the coaxial stud 1292 to rotate in the lift rod 129 in a bushing structure, when the stud 1292 is restricted from moving up and down, and when the lift rod 129 in a bushing structure is restricted from rotating, the lift rod 129 can be driven to move up and down in the installation slot 128 due to the rotation thereof, and since the second engaging structure 127 is disposed at the top end of the lift rod 129, thereby moving up and down, further lifting the lower surface of the mop plate assembly 21 to enable the clamping groove structure 213 to be close to the magnetic rotation shaft 22 on the chassis 20 of the cleaning robot 2 until the clamping groove structure is completely inserted, and due to the magnetic attraction effect of the magnetic rotation shaft 22 and the third magnetic member 214 arranged at the bottom of the clamping groove structure 213, the whole mop plate assembly 21 is arranged on the chassis 20 of the cleaning robot 2; then, the magnetic attraction rotation shaft 22 on the chassis 20 of the cleaning robot 2 outputs a certain speed and rotates in a second direction (for example, counterclockwise rotation), and since the rotation of the second engaging structure 127 is also passive in this process, the latch 1270 thereof moves from the locking space 2151 of the first engaging structure 215 to the releasing space 2152 thereof along with the rotation of the second engaging structure 127, thereby releasing the first engaging structure 215 and the second engaging structure 127, and further achieving the purpose of releasing the mop plate assembly 21 of the cleaning robot 2.

Then, the base station 1 controls the driving mechanism 126 to output reverse power to drive the second gear disc 1294 coaxially connected with the output shaft thereof to rotate reversely, since second toothed disc 1294 is in meshing engagement with first toothed disc 1291, first toothed disc 1291 also rotates in the opposite direction and link stud 1292 rotates in the opposite direction, thereby driving the coaxial stud 1292 to reversely rotate in the lifting rod 129 with a shaft sleeve structure, when the stud 1292 is limited from moving up and down and the lifting rod 129 in a shaft sleeve structure is limited from rotating reversely, the lifting rod 129 is driven to move downwards in the mounting groove 128 due to the reverse rotation, at this time, since the second engaging structure 127 is already disengaged from the first engaging structure 215, the second engaging structure 127 is far away from the first engaging structure 215 when descending, thereby completing the mop plate assembly 21 to be mounted on the chassis 20 of the cleaning robot 2.

The mop plate assembly and disassembly mechanism is provided with a first clamping structure and a second clamping structure, the mop plate assembly is arranged on a chassis of the cleaning robot in a magnetic attraction mode, and because the first clamping structure is arranged on the lower surface, facing a base station, of the mop plate assembly, a lifting structure carrying the second clamping structure is arranged in a berth assembly of the base station to drive the second clamping structure to clamp the first clamping structure, and the second clamping structure is lowered to pull the whole mop plate assembly off the chassis of the cleaning robot; otherwise, elevation structure will mop dish subassembly jacking so that cleaning machines people's magnetism inhale the pivot insert the draw-in groove structure in the mop dish subassembly, then through the block of releasing first, second block structure, will through the magnetism effect of inhaling in pivot and the draw-in groove structure the mop dish subassembly is installed on cleaning machines people's chassis, so, then can accomplish the auto-control handling process of mop dish, and then save the operation of manpower.

The present application further provides a cleaning system comprising: a mobile robot and a base station.

In the embodiment shown in fig. 12 and 20, a mop cloth disc assembly is detachably mounted on a chassis of the mobile robot, and comprises a disc body and a mop cloth arranged on the lower surface of the disc body; the central part of the lower surface of the disc body is provided with a first clamping structure.

In the embodiment shown in fig. 20 to 24, a berth assembly is disposed at the bottom of the base station, and the berth assembly includes a berth body provided with a berth and a second engaging structure disposed on the berth body and capable of rotating and lifting to capture the first engaging structure. When the cleaning robot stops at the parking position, the second clamping structure ascends and clamps the first clamping mechanism in a state that the disc body rotates in the first direction, and when the second clamping structure descends, the second clamping structure drives the mop disc assembly to be dismounted from the cleaning robot chassis; or the second clamping structure lifts up the mop plate component by rising so as to be arranged on the chassis of the cleaning robot, releases the clamping with the first clamping structure under the state that the plate body rotates in the second direction, and is far away from the first clamping structure when descending.

According to the cleaning system, the first clamping structure is arranged on the mop plate assembly of the cleaning robot, the second clamping structure is arranged on the base station, the mop plate assembly is arranged on the chassis of the cleaning robot in a magnetic attraction mode, and the lifting structure carrying the second clamping structure is arranged in the berth assembly of the base station to drive the second clamping structure to clamp the first clamping structure and pull the whole mop plate assembly off the chassis of the cleaning robot by descending the second clamping structure as the first clamping structure is arranged on the lower surface of the mop plate assembly facing the base station; otherwise, elevation structure will mop dish subassembly jacking so that cleaning machines people's magnetism inhale the pivot insert the draw-in groove structure in the mop dish subassembly, then through the block of releasing first, second block structure, will through the magnetism effect of inhaling in pivot and the draw-in groove structure the mop dish subassembly is installed on cleaning machines people's chassis, so, then can accomplish the auto-control handling process of mop dish, and then save the operation of manpower.

The above embodiments are merely illustrative of the principles and utilities of the present application and are not intended to limit the application. Any person skilled in the art can modify or change the above-described embodiments without departing from the spirit and scope of the present application. Accordingly, it is intended that all equivalent modifications or changes which can be made by those skilled in the art without departing from the spirit and technical concepts disclosed in the present application shall be covered by the claims of the present application.

Claims (15)

1. A dust collection base station for recycling garbage in a dust box of a cleaning robot, comprising:

the base station body is provided with a dust collecting cavity and negative pressure equipment communicated with the dust collecting cavity, the bottom end part of the base station body is provided with a garbage suction inlet butted with a dust suction port of the cleaning robot, and the garbage suction inlet is communicated with the dust collecting cavity through a conveying channel;

the dust collecting barrel is detachably arranged in the dust collecting cavity and comprises a barrel body with a cover body, a garbage inlet formed on the barrel body, a negative pressure suction port communicated with the negative pressure equipment, a dust collecting chamber formed in the barrel body and a cyclone assembly arranged in the barrel body; the cyclone component is provided with a transverse cyclone separating mechanism communicated with the garbage inlet and a longitudinal cyclone separating mechanism communicated with the negative pressure suction port, and the longitudinal cyclone separating mechanism is provided with an inner chamber independent of the dust collecting chamber.

2. The dust collecting base station of claim 1, further comprising a docking assembly extendedly disposed at the bottom of the base station body, wherein the dust suction inlet is disposed on the docking assembly for docking with a dust suction port of the cleaning robot when the cleaning robot is docked.

3. The dust collection base station of claim 1, further comprising a charging assembly disposed at a bottom of the base station body for electrically connecting the cleaning robot charging circuit when the cleaning robot is parked.

4. The dust collecting base station as claimed in claim 1, wherein the base station body further comprises a top cover movably disposed to cover the dust collecting chamber.

5. The dust collection base station of claim 1, further comprising a dust bag removably disposed in the dust collection chamber, the dust bag having a dust inlet of the same size as the dust collection bucket.

6. The dust collection base station as claimed in claim 1, wherein the dust inlet and the negative suction port of the dust collection tub are located on the same side wall of the dust collection tub.

7. The dust collecting base station as claimed in claim 1, wherein the lid of the dust collecting bucket is engaged with the bottom of the bucket body, and is released from engagement with the bottom of the bucket body by pressing a button structure to release the garbage in the dust collecting chamber.

8. The dust collecting base station as claimed in claim 1, wherein a handle is provided at a top of the dust collecting bucket to facilitate the dust collecting bucket to be placed in or taken out of the dust collecting chamber.

9. The dust collection base station of claim 1, wherein the lateral cyclonic separation mechanism comprises:

a cyclone plate is arranged in the front end barrel of the transverse cyclone barrel, and a separation opening facing the dust collecting chamber is formed in the barrel wall;

the transverse filter cylinder is coaxially arranged in the cylinder body at the rear end of the transverse cyclone cylinder and comprises a closed front end, an open rear end and a filter screen surrounding the space between the closed front end and the open rear end.

10. The dust collection base station of claim 9, wherein the longitudinal cyclonic separation mechanism comprises:

the longitudinal inner barrel comprises an upper barrel body and a lower barrel body which is isolated from the upper barrel body in space, and an opening which is connected with the rear end of the opening of the transverse filter barrel is formed in one side wall of the upper barrel body; the bottom end opening of the lower barrel body contacts the bottom of the dust collecting barrel to form an inner chamber independent of the dust collecting chamber;

the vertical cyclone assembly is longitudinally arranged in the upper barrel body and comprises a plurality of internal cyclone pipes which are distributed in an arrangement mode and are independent in space, and openings at the bottom ends of the internal cyclone pipes extend to be communicated with the inner space of the lower barrel body; the top end opening of each internal cyclone pipe is communicated with the negative pressure suction port.

11. The dust collecting base station as claimed in claim 10, wherein the dust collecting barrel further comprises a middle cover for spatially isolating the dust collecting chamber, and a clean air passage for communicating the top end opening of each internal cyclone tube with the negative pressure suction port is formed between the middle cover and the top surface of the dust collecting barrel.

12. The dust collecting base station of claim 11, wherein the upper end of each of the inner cyclone pipes is opened with a dust inlet facing the horizontal cyclone separating mechanism, and the dust inlet is spatially separated from the clean air passage by the middle cover.

13. The dust collection base station of claim 10, wherein said inner cyclone tube has a space reducing structure from top to bottom.

14. The dust collecting base station as claimed in claim 10, wherein the lower body of the longitudinal inner barrel is of a space reducing structure from top to bottom.

15. A cleaning system comprising a cleaning robot and a dust collection base as claimed in any one of claims 1 to 14 for recovering debris from within a dust box of the cleaning robot.

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