Base station and cleaning system

The integrated tank body design in the base station addresses high costs and safety hazards by using a single mold for housing chambers and positioning near the enclosure's side, improving efficiency and safety in base station layout.

FR3162650B3Active Publication Date: 2026-06-12BEIJING ROCKROBO TECH CO LTD

Patent Information

Authority / Receiving Office
FR · FR
Patent Type
Utility models
Current Assignee / Owner
BEIJING ROCKROBO TECH CO LTD
Filing Date
2025-05-28
Publication Date
2026-06-12

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Patent Text Reader

Abstract

The embodiments of this application describe a base station and a cleaning system. The base station comprises a housing and a tank body. The tank body includes at least a first housing chamber and a second housing chamber, in which the first and second housing chambers are used to store a first and second liquid, respectively. According to the base station proposed by the embodiments of this application, different liquids can be stored in a tank body that is designed to be integral. During a production process, the first and second housing chambers can be manufactured simultaneously using a single mold, thus ensuring high production efficiency. [Fig 1]
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Description

Title of the invention: Base station and cleaning system technical field

[0001] The embodiments of this application relate to the technical field of cleaning systems and in particular a base station and a cleaning system. Context of the invention

[0002] Sweeping robots have seen widespread application in recent years. After operating for a certain period, the sweeping robot must return to a base station to have certain cleaning elements washed off. Therefore, in traditional technologies, a base station is equipped with a first housing chamber and a second housing chamber. During the manufacturing process of a base station, two sets of molds are required to produce the first and second housing chambers, respectively, resulting in a high cost.During the base station layout process, two positions must also be reserved in a base station enclosure to install the first housing chamber and the second housing chamber respectively, and the first and second housing chambers inevitably come into contact with live devices, resulting in safety hazards. Summary of the utility model

[0003] The present utility model aims to solve at least one of the technical problems existing in the prior art or in the related art.

[0004] To this end, in a first aspect of the present utility model, a base station is proposed.

[0005] In a second aspect of the present utility model, a cleaning system is proposed.

[0006] Taking this into consideration, according to a first aspect of the embodiments of the present application, a base station is proposed. The base station comprises:

[0007] a housing; and

[0008] a reservoir body arranged in the housing;

[0009] the tank body comprising at least a first housing chamber and a second housing chamber, in which the first housing chamber and the second housing chamber are used to store respectively a first liquid and a second liquid.

[0010] In a feasible embodiment, the base station further comprises:

[0011] a separation plate, the tank body and the separation plate being made with an integrated structure, the separation plate separating the tank body into a first housing chamber and a second housing chamber.

[0012] In a feasible embodiment, in a height direction of the housing, a transverse area of ​​the tank body, from top to bottom, is progressively reduced.

[0013] In a feasible embodiment, the base station further comprises:

[0014] a lid body arranged on the tank body to close the body of reservoir.

[0015] In a feasible embodiment, the base station further comprises:

[0016] a first set of floating spheres arranged in the first housing chamber; and / or

[0017] a second set of floating spheres arranged in the second housing chamber; and / or

[0018] an overflow assembly connected to the first housing chamber.

[0019] In a feasible embodiment, the tank body is arranged to be close to one side of the housing.

[0020] In a feasible embodiment, a section of the housing along the height direction is polygonal, so that a corner is formed in the housing, and the tank body is arranged at the corner of the housing.

[0021] In a feasible embodiment, the base station further comprises:

[0022] a high-voltage control device, the tank body being arranged on one side of the housing and the high-voltage control device being positioned on the other side of the housing.

[0023] In a feasible embodiment, the base station further comprises: a low-voltage control device, and the low-voltage control device being arranged between the tank body and the high-voltage control device, wherein:

[0024] a nominal voltage of the high-voltage control device is greater than a nominal voltage of the low-voltage control device.

[0025] In a possible implementation, the low-voltage control device comprises:

[0026] a negative pressure element, a dust collection tray being formed in the housing, the negative pressure element being connected to the dust collection tray and used to provide a negative pressure environment for the dust collection tray, and the tank body being positioned on one side of the negative pressure element; and / or

[0027] a drying element, a third housing chamber being formed in the casing and the drying element being used to provide thermal energy for the interior of the third housing chamber.

[0028] In a feasible embodiment, the base station further comprises:

[0029] a dust extraction duct, the third housing chamber being formed in the casing, one end of the dust extraction duct being connected to the third housing chamber, the other end of the dust extraction duct being connected to the dust collection bin, the dust extraction duct being positioned on one side of the negative pressure element opposite the tank body; and / or

[0030] a ramp plate fitted in the third bedroom of the dwelling; and / or

[0031] a cleaning disc arranged on the ramp plate; and / or

[0032] a box body and a pump body, the box body being used to store a cleaning agent inside the latter, and the pump body being connected to the box body and to the first housing chamber.

[0033] In a possible implementation, the high-voltage control device comprises:

[0034] a heating element for heating the liquid flowing from the first housing chamber.

[0035] According to a second aspect of the embodiments of the present application, a cleaning system is proposed. The cleaning system comprises:

[0036] the base station according to any one of the above technical solutions; and

[0037] a cleaning device body, the base station being used to house the cleaning device body.

[0038] Compared to the prior art, the present utility model has at least the following beneficial effects.

[0039] The base station proposed by the embodiments of this application comprises the housing and the tank body. The tank body comprises at least the first housing chamber and the second housing chamber, and a plurality of first housing chambers and a plurality of second housing chambers can be used to store the first liquid and the second liquid, respectively. That is to say, a tank body can store different liquids during the operation of the base station; the first liquid can be clean water, and the second liquid can be wastewater. Based on this, the cleaning elements on the cleaning apparatus body can be cleaned with clean water from the first housing chamber, and the wastewater generated during the cleaning process can be collected via the second housing chamber.According to the base station proposed by the embodiments of this application, . Different liquids can be stored in a single, integrated tank body. During production, the first and second housing chambers can be manufactured simultaneously using a single mold, resulting in high production efficiency and low costs. When positioning the tank body in the base station layout, it can be placed close to the side wall of the enclosure, effectively avoiding live components within the enclosure. This allows for better separation of water and electricity, leading to a more efficient base station layout. The integrated tank body design minimizes its volume while maintaining effective capacity, further reducing the overall size of the base station.This is particularly suitable for an integrated base station. Brief description of the drawings

[0040] Upon reading the following detailed description of the embodiments, various other advantages and benefits will become more apparent to those skilled in the art. The accompanying drawings are provided solely for illustrative purposes of the preferred embodiments but are not considered to be limitations to this application. Throughout the accompanying drawings, the same reference symbols generally refer to the same components. In the drawings:

[0041] [Fig.1] Fig.1 is a structural diagram of a base station according to an embodiment of the present application;

[0042] [Fig.2] Fig.2 is a structural diagram of a tank body of a station base in a fragmented state according to a method of implementation of the present request;

[0043] [Fig.3] Fig.3 is a structural diagram of a tank body of a station based on a method of implementation of the present request from a perspective;

[0044] [Fig.4] The [Fig.4] is a structural diagram of a tank body of a station based on a method of implementing the present request from another perspective;

[0045] [Fig. 5] [Fig. 5] is a structural diagram of a tank body of a station base with a concealed lid body according to an embodiment of the present application from a perspective;

[0046] [Fig.6] Fig.6 is a structural diagram of a tank body of a station base with a concealed lid body according to an embodiment of the present application from another perspective;

[0047] [Fig.7] Fig.7 is a structural diagram of a tank body of a station base with a concealed lid body according to an embodiment of the present application from yet another perspective;

[0048] [Fig-8] The [Fig.8] is a structural diagram of a base station with a partially concealed housing according to an embodiment of the present application from a perspective view;

[0049] [Fig.9] Fig.9 is a structural diagram of a base station with a housing partially concealed according to a method of implementation of the present request from another perspective;

[0050] [Fig. 10] The [Fig. 10] is a structural diagram of a housing and a ramp plate in a base station according to an embodiment of the present application; and

[0051] [Fig. 11] The [Fig. 11] is a structural diagram of a ramp plate and a cleaning disc in a base station according to an embodiment of the present application.

[0052] The corresponding relationships between the reference symbols and the component names in Figures 1 to 11 are as follows:

[0053] 110 - housing; 120 - tank body; 130 - separating plate; 140 - first Floating sphere assembly; 150 - second floating sphere assembly; 160 - overflow assembly; 170 - negative pressure element; 180 - drying element; 190 - heating element; 200 - dust suction duct; 210 - ramp plate; 220 - cleaning disc; 230 - box body; 240 - pump body;

[0054] 121 - first living room; 122 - second living room; and 123 - lid body. Detailed description

[0055] In order to better understand the technical solutions mentioned above, the technical solutions of the embodiments of this application are described in detail by means of the accompanying drawings and the specific embodiments below. It should be understood that the embodiments of this application and the specific features in the embodiments are detailed descriptions of the technical solutions of the embodiments of this application and are not limitations on the technical solutions of this application. In the absence of conflict, the embodiments of this application and the technical features in the embodiments may be combined.

[0056] In the present application, it is considered that a first housing chamber 121 and a second housing chamber 122 of a base station in traditional technologies have a split design. According to this scheme, during the base station manufacturing process, two sets of molds are required to manufacture the first housing chamber 121 and the second housing chamber 122, respectively. housing 122, which translates into a high cost. During the base station layout process, two positions must also be reserved in a base station enclosure to install respectively, the first housing chamber 121 and the second housing chamber 122, and the first housing chamber 121 and the second housing chamber 122 inevitably come into contact with live devices, which results in safety risks.

[0057] Taking this into consideration, as shown in Figures 1 to 11, according to a first aspect of the embodiments of the present application, a base station is proposed. The base station comprises a housing 110; and a tank body 120 arranged in the housing 110. The tank body 120 comprises at least a first housing chamber 121 and a second housing chamber 122, in which the first housing chamber 121 and the second housing chamber 122 are used to store a first liquid and a second liquid, respectively.

[0058] The base station proposed by the embodiments of this application comprises the housing 110 and the tank body 120. The tank body 120 comprises at least two housing spaces, and at least two of these, i.e., first housing chambers 121 and second housing chambers 122 from among a plurality of housing spaces, can be used to store the first liquid and the second liquid, respectively. That is to say, during the operation of the base station, a tank body 120 can store different liquids; the first liquid can be clean water, and the second liquid can be wastewater. Based on this, the cleaning elements on the cleaning unit body can be cleaned with clean water from the first housing chamber 121, and the wastewater generated during the cleaning process can be collected via the second housing chamber 122.According to the base station proposed by the embodiments of this application, different liquids can be stored in a single tank body 120, which is designed as a single unit. During the production process, the first housing chamber 121 and the second housing chamber 122 can be manufactured simultaneously using a single mold, resulting in high production efficiency and low cost. During the base station layout process, the tank body 120 can be positioned close to the side wall of the enclosure 110, thus effectively avoiding contact with live devices in the enclosure 110. This allows for better separation of water and electricity, and can lead to a more efficient base station layout. Through the integrated design of the tank body 120, its volume can be reduced as much as possible. while ensuring effective capacity, which promotes a reduction in the base station's volume. This is particularly suitable for an integrated base station.

[0059] It should be understood that the first housing chamber 121 can be used as a clean water tank, and the second housing chamber 122 can be used as a wastewater tank.

[0060] As shown in Figures 2 to 6, in a feasible embodiment, the base station further includes a separation plate 130. The tank body 120 and the separation plate 130 have an integrated structure, and the separation plate 130 divides the tank body 120 into a first housing chamber 121 and a second housing chamber 122.

[0061] The base station proposed by the embodiments of this application comprises the housing 110, the tank body 120, and the separation plate 130. The separation plate 130 and the tank body 120 have an integrated structure, and the separation plate 130 divides the tank body 120 into a first housing chamber 121 and a second housing chamber 122. During the operation of the base station, the cleaning elements on the cleaning device body can be cleaned with clean water from the first housing chamber 121, and the wastewater generated during the cleaning process can be collected via the second housing chamber 122.

[0062] According to the base station proposed by the embodiments of this application, the tank body 120 and the separation plate 130 have an integrated design, such that the first housing chamber 121 and the second housing chamber 122 also have an integrated design. During the production process, the first housing chamber 121 and the second housing chamber 122 can be manufactured simultaneously using a single mold, resulting in high production efficiency and low cost. During the base station layout process, the tank body 120 can be positioned close to the side wall of the housing 110, thus effectively avoiding live devices in the housing 110, thereby promoting the separation of water and electricity, and making the base station layout more efficient.

[0063] According to the base station proposed by the embodiments of this application, through the integrated design of the tank body 120, the volume of the tank body 120 can be reduced as much as possible while ensuring the effective capacity, which promotes a reduction in the volume of the base station. This is particularly suitable for an integrated base station.

[0064] As shown in Figures 2 to 6, in a feasible embodiment, in a height direction of the housing 110, a transverse area of ​​the tank body 120, from top to bottom, is progressively reduced.

[0065] In this embodiment, a tank body 120 is further proposed in which the cross-sectional area of ​​the tank body 120, from top to bottom, is progressively reduced in the vertical direction of the housing 110, so that the tank body 120 gradually narrows from a wider top to a narrower bottom. With such an arrangement, the tank body 120 can make better use of space at the top of the housing 110 and reserve space at the bottom of the housing 110, so that there is enough space at the bottom of the housing 110 to store the cleaning device body, thus reducing the volume of the base station.

[0066] As shown in Figures 2 and 3, in a feasible embodiment, the base station further comprises a cover body 123. The cover body 123 is arranged on the tank body 120 to close the tank body 120.

[0067] In this technical solution, the base station may further include the cover body 123 which can cover the tank body 120. With such an arrangement, the probability of foreign bodies entering the tank body 120 can be reduced and the cleanliness of the tank body 120 is guaranteed.

[0068] As shown in [Fig.6] and [Fig.7], in a feasible embodiment, the base station further comprises: a first set of floating spheres 140 arranged in the first housing chamber 121; and / or a second set of floating spheres 150 arranged in the second housing chamber 122; and / or an overflow set 160 connected to the first housing chamber 121.

[0069] In this technical solution, the base station may include the first set of floating spheres 140. By arranging the first set of floating spheres 140 in the first housing chamber 121, the base station can monitor the liquid level in the first housing chamber 121, making it convenient to determine whether water is being replenished in the first housing chamber 121. This is particularly suitable for an integrated base station. The liquid level in the tank body can be monitored via the first set of floating spheres 140, and then a water supply pipe can be controlled to automatically replenish the water in the first housing chamber 121, thus enabling better self-sufficiency and reducing manual intervention, thereby improving the user experience.

[0070] In this technical solution, the base station may further comprise the second set of floating spheres 150 arranged in the second housing chamber 122. With the arrangement of the second set of floating spheres 150, the liquid level in the second housing chamber 122 can be monitored, so that the discharge of wastewater from the second housing chamber 122 is easily controlled, which is particularly suitable for an integrated base station. The liquid level of the wastewater can be determined by means of the second The floating sphere assembly 150 allows a discharge valve from the second housing chamber 122 to be easily opened to discharge wastewater into the user's sewer pipe, enabling better self-supply and reducing manual intervention, thus improving the user experience.

[0071] In this technical solution, the base station may further include an overflow assembly 160. With the arrangement of the overflow assembly 160, when the liquid being replenished in the first housing chamber 121 is excessive and the liquid level exceeds a certain height of the overflow assembly 160, the liquid can be discharged through the overflow assembly 160, thus making the base station safer to use. This is particularly suitable for an integrated base station. The other end of the overflow assembly 160 can pass through the housing 110 and be connected to the user's drain pipe.

[0072] As shown in Figures 8 to 9, in a feasible embodiment, the tank body 120 is arranged to be near one side of the housing 110.

[0073] In this technical solution, an arrangement position for the tank body 120 is further proposed. The tank body 120 can be arranged close to the side wall of the housing 110. With such an arrangement, a water receiving device for the base station can be arranged to be close to one side of the housing 110, and the tank body 120 can be kept opposite or as far away as possible from the live devices in the base station, so that the base station can be more reasonable from the point of view of layout and safer in use.

[0074] It must be understood that the tank body 120, which is arranged near the side wall of the housing 110, may refer to the fact that the tank body 120 can be directly connected to the side wall of the housing 110, or that there is an avoidance clearance between the tank body 120 and the side wall of the housing 110, or that there is no other device between the tank body 120 and a side wall of the housing 110, as long as the tank body 120 is arranged on one side in the housing 110 to avoid live devices as much as possible.

[0075] As shown in [Fig.8] and [Fig.9], in a feasible embodiment, a section of the housing 110 along the height direction is polygonal, so that a corner is formed in the housing 110 and the tank body 120 is arranged at the corner of the housing 110.

[0076] In this technical solution, the shape of the housing 110 and the arrangement position of the tank body 120 are further proposed. The cross-section of the housing 110 along the vertical direction is polygonal, which is advantageous for manufacturing the housing 110 and can also make the housing 110 more aesthetically pleasing. In some examples, the housing 110 may be cube-shaped.

[0077] In this technical solution, the tank body 120 is arranged in the corner of the housing 110. That is, the tank body 120 is close to two side walls of the housing 110 simultaneously, and is arranged in the corner inside the housing 110, so that the distance between the tank body 120 and any other loaded device can be further increased, and the tank body 120 can effectively avoid live devices. Meanwhile, the tank body 120's position in the corner of the housing 110 facilitates the drainage of water from the second housing chamber 122 and the supply of water to the first housing chamber 121, thus simplifying the assembly of the base station.

[0078] As shown in [Fig. 8] and [Fig. 9], in a feasible embodiment, the base station further comprises: a high-voltage control device and a low-voltage control device. The tank body 120 is arranged on one side of the housing 110, the high-voltage control device is positioned on the other side of the housing 110, the low-voltage control device is arranged between the tank body 120 and the high-voltage control device, and a rated voltage of the high-voltage control device is greater than a rated voltage of the low-voltage control device.

[0079] In this technical solution, the base station may comprise a plurality of energized devices. This plurality of energized devices may include high-voltage control devices and low-voltage control devices, and the rated voltage of each high-voltage control device is greater than the rated voltage of each low-voltage control device. During the base station layout, the high-voltage control device and the tank body 120 are arranged on opposite sides of the housing 110, and the low-voltage control device is arranged between the high-voltage control device and the tank body 120. This allows the tank body 120 to be positioned opposite the high-voltage control device, resulting in a more efficient layout and safer operation.

[0080] As shown in [Fig.8] and [Fig.9], in a feasible embodiment, the low voltage control device includes a negative pressure element 170. A dust collection bin is formed in the housing 110, the negative pressure element 170 is connected to the dust collection bin and used to provide a negative pressure environment for the dust collection bin, and the tank body 120 is positioned on one side of the negative pressure element 170.

[0081] In this technical solution, the low-voltage control device may include the negative pressure element 170. Based on this, during the working process, when the cleaning device body returns to the base station for For dust collection, the 170 negative pressure element can be activated to provide a negative pressure environment for the dust collection bin. The dust collected by the cleaning unit can then be stored in the dust collection bin under negative pressure. Considering that the 170 negative pressure element can be a fan, and that the fan can be a low-voltage device, the 170 negative pressure element can be positioned on one side of the 120 tank body, resulting in a more compact and safer base station layout.

[0082] As shown in [Fig.8] and [Fig.9], in a feasible embodiment, the low-voltage control device includes a drying element 180. A third housing chamber is formed in the housing 110, and the drying element 180 is used to provide thermal energy for the interior of the third housing chamber.

[0083] In this technical solution, the low-voltage control device may further include a drying element 180. When the cleaning unit returns to the base station and completes the cleaning of the cleaning elements, the drying element 180 can be started to dry the cleaning element. Considering that the cleaning elements are usually dried after the cleaning operation is complete, the user may not need the cleaning unit to operate again for a short period of time. Therefore, the cleaning elements can be dried by providing the drying element 180 with a relatively low rated voltage, and the drying element 180 can be arranged between the high-voltage control device and the tank body 120. Consequently, the tank body 120 can be positioned opposite the high-voltage control device.

[0084] As shown in Figures 8 to 9, in a feasible embodiment, the high-voltage control device includes a heating element 190. The heating element 190 is used to heat the water from the first housing chamber 121.

[0085] In this technical solution, the high-voltage control device may include the heating element 190. During operation, water from the first housing chamber 121 can be heated by the heating element 190, and the water with the increased temperature is then conveyed to the cleaning elements on the cleaning unit body, thus improving cleaning efficiency. Considering that the water requires higher power, the heating element 190 is a high-voltage device. The heating element 190 is arranged opposite the tank body 120, which can make the operation of the base station safer.

[0086] In some examples, the base station may further include a plug-in connector for the power supply. The voltage of such a plug-in connector may be 220 V, so this plug-in connector must also be arranged opposite the tank body 120.

[0087] As shown in [Fig.8] and [Fig.9], in a feasible embodiment, the base station further includes a dust suction duct 200. The third housing chamber is formed in the housing 110, one end of the dust suction duct 200 is connected to the third housing chamber, the other end of the dust suction duct is connected to a dust collection bin, the dust suction duct 200 is positioned on one side of the negative pressure element 170 opposite the tank body 120.

[0088] In this technical solution, the base station may include the dust suction duct 200. On this basis, when the cleaning device body collects the dust, the negative pressure element 170 can be started, a passage is formed between the negative pressure element 170 - the dust collection bin - the dust suction duct 200 - the housing chamber - the cleaning device body, and a negative pressure can act on the cleaning device body through the dust suction duct 200, which facilitates the suction of dust.

[0089] As shown in [Fig.8] and [Fig.9], in a feasible embodiment, the base station further comprises a box body 230 and a pump body 240. The box body 230 is used to store a cleaning agent inside and the pump body 240 is connected to the box body 230 and to the first housing chamber 121.

[0090] In this technical solution, the base station may further comprise the box body 230 and the pump body 240. The user can fill the box body 230 with the cleaning agent. During the cleaning process, the pump body 240 can extract the cleaning agent from the box body 230 and supply the cleaning agent to the first housing chamber 121. Based on this, the first housing chamber 121 can produce clean water containing the dissolved cleaning agent, thus improving the cleaning effect.

[0091] As shown in [Fig. 10] and [Fig. 11], in a feasible embodiment, the base station further comprises a ramp plate 210 arranged in the housing chamber. With the arrangement of the ramp plate 210, it is convenient for the cleaning device body to enter and exit the housing chamber.

[0092] As shown in [Fig. 10] and [Fig. 11], in a feasible embodiment, the base station further comprises a cleaning disc 220 arranged on the ramp plate 210. The cleaning elements on the body of the cleaning device can be cleaned using the cleaning disc 220 and the wastewater generated during the cleaning process can be collected by the second housing chamber 122.

[0093] As shown in Figures 1 to 11, according to a second aspect of the embodiments of the present application, a cleaning system is proposed. The cleaning system comprises the base station according to any one of the above technical solutions; and a cleaning device body, the base station being used to house the cleaning device body.

[0094] Since the cleaning system proposed by the embodiments of this application includes the base station according to any one of the above technical solutions, the cleaning system has all the beneficial effects of the base station in the above technical solutions.

[0095] According to the cleaning system proposed by the embodiments of the present application, when the cleaning device body is in operation, the cleaning elements on the cleaning device body can be wetted with clean water from the first housing chamber 121, and then perform the cleaning, thus improving the cleaning efficiency; when the cleaning device body finishes the cleaning operation, clean water can be supplied to the cleaning elements through the first housing chamber 121 to clean the cleaning elements, and then the wastewater generated during the cleaning process can be recovered by the second housing chamber 122, so that it is more convenient to use the cleaning device body.

[0096] The cleaning system base station proposed by the embodiments of this application comprises the housing 110, the tank body 120, and the separation plate 130. The separation plate 130 and the tank body 120 have an integrated structure, and the separation plate 130 divides the tank body 120 into a first housing chamber 121 and a second housing chamber 122. During the operation of the base station, the cleaning elements on the cleaning apparatus body can be cleaned with clean water from the first housing chamber 121, and the wastewater generated during the cleaning process can be collected by the second housing chamber 122.According to the base station proposed by the embodiments of this application, the tank body 120 and the separation plate 130 have an integrated design, so that the first housing chamber 121 and the second housing chamber 122 also have an integrated design. During the production process, the first housing chamber 121 and the second housing chamber 122 can be manufactured simultaneously using a single mold, resulting in high production efficiency and low cost. During the base station layout process, the... The 120 tank body can be positioned close to the side wall of the 110 enclosure, effectively avoiding contact with live components within the 110 enclosure. This allows for better separation of water and electricity, resulting in a more efficient base station layout. The integrated design of the 120 tank body minimizes its overall volume while maintaining sufficient capacity, further reducing the overall size of the base station. This is particularly suitable for an integrated base station configuration.

[0097] It should be understood that the cleaning system may be an automatic cleaning system, while the body of the cleaning device may be a sweeping robot.

[0098] In this utility model, the terms "first," "second," and "third" are used for descriptive purposes only and are not to be interpreted as indicating or implying relative importance; and the term "a plurality of" refers to two or more, unless otherwise stated. The terms "install," "connected," "connection," "fixed," and the like are to be understood broadly. For example, the term "connection" may refer to a fixed connection, a detachable connection, or an integrated connection; and the term "connected" may refer to being directly connected or indirectly connected via an intermediate support. For a person skilled in the art, the specific meanings of the preceding terms in this utility model can be understood on the basis of specific situations.

[0099] In the description of this utility model, it should be understood that the orientation or positional relationships indicated by technical terms such as "upper," "lower," "left," "right," "front," and "rear" are based on the orientation or positional relationships shown in the drawings and are intended purely to describe embodiments of this utility model and to simplify the description, rather than to indicate or imply that the device or unit referred to must have a specific direction or be configured and operated in a specific orientation. Therefore, these terms should not be construed as limitations to this utility model.

[0100] In the Description, the description of terms such as "an embodiment," "certain embodiments," and "specific embodiments" is intended to indicate that a particular element, structure, material, or feature described in combination with that embodiment or example is included in at least one embodiment or example of this utility model. In the Description, schematic expressions of the above terms do not necessarily refer to the same embodiment. or example. Furthermore, the particular element, structure, material or characteristic described can be combined with any one or more embodiments or examples in an appropriate manner.

[0101] The above describes only preferred embodiments of the present utility model, but they are not intended to limit the present utility model. Various changes and modifications can be made to the present utility model by those skilled in the art. Any modification, equivalent substitution, improvement, etc., carried out in the spirit and principles of the present utility model must be included within the scope of protection of the present utility model.

Claims

Demands

1. Base station comprising: a casing; and a tank body arranged in the casing; the tank body comprising at least a first housing chamber and a second housing chamber, in which the first housing chamber and the second housing chamber are used to store a first liquid and a second liquid respectively.

2. Base station according to claim 1, further comprising: a separation plate, the tank body and the separation plate being an integrated structure and the separation plate dividing the tank body into a first housing chamber and a second housing chamber.

3. Base station according to claim 1, wherein: in a height direction of the casing, a transverse area of ​​the tank body, from top to bottom, is progressively reduced.

4. Base station according to claim 1, further comprising: a cover body arranged on the tank body to close the tank body.

5. Base station according to claim 1, further comprising: a first set of floating spheres arranged in the first housing chamber; and / or a second set of floating spheres arranged in the second housing chamber; and / or an overflow set connected to the first housing chamber.

6. Base station according to any one of claims 1 to 5, wherein: the tank body is arranged to be near one side of the casing.

7. Base station according to any one of claims 1 to 5, wherein: a section of the casing along a height direction is polygonal, so that a corner is formed in the casing, and the tank body is arranged at the corner of the casing.

8. Base station according to any one of claims 1 to 5, further comprising: a high-voltage control device, the tank body being arranged on one side of the housing and the high-voltage control device being positioned on the other side of the housing.

9. Base station according to claim 8, further comprising: a low voltage control device arranged between the tank body and the high voltage control device, wherein: a nominal voltage of the high voltage control device is greater than a nominal voltage of the low voltage control device.

10. Base station according to claim 9, wherein the low-voltage control device comprises: a negative pressure element, a dust collection bin being formed in the housing, the negative pressure element being connected to the dust collection bin and used to provide a negative pressure environment for the dust collection bin, the tank body being positioned on one side of the negative pressure element; and / or a drying element, a third housing chamber being formed in the housing, and the drying element being used to provide thermal energy for an interior of the third housing chamber.

11. Base station according to claim 10, further comprising: a dust suction duct, the third housing chamber being formed in the housing, one end of the dust suction duct being connected to the third housing chamber, the other end of the dust suction duct being connected to the dust collection bin, the dust collection bin being positioned on one side of the negative pressure element opposite the tank body; and / or a ramp plate arranged in the third housing chamber; and / or a cleaning disc being arranged on the ramp plate; and / or a box body and a pump body, the box body being used to store a cleaning agent inside the latter, the pump body being connected to the box body and to the first housing chamber.

12. Base station according to claim 8, wherein the high-voltage control device comprises: a heating element for heating the liquid flowing from the first housing chamber.

13. Cleaning system comprising: the base station according to any one of claims 1 to 12; and a cleaning device body, the base station being used to house the cleaning device body.