CN220860009U - Cleaning robot apparatus - Google Patents

Abstract

The application discloses cleaning robot equipment, and relates to the technical field of cleaning equipment. The cleaning robot device comprises a cleaning base station and a cleaning robot, wherein the cleaning base station comprises a first fan, the cleaning robot comprises a robot main body and a dust collecting box, the dust collecting box is arranged in the robot main body and is provided with a dust collecting opening, a fan opening and an air inlet, the fan opening and the air inlet are arranged side by side, the air inlet is positioned at one side of the fan opening, which is away from the dust collecting opening, under the condition that the cleaning base station is in a dust collecting state, the first fan can be communicated with a containing cavity of the dust collecting box through the dust collecting opening, and the air inlet can be ventilated into the containing cavity. The scheme can solve the problem that the dust collection efficiency of the current clean base station is lower.

Description

Cleaning robot apparatus

Technical Field

The application belongs to the technical field of cleaning equipment, and particularly relates to cleaning robot equipment.

Background

Along with development of science and technology and acceleration of life rhythm, the cleaning robot is utilized to clean the environment, so that the cleaning efficiency can be improved, and the purpose of freeing hands can be realized. Generally, a dust box is arranged in a main body of the cleaning robot and is used for collecting garbage cleaned by the cleaning device, and when more garbage is contained in the dust box, the cleaning robot needs to return to a cleaning base station to perform dust collection treatment so that the garbage in the dust box is transferred to the cleaning base station.

At present, the cleaning robot can only intake air from the dust collecting port and the fan port in the dust collecting process, and in practical application, as the fan in the cleaning robot is usually arranged at the rear of the dust collecting box, the fan port is correspondingly arranged at the rear of the dust collecting box, and the dust collecting port is usually arranged at the side part of the dust collecting box. In this case, during the dust collection of the cleaning robot, there is inevitably a region where the air flow passes less, even not, in the dust collection box, resulting in that the dust in the region remains in the dust collection box, thereby making the dust collection efficiency of the cleaning base station lower.

Disclosure of utility model

The embodiment of the application aims to provide cleaning robot equipment which can solve the problem that the dust collection efficiency of a conventional cleaning base station is low.

In order to solve the technical problems, the application is realized as follows:

The embodiment of the application provides cleaning robot equipment, which comprises a cleaning base station and a cleaning robot, wherein the cleaning base station comprises a first fan, the cleaning robot comprises a robot main body and a dust collecting box, the dust collecting box is arranged in the robot main body and is provided with a dust collecting port, a fan port and an air inlet, the fan port and the air inlet are arranged side by side, the air inlet is positioned at one side of the fan port away from the dust collecting port,

Under the condition that the cleaning base station is in a dust collection state, the first fan can be communicated with the accommodating cavity of the dust collection box through the dust collection port, and the air inlet can ventilate into the accommodating cavity.

In the embodiment of the application, the dust collecting box is provided with the dust collecting port, the fan port and the air inlet are arranged side by side, the air inlet is positioned on one side of the fan port away from the dust collecting port, and the first fan can be communicated with the accommodating cavity of the dust collecting box through the dust collecting port under the condition that the cleaning base station is in a dust collecting state, and the air inlet can ventilate into the accommodating cavity. According to the scheme, the air inlet is additionally formed in the position far away from the dust collecting opening, so that the coverage area of air flow in the dust collecting box is increased, garbage in the edge corners of the accommodating cavity can be collected into the cleaning base station, and the dust collecting efficiency of the cleaning base station is improved.

Drawings

Fig. 1 and fig. 2 are schematic structural views of a dust box according to an embodiment of the present application at different viewing angles;

FIG. 3 is an exploded view of a dust box according to an embodiment of the present application;

FIG. 4 is a schematic view showing the structure of a cartridge body according to an embodiment of the present application;

FIG. 5 is a schematic view of a flip cover according to an embodiment of the present application;

fig. 6 is a cross-sectional view of a dust box according to an embodiment of the present application;

FIG. 7 is a cross-sectional view of a flip cover as disclosed in an embodiment of the present application;

FIG. 8 is a side view of an air intake baffle according to an embodiment of the present disclosure;

Fig. 9 and 10 are top views of a cleaning base station according to an embodiment of the present application in different operation modes;

wherein the arrowed lines in fig. 9 and 10 are the gas flow direction.

Reference numerals illustrate:

100-dust collecting box, 110-dust collecting port, 120-fan port, 130-air inlet, 140-accommodating cavity, 141-limit boss, 142-mounting groove, 142 a-avoiding opening, 143-fixing part, 143 a-first fixing part, 143 b-second fixing part, 144-first arc side wall, 145-second arc side wall, 150-box main body, 160-flip cover, 170-dust inlet and 180-handle;

200-air inlet baffles, 210-easy-to-fold openings, 220-shielding parts, 230-hanging parts, 231-first hanging parts and 232-second hanging parts;

300-pressing plate and 310-clamping part;

400-a dust inlet baffle;

500-a filter;

600-dust collecting opening baffle.

Detailed Description

The following description of the embodiments of the present application will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that some, but not all embodiments of the application are described. All other embodiments, which can be made by those skilled in the art based on the embodiments of the application without making any inventive effort, are intended to be within the scope of the application.

The terms first, second and the like in the description and in the claims, are used for distinguishing between similar elements and not necessarily for describing a particular sequential or chronological order. It is to be understood that the data so used may be interchanged where appropriate such that embodiments of the application may be practiced otherwise than as specifically illustrated or described herein. Furthermore, in the description and claims, "and/or" means at least one of the connected objects, and the character "/", generally means that the associated object is an "or" relationship.

The cleaning robot device provided by the embodiment of the application is described in detail below through specific embodiments and application scenes thereof with reference to the accompanying drawings.

Referring to fig. 1 to 10, an embodiment of the present application discloses a cleaning robot apparatus including a cleaning base station provided with an accommodation space communicating with the outside, and a cleaning robot which can enter the accommodation space of the cleaning base station to perform dust collection, washing, drying, and the like. The cleaning base station includes a first fan, optionally, the first fan may be an exhaust fan, the cleaning robot includes a robot main body and a dust collecting box 100, the dust collecting box 100 is disposed in the robot main body, the dust collecting box 100 is provided with a dust collecting opening 110, a fan opening 120 and an air inlet 130, the fan opening 120 and the air inlet 130 are disposed side by side, and the air inlet 130 is located at one side of the fan opening 120 deviating from the dust collecting opening 110, optionally, the dust collecting opening 110, the fan opening 120 and the air inlet 130 are all disposed on the side wall of the dust collecting box 100, the dust collecting opening 110 may be disposed side by side with the fan opening 120, or may be disposed on the side wall of the dust collecting box 100, i.e. the dust collecting opening 110 and the fan opening 120 are located on different sides of the dust collecting box 100, or the dust collecting opening 110 may also be disposed at a corner of the dust collecting box 100, i.e. at a junction of adjacent sides, and the arrangement mode of the dust collecting opening 110 is not particularly limited herein. In the case that the cleaning base station is in a dust collecting state, the first fan may be connected with the accommodating chamber 140 of the dust collecting box 100 through the dust collecting port 110, and the air inlet 130 may ventilate into the accommodating chamber 140. It should be noted that, the bottom of the cleaning robot may be provided with an opening to allow the air inlet 130 to communicate with the outside, that is, the air inlet 130 is introduced into the accommodating chamber 140 from the opening, and the assembly gap between other structures of the cleaning robot.

In the embodiment of the application, the fan port 120 and the air inlet 130 are arranged side by side, and the air inlet 130 is positioned at one side of the fan port 120 away from the dust collecting port 110, i.e. the air inlet 130 is additionally arranged at a position far away from the dust collecting port 110, so that the coverage area of the air flow in the dust collecting box 100 is increased, and the garbage in the edge corner of the accommodating cavity 140 can be collected in the cleaning base station, thereby improving the dust collecting efficiency of the cleaning base station.

In an alternative embodiment, the cleaning robot further includes an air inlet baffle 200, where the air inlet baffle 200 is disposed in the accommodating cavity 140, and a first end of the air inlet baffle 200 is detachably connected with the dust box 100, and optionally, the first end of the air inlet baffle 200 and the dust box 100 may be connected by adopting interference fit, dispensing, torsion springs, screws, and the like. The second end of the air intake damper 200 may be rotatable relative to the air intake 130 to be either closer to or farther from the air intake 130 to close or open the air intake 130. When the cleaning base station is in a dust collection state, the first fan can extract the gas in the accommodating cavity 140, and at the moment, the second end of the air inlet baffle 200 is far away from the air inlet 130, so that the air inlet 130 is opened, and at the moment, the air inlet 130 ventilates into the accommodating cavity 140; under the condition that no gas flows in the accommodating cavity 140, the air inlet baffle 200 approaches the air inlet 130 under the action of self gravity, so that the air inlet 130 is closed, and the garbage leakage in the accommodating cavity 140 is avoided.

The rotation axis of the air intake damper 200 extends in the horizontal direction.

Alternatively, the air intake baffle 200 may be a rigid structure, where the first end of the air intake baffle 200 is rotatably connected to the dust box 100; or in other embodiments the intake baffle 200 is a flexible structure, alternatively, the flexible structure may be rubber, plastic, or the like. The side of the air inlet baffle 200 away from the air inlet 130 is provided with a flexible opening 210, the flexible opening 210 is positioned at the first end of the air inlet baffle 200, at this time, the second end of the air inlet baffle 200 can rotate around the flexible opening 210, and the thickness of the flexible opening 210 is smaller and is easy to bend, so that the second end of the air inlet baffle 200 can flexibly rotate; in addition, the first end of the air inlet baffle 200 with such a structure may be detachably connected to the dust box 100 by means of a clamping connection, so as to facilitate the disassembly and assembly of the air inlet baffle 200. Of course, the air inlet baffle 200 may not be provided with the frangible opening 210, and at this time, the rotation flexibility of the second end of the air inlet baffle 200 is not as good as that of the scheme that the frangible opening 210 is provided on the side of the air inlet baffle 200 facing away from the air inlet 130, and the rotation angle of the second end of the air inlet baffle 200 will be smaller when the frangible opening 210 is not provided.

Alternatively, the frangible opening 210 may include a first side wall and a second side wall that are connected to each other, where an included angle is formed between the first side wall and the second side wall, and the second side wall may be close to or far away from the first side wall during the rotation of the second end of the air intake baffle 200, so that the angle of the included angle is changed.

In a further alternative embodiment, the air inlet baffle 200 includes a shielding portion 220, the shielding portion 220 is provided with a pliable opening 210, and the shielding portion 220 is disposed obliquely along the air inlet direction of the air inlet 130, that is, in the case that no air flows at the air inlet 130, the distance between the second end of the shielding portion 220 and the air inlet 130 is greater than the distance between the first end of the shielding portion 220 and the air inlet 130. When a certain amount of air intake exists at the air inlet 130, the second end of the inclined shielding portion 220 is easier to rotate, so as to be away from the air inlet 130. Of course, the shielding portion 220 may be vertically disposed in the case that no gas flows at the air inlet 130. Optionally, the inclination angle of the shielding portion 220 may be 10-60 °, so that the shielding portion is prevented from occupying a larger space due to an excessively large inclination angle, and is easy to be blocked into the air inlet 130 due to an excessively small inclination angle; further alternatively, the inclination angle of the shielding portion 220 may be 15 °, which may be selected according to actual needs, but is not particularly limited thereto.

Alternatively, the air intake 130 may be near the top of the receiving chamber 140; or the air inlet 130 is disposed near the bottom of the accommodating chamber 140 so that the air introduced from the air inlet 130 can more fully cover the bottom of the accommodating chamber 140, thereby improving dust collection efficiency. Optionally, the side wall of the accommodating cavity is provided with a limiting boss 141, the limiting boss 141 is arranged around the air inlet 130, the limiting boss 141 extends to the bottom of the accommodating cavity 140, and the shielding part 220 and the limiting boss 141 can be in limiting fit. When the shielding part 220 rotates to be close to the air inlet 130, the shielding part 220 is in limit fit with the limit boss 141 so as to prevent the shielding part 220 from continuing to rotate and prevent the shielding part 220 from being blocked in the air inlet 130; in addition, under the condition that no gas flows at the air inlet 130, the shielding part 220 is attached to the limiting boss 141, so that the leakage of garbage in the dust box 100 is avoided, and especially when a user installs and removes the dust box 100, the shielding part 220 needs to seal the air inlet 130. Of course, the limit boss 141 may be disposed only at the bottom of the receiving chamber 140.

In another alternative embodiment, the cleaning robot further includes a pressing plate 300, where the pressing plate 300 is detachably disposed on a side wall of the accommodating cavity 140, and the pressing plate 300 is located above the frangible opening 210, that is, the pressing plate 300 is away from the frangible opening 210 on the air inlet baffle 200, so as to ensure that the second end of the air inlet baffle 200 can flexibly rotate, in the air inlet direction of the air inlet 130, the pressing plate 300 presses the edge of the air inlet baffle 200, that is, in the air inlet direction of the air inlet 130, the edge of the pressing plate 300 overlaps the edge of the air inlet baffle 200, so that the pressing plate 300 is in limit fit with the air inlet baffle 200, so as to fix the first end of the air inlet baffle 200, thereby improving the stability in the rotation process of the second end of the air inlet baffle 200. Of course, the first end of the air intake damper 200 and the sidewall of the receiving chamber 140 may be connected by fasteners.

In a further alternative embodiment, the air intake baffle 200 includes a shielding portion 220, and the pressing plate 300 presses the edge of the shielding portion 220 in the air intake direction of the air intake 130, that is, the first end of the shielding portion 220 may be clamped between the sidewall of the accommodating cavity 140 and the pressing plate 300, but the shielding portion 220 is easy to fall with increasing rotation times of the second end of the shielding portion 220. Based on this, optionally, the sidewall of the accommodating cavity 140 is provided with the mounting groove 142, the air intake baffle 200 further includes a hanging portion 230, the hanging portion 230 is connected to the shielding portion 220, the hanging portion 230 is located on one surface of the shielding portion 220 facing the air intake 130, and the hanging portion 230 is hung on the mounting groove 142, so as to prevent the air intake baffle 200 from falling down, so as to improve the stability of the air intake baffle 200.

In a further alternative embodiment, the side wall of the accommodating cavity 140 further has a fixing portion 143, the fixing portion 143 is located above the air inlet baffle 200, the first end of the pressing plate 300 is pressed against the edge of the shielding portion 220, and the second end of the pressing plate 300 is fixedly matched with the fixing portion 143, because the air inlet baffle 200 is of a flexible structure, the air inlet baffle 200 can be deformed, when the rotation amplitude of the second end of the shielding portion 220 is larger, the first end of the shielding portion 220 is easy to shake, and at this time, the stability of the whole air inlet baffle 200 is not good. In view of this, optionally, the side wall of the mounting groove 142 is provided with an avoidance opening 142a, the avoidance opening 142a extends to the air inlet 130, one surface of the pressing plate 300 facing the mounting groove 142 is provided with a clamping portion 310, and the clamping portion 310 is clamped in the avoidance opening 142a, that is, the clamping portion 310 extends into the mounting groove 142 and is clamped in the avoidance opening 142a, so that the pressing force of the pressing plate 300 acting on the shielding portion 220 is increased, the stability of the shielding portion 220 is improved, the clamping portion 310 and the hanging portion 230 are arranged side by side, that is, a part of the clamping portion 310 is located in the mounting groove 142, and the space utilization of the accommodating groove 142 is improved.

Alternatively, the thickness of the first end of the pressing plate 300 may be greater than the thickness of the second end of the pressing plate 300, thereby improving the stability of the pressing plate 300 against the edge of the shielding part 220.

Alternatively, the number of the hitches 230 may be one; or the number of the hanging parts 230 may be at least two, including the first hanging parts 231 and the second hanging parts 232 which are arranged at intervals, and the clamping part 310 may be located between the first hanging parts 231 and the second hanging parts 232, so that the pressing force of the pressing plate 300 pressing the shielding part 220 is located in the middle of the shielding part 220, thereby further improving the stability of the air inlet baffle 200.

Optionally, the fixing portion 143 includes a connecting section and a limiting section, where one end of the connecting section is connected to the side wall of the accommodating cavity 140, the other end of the connecting section is connected to the limiting section, the limiting section is bent relative to the connecting section, the limiting section is opposite to the side wall of the accommodating cavity 140, that is, the limiting section, the connecting section and the side wall of the accommodating cavity 140 form a clamping groove, and the second end of the pressing plate 300 is clamped in the clamping groove, so that the second end of the pressing plate 300 is fixed.

Further alternatively, the number of the fixing portions 143 may be one; or the number of the fixing parts 143 is at least two, including the first fixing parts 143a and the second fixing parts 143b which are disposed at intervals, at this time, two corners of the second end of the pressing plate 300 may be fixed to the first fixing parts 143a and the second fixing parts 143b, respectively, and the manufacturing material of the fixing parts 143 may be reduced on the basis of ensuring the stability of the pressing plate 300.

In yet another alternative embodiment, the dust box 100 includes a box main body 150 and a flip cover 160 which are detachably connected, the flip cover 160 and the box main body 150 enclose a containing cavity 140, optionally, one end of the flip cover 160 is rotatably connected with the box main body 150, and the other end of the flip cover 160 is clamped with the box main body 150, when a user manually cleans the dust in the dust box 100, the flip cover 160 can be opened at this time to dump the dust and clean the inner wall of the dust box 100. When the cover 160 is opened, the rotation axis may extend in the vertical direction. The box main body 150 is provided with the dust collecting port 110, the flip cover 160 is provided with the fan port 120 and the air inlet 130, the first end of the air inlet baffle 200 is detachably connected with the flip cover 160, the pressing plate 300 is detachably arranged on the flip cover 160, the air inlet baffle 200 is of a silica gel structure, and has good thermal stability and insulativity, and high mechanical strength, so that the air inlet baffle 200 can be prevented from being adsorbed on the inner side wall of the dust collecting box 100 due to the action of electrostatic force, and meanwhile, the silica gel structure is easy to detach and replace. The box main body 150, the flip cover 160 and the pressing plate 300 are all of plastic structures, have good insulativity, are light and firm in weight, are easy to process and can be produced in a large scale, and are low in price, so that the box main body 150, the flip cover 160 and the pressing plate 300 are of plastic structures, are durable, and are beneficial to saving cost; in addition, each structure in this scheme need not to carry out welding, point and glue, threaded connection etc. when assembling, and its installation is simpler.

Optionally, the cleaning robot further includes a filter 500, where the filter 500 is detachably disposed at the air inlet 130 of the cover 160, so as to prevent the dust in the dust box 100 from entering the first fan, thereby protecting the first fan. Alternatively, the filter 500 may be HEPA (High-EFFICIENCY PARTICULATE ARRESTANCE, high efficiency particulate filter), which may filter ultrafine particulate dust. Optionally, the filter 500 may include a frame and a filter screen, where the filter screen is mounted on the frame, and the frame may be a plastic structure to facilitate disassembly and assembly.

In an alternative embodiment, the dust collecting box 100 further includes a handle 180, and both ends of the handle 180 are movably connected to both sides of the box body 150, respectively, so as to be convenient for a user to hold. Alternatively, the handle 180 may be a plastic construction that is lightweight and sturdy, yet relatively durable.

Optionally, the cleaning robot further includes a dust collecting port baffle 600, the dust collecting port baffle 600 is detachably disposed on the dust collecting box 100, the dust collecting port baffle 600 is located outside the dust collecting box 100, one end of the dust collecting port baffle 600 is rotatably connected with the dust collecting box 100, and the second end of the dust collecting port baffle 600 can rotate relative to the dust collecting port 110 to be close to or far away from the dust collecting port 110, so that the dust collecting port 110 is closed or opened. When the dust collecting port baffle 600 approaches the dust collecting port 110 to close the dust collecting port 110, the dust collecting port baffle 600 can be attached to the edge of the dust collecting port 110, thereby preventing the leakage of the garbage in the dust collecting box 100; when the first fan is turned on, the second end of the dust collecting port shutter 600 is away from the dust collecting port 110 by the airflow, so that the dust collecting port is opened.

In an alternative embodiment, the dust box 100 is further provided with a dust inlet 170, the dust inlet 170 is opposite to the fan inlet 120, the fan inlet 120 is used for exhausting air in the process of cleaning the floor by the cleaning robot, and the dust inlet 170 is abutted against the rolling brush of the cleaning robot so that garbage enters the dust box 100 from the dust inlet 170; in the case that the cleaning base station is in a dust collecting state, a large amount of gas flows through the dust inlet 170 so that the garbage in the dust box 100 is collected in the cleaning base station. The cleaning robot further includes a dust inlet baffle 400, the dust inlet baffle 400 is detachably disposed in the accommodating cavity 140, a first end of the dust inlet baffle 400 is rotatably connected with the dust box 100, and a second end of the dust inlet baffle 400 can rotate relative to the dust inlet 170 to be close to or far from the dust inlet 170, so that the dust inlet 170 is closed or opened. When no gas flows at the dust inlet 170, the dust inlet baffle 400 is close to the dust inlet 170, so that the dust inlet 170 is closed, and the dust in the dust box 100 is prevented from leaking; when there is gas flow at the dust inlet 170, the dust inlet baffle 400 is far away from the dust inlet 170, so that the dust inlet 170 is opened, if the cleaning base station is in a dust collecting state, the dust inlet 170 is used as a main air inlet at this time, and if the cleaning robot is in a working state, the dust inlet 170 can be used for garbage to enter the dust box 100.

It should be noted that, the rotation axis of the dust inlet baffle 400 extends in the horizontal direction so as to seal the dust box 100 under the action of gravity.

Alternatively, the sidewall of the dust inlet shutter 400 contacts with the sidewall of the receiving chamber 140, thereby preventing the dust in the dust box 100 from being caught to the edge of the dust inlet shutter 400. Alternatively, the edge of the dust inlet baffle 400 may be a right angle edge, and the sidewall of the accommodating chamber 140 may be a horizontal plane, so as to facilitate the manufacture of the dust inlet baffle 400 and the dust collecting box 100. Of course, the edge of the dust inlet baffle 400 may be arc-shaped, and the side wall of the accommodating cavity 140 may be an arc-shaped surface, so that the side wall of the accommodating cavity 140 is adapted to the edge of the dust inlet baffle 400, but the manufacturing difficulty of the dust box 100 will be increased.

Optionally, the side wall of the dust box 100 provided with the dust inlet 170 may be inclined, so that the dust inlet 170 is better abutted with the rolling brush of the cleaning robot, thereby improving dust inlet efficiency.

Alternatively, the dust inlet baffle 400 and the dust collecting baffle 600 may be both plastic structures, which have good insulation, are lightweight and strong, and are easy to process and mass-producible, and inexpensive.

In yet another alternative embodiment, the accommodating cavity 140 has a first arc-shaped side wall 144 and a second arc-shaped side wall 145 which are oppositely arranged, the first arc-shaped side wall 144 extends to the air inlet 130, and the second arc-shaped side wall 145 extends to the dust collecting opening 110, so that the air flow in the accommodating cavity 140 is smoother, dead angles are reduced, and the dust collecting efficiency of the cleaning base station is improved.

Alternatively, the radius of the arc of the first arc-shaped sidewall 144 may be 70mm, and the sidewall of the air inlet 130 is tangent to the first arc-shaped sidewall 144, so as to avoid dead angle formation, however, the radius of the arc of the first arc-shaped sidewall 144 may also be other values, which is not particularly limited in the embodiment of the present application.

Alternatively, the radius of the arc of the second arc-shaped sidewall 145 may be 100mm, which may be approximately perpendicular to the sidewall of the dust collecting port 110, so as to avoid blocking the gas flow of the dust collecting port 110, thereby improving the smoothness of the gas flow, however, the radius of the arc of the second arc-shaped sidewall 145 may also be other values, which is not particularly limited in the embodiment of the present application. Further alternatively, the radius of the arc of the second arcuate sidewall 145 is larger and may even approximate a plane.

Optionally, in the embodiment where the sidewall of the dust inlet baffle 400 contacts the sidewall of the accommodating cavity 140, the sidewall of one side of the dust inlet 170 includes a first planar sidewall and a first arc sidewall 144 connected to each other, the sidewall of the other side of the dust inlet 170 includes a second planar sidewall and a second arc sidewall 145, and both ends of the dust inlet baffle 400 contact the first planar sidewall and the second planar sidewall, respectively, so that the garbage in the dust box 100 is prevented from hanging on the edge of the dust inlet baffle 400, and dead corners in the accommodating cavity 140 can be reduced at the same time, so that smooth flow of gas is facilitated.

In an alternative embodiment, the cleaning robot further comprises a second fan, and optionally, the second fan can have two working modes, namely a blowing mode and an exhausting mode when working. The second fan is in communication with the fan port 120, and in the case that the first fan is in the operation mode, i.e., the cleaning base station is in the dust collecting state, the second fan is in the closing mode, the blowing mode or the air suction mode. That is, in the case where the first fan is in the working mode, the second fan may be in the off mode, may be in the blowing mode, and may be in the air suction mode. The method comprises the following steps: when the second fan is in the closed mode, the dust inlet 170 is a main air inlet, a large amount of air enters the dust box 100 from the dust inlet 170, and a small amount of air enters the dust box 100 from the fan inlet 120 and the air inlet 130, so that the mode can be used under the condition that the mass of garbage in the dust box 100 is small; when the second fan is in the blowing mode, the air inlet 170 and the air inlet 120 have larger air inlet quantity, and the air inlet 130 has only a small amount of air inlet, so that the mode can be used under the condition that the dust box 100 contains garbage with larger mass; when the second fan is in the air draft mode, the air intake of the dust inlet 170 will not meet the air draft of the dust collecting opening 110 and the fan opening 120, and a large amount of air is required to enter the air inlet 130, so the air intake of the dust inlet 170 and the air inlet 130 is large, so as to improve the cleaning efficiency of the inner corners of the accommodating cavity 140.

In other embodiments, when the first fan is in the working mode, the second fan may be alternately in at least two of the off mode, the blowing mode and the exhausting mode, where different types of garbage and garbage in different areas in the dust box 100 may be collected in the cleaning base station in a targeted manner, so as to improve the cleaning efficiency of the cleaning base station. Optionally, when the second fan is alternately in at least two of the closing mode, the blowing mode and the exhausting mode, the modes may respectively last for the same time, may respectively last for different times, and may specifically be flexibly set according to actual needs, which is not particularly limited by the embodiment of the present application. Optionally, when the second fan is alternately in the closing mode, the blowing mode and the exhausting mode, the working sequences of the three modes may be sequentially performed, or may be flexibly selected according to actual needs, which is not particularly limited in the embodiment of the present application.

In still another alternative embodiment, the cleaning robot further includes a third fan, where the cleaning base station is in a dust collecting state, the third fan may be in communication with the air inlet 130, and the third fan ventilates into the accommodating cavity through the air inlet 130 at this time, so as to increase the air intake at the air inlet 130, which is beneficial to improving the cleaning efficiency of the edge area of the accommodating cavity 140.

In other embodiments, the cleaning robot further includes a water injection mechanism, which is communicated with the accommodating cavity 140 through the air inlet 130, so as to clean the accommodating cavity 140, especially for cleaning stains attached to the inner wall of the accommodating cavity 140, and the sewage in the accommodating cavity 140 can be discharged through the dust collecting port 110, so that the cleanliness in the accommodating cavity 140 is further improved. Optionally, the water injection mechanism and the first fan may be turned on simultaneously, at this time, the sewage may be discharged in time, so as to avoid that much sewage in the accommodating cavity 140 overflows from the fan port 120 and the air inlet 130, and of course, the water injection mechanism and the first fan may also be turned on sequentially, so that the user may select according to the actual needs, which is not particularly limited in the embodiment of the present application.

The embodiments of the present application have been described above with reference to the accompanying drawings, but the present application is not limited to the above-described embodiments, which are merely illustrative and not restrictive, and many forms may be made by those having ordinary skill in the art without departing from the spirit of the present application and the scope of the claims, which are to be protected by the present application.

Claims (12)

1. The cleaning robot device is characterized by comprising a cleaning base station and a cleaning robot, wherein the cleaning base station comprises a first fan, the cleaning robot comprises a robot main body and a dust collecting box (100), the dust collecting box (100) is arranged in the robot main body, the dust collecting box (100) is provided with a dust collecting opening (110), a fan opening (120) and an air inlet (130), the fan opening (120) and the air inlet (130) are arranged side by side, the air inlet (130) is positioned on one side of the fan opening (120) deviating from the dust collecting opening (110),

When the cleaning base station is in a dust collecting state, the first fan can be communicated with the accommodating cavity (140) of the dust collecting box (100) through the dust collecting opening (110), and the air inlet (130) can ventilate into the accommodating cavity (140).

2. The cleaning robot apparatus of claim 1, further comprising an air intake baffle (200), the air intake baffle (200) being disposed in the accommodating cavity (140), a first end of the air intake baffle (200) being detachably connected to the dust box (100), a second end of the air intake baffle (200) being rotatable relative to the air intake (130) to be close to or away from the air intake (130) to close or open the air intake (130).

3. The cleaning robot device according to claim 2, wherein the air inlet baffle (200) is of a flexible structure, a side of the air inlet baffle (200) facing away from the air inlet (130) is provided with a frangible opening (210), and the frangible opening (210) is located at the first end of the air inlet baffle (200).

4. A cleaning robot device according to claim 3, characterized in that the air inlet baffle (200) comprises a shielding part (220), the shielding part (220) is provided with the frangible opening (210), the shielding part (220) is obliquely arranged along the air inlet direction of the air inlet (130), the air inlet (130) is arranged close to the bottom of the accommodating cavity (140), the side wall of the accommodating cavity is provided with a limit boss (141), the limit boss (141) is arranged around the air inlet (130), the limit boss (141) extends to the bottom of the accommodating cavity (140), and the shielding part (220) is in limit fit with the limit boss (141).

5. A cleaning robot device according to claim 3, characterized in that the cleaning robot further comprises a pressure plate (300), the pressure plate (300) being detachably arranged on the side wall of the receiving cavity (140), and the pressure plate (300) being located above the frangible opening (210), the pressure plate (300) being pressed against the edge of the air inlet flap (200) in the air inlet direction of the air inlet (130).

6. The cleaning robot apparatus according to claim 5, wherein the sidewall of the accommodating chamber (140) is provided with a mounting groove (142), the air inlet baffle (200) includes a shielding part (220) and a hanging part (230) connected, the hanging part (230) is located at a surface of the shielding part (220) facing the air inlet (130), the hanging part (230) is hung on the mounting groove (142), and the pressing plate (300) is pressed on an edge of the shielding part (220) in an air inlet direction of the air inlet (130).

7. The cleaning robot device according to claim 6, wherein the side wall of the mounting groove (142) is provided with an avoidance opening (142 a), the avoidance opening (142 a) extends to the air inlet (130), the side wall of the accommodating cavity (140) is further provided with a fixing portion (143), the fixing portion (143) is located above the air inlet baffle (200), one surface of the pressing plate (300) facing the mounting groove (142) is provided with a clamping portion (310), the clamping portion (310) is clamped to the avoidance opening (142 a), the clamping portion (310) and the hanging portion (230) are arranged side by side, a first end of the pressing plate (300) is pressed to the edge of the shielding portion (220), and a second end of the pressing plate (300) is fixedly matched with the fixing portion (143).

8. The cleaning robot apparatus according to claim 5, wherein the dust collecting case (100) includes a case main body (150) and a cover (160) detachably connected, the cover (160) and the case main body (150) enclose the accommodating chamber (140), the case main body (150) is provided with the dust collecting port (110), the cover (160) is provided with the blower port (120) and the air inlet (130), a first end of the air inlet baffle (200) is detachably connected with the cover (160), the pressing plate (300) is detachably provided in the cover (160), the air inlet baffle (200) is of a silica gel structure, and the case main body (150), the cover (160) and the pressing plate (300) are of a plastic structure.

9. The cleaning robot apparatus according to claim 1, wherein the dust box (100) is further provided with a dust inlet (170), the dust inlet (170) is disposed opposite to the blower opening (120), the cleaning robot further comprises a dust inlet baffle (400), the dust inlet baffle (400) is detachably disposed in the accommodating chamber (140), a first end of the dust inlet baffle (400) is rotatably connected with the dust box (100), and a second end of the dust inlet baffle (400) is rotatable relative to the dust inlet (170) to be close to or far away from the dust inlet (170), so that the dust inlet (170) is closed or opened, and a side wall of the dust inlet baffle (400) is in contact with a side wall of the accommodating chamber (140).

10. The cleaning robotic device of claim 1, wherein the receiving cavity (140) has oppositely disposed first and second arcuate side walls (144, 145), the first arcuate side wall (144) extending to the air inlet (130) and the second arcuate side wall (145) extending to the dust collection port (110).

11. The cleaning robot apparatus of claim 1, further comprising a second blower in communication with the blower port (120), the second blower being in a shut-off mode, a blowing mode, or a suction mode with the first blower in an operational mode, or the second blower being alternately in at least two of the shut-off mode, the blowing mode, and the suction mode.

12. The cleaning robot apparatus according to claim 1, characterized in that the cleaning robot further comprises a third fan, which is communicable with the air intake (130) in case the cleaning base station is in the dust collecting state; and/or the number of the groups of groups,

The cleaning robot further comprises a water injection mechanism, and the water injection mechanism can be communicated with the accommodating cavity (140) through the air inlet (130).