CN115528761A - Auxiliary power supply system based on basic device - Google Patents

Abstract

The invention discloses an auxiliary power supply system based on a basic device, which comprises at least one basic device and at least one piece of equipment, wherein the basic device comprises at least one basic base and at least one basic electric device, the basic electric device can be electrically connected in a mode of being placed on the basic base, the base unit is electrically connectable to the base unit, the device is powered by the base unit, and the device is operable to perform work remotely from the base unit.

Description

Auxiliary power supply system based on basic device

Technical Field

The invention relates to the field of storage power supply, in particular to an auxiliary power supply system based on a basic device.

Background

With the improvement of living standard, some intelligent products are gradually accepted by people, for example, intelligent devices such as mobile phones, tablet computers, floor-sweeping robots, dust collectors, mopping machines, automatic washing machines, automatic baking machines, automatic cooking machines, and the like. The charging problem of the intelligent device becomes a great problem. The charger and the charging mode that every money device adaptation differ for the device charges and needs a plurality of charging positions in order to charge, and then occupies a plurality of sockets of user's family, not only causes the socket of user's family to be in short supply, and multiple charger and charging mode also cause user's clean burden moreover. Especially for a user family without more sockets, the user needs to connect to a ground wall surface and drag a row of sockets to provide more sockets, so that the possibility of stumbling exists, and the fire accident caused by overload of electric appliances is more likely to be caused.

It is worth mentioning that smart devices are applied to different spaces. Therefore, the intelligent device is easy to be placed in a certain corner conveniently, and is forgotten by a user, and the intelligent device can be found by spending some time in the next searching. Different smart devices are stacked in each corner separately, take up a lot of space, and are prone to getting messy.

Disclosure of Invention

An object of the present invention is to provide an auxiliary power supply system based on a base device, wherein the accommodating power supply system comprises at least a base and at least one device, wherein the device is accommodated by the base.

Another object of the present invention is to provide an auxiliary power supply system based on a base device, wherein the accommodating power supply system comprises at least one base and at least two devices, wherein the devices are accommodated by the base.

It is another object of the present invention to provide a base unit based auxiliary power system, which includes at least one said base and at least two said devices, wherein said devices are charged by said base.

Another object of the present invention is to provide an auxiliary power supply system based on a base unit, wherein the base is adapted to accommodate at least two devices of different types, wherein the types refer to categories formed by things having common characteristics, for example, a sweeping robot and a vacuum cleaner belong to a cleaning device for cleaning a surface, a mobile phone and an ipad belong to a mobile device for interactive communication, and a cooking device belongs to a cooking device for cooking.

It is another object of the present invention to provide a base unit based auxiliary power supply system, wherein the housing power supply system is adapted to house at least two devices of the same type.

It is another object of the present invention to provide a base unit-based auxiliary power supply system, wherein the base houses at least one cleaning device for cleaning a surface, for example, the cleaning device is implemented as at least one of a sweeping robot, a vacuum cleaner, and a scrubber.

It is another object of the present invention to provide an auxiliary power supply system based on a base unit, wherein the base houses at least one mobile device for interactive communication, for example, the mobile device can be implemented as at least one of a mobile phone, an ipad, a game console, an AR device, and an entertainment electric device.

Another object of the present invention is to provide an auxiliary power supply system based on a base device, wherein the base is received in at least one cooking device, for example, the cooking device can be implemented as at least one of an automatic cooker, a baking machine, a thermo jug and a kettle.

Another object of the present invention is to provide an auxiliary power supply system based on a base unit, wherein the accommodating power supply system can accommodate at least two devices of different types in a rechargeable manner.

Another object of the present invention is to provide an auxiliary power supply system based on a base unit, wherein the accommodating power supply system can accommodate at least two devices of the same type for charging.

Another object of the present invention is to provide an auxiliary power supply system based on a base unit, wherein the base unit supplies power to at least one cleaning device, for example, the cleaning device is implemented as at least one of a sweeping robot, a vacuum cleaner and a floor washing machine.

It is another object of the present invention to provide an auxiliary power supply system based on a base unit, wherein the base unit supplies power to at least one mobile device, for example, the mobile device can be implemented as at least one of a mobile phone, an ipad, a game machine, an AR device, an entertainment electric device, and an entertainment electric device.

It is another object of the present invention to provide an auxiliary power supply system based on a base device, wherein the base supplies power to at least one cooking device, for example, the cooking device can be implemented as at least one of an automatic cooker, a baking machine, a thermo jug and a water kettle.

Another object of the present invention is to provide an auxiliary power supply system based on a base device, wherein the base can continuously supply power to the device, so as to avoid the process of charging the device and the pressure of finding a suitable charging plug and charger seat for the user.

Another objective of the present invention is to provide an auxiliary power supply system based on a base device, wherein the base can continuously supply power to at least two devices, so as to reduce the load of the charging dock in a home, and effectively alleviate the problem of charging dock strain caused by the increase of electric devices.

Another object of the present invention is to provide an auxiliary power supply system based on a base device, wherein the accommodating power supply system can provide an external battery for the equipment to be used alternately, and the replaceable external battery can prolong the service life of the equipment, thereby preventing the problem that the electric equipment cannot be cleaned continuously due to insufficient capacity.

Another objective of the present invention is to provide an auxiliary power supply system based on a base device, wherein the base is charged in an external battery, so as to effectively reduce the problem that an electric device cannot operate for a long time due to damage of the battery, reduce the cost for replacement of the electric device, improve the service life of the electric device, and reduce the operation and maintenance cost of the electric device.

Another object of the present invention is to provide an auxiliary power supply system based on a base unit, wherein the accommodating power supply system realizes the exchange of external batteries between different types of devices.

Another object of the present invention is to provide an auxiliary power supply system based on a base device, wherein at least one other device is powered by the base of the base power supply device which requires a long time for power supply.

Another object of the present invention is to provide an auxiliary power supply system based on basic devices, wherein a long time is required to supply power to the base of a device, and at least one other device and the device are intensively supplied with power.

It is another object of the present invention to provide an auxiliary power system based on a base unit, wherein the connection is triggered by an action of the unit and/or the device.

It is another object of the present invention to provide an auxiliary power supply system based on a base unit wherein the unit and/or the device are electrically connected in a manner disposed in the base unit to collectively supply power to the unit and the device.

It is another object of the present invention to provide an auxiliary power supply system based on a base unit, wherein the unit and/or the device are electrically connected in such a way that the unit and/or the device are embedded to commonly supply power to the unit and the device.

It is another object of the present invention to provide an auxiliary power supply system based on a basic device, wherein the device is implemented as a power supply apparatus, the power supply apparatus and the device are directly powered by the base, and the power supply apparatus is switched to the device when the device is far away from the base, wherein the power supply apparatus not only solves the difficulty of being powered for a long time, but also is more suitable to be switched to the device, so as to ensure that the device is always powered.

Another object of the present invention is to provide an auxiliary power supply system based on a base device, wherein the power supply mode of the device by the base includes, but is not limited to, direct power supply and power exchange power supply, and the device is placed on the base to be powered and is also powered by the power exchange mode when the base is kept at a certain distance, so as to ensure that the device is powered all the time.

It is another object of the present invention to provide a base unit based auxiliary power system that can supply power to a power supply device in a manner that alternates the power supply to the device.

It is another object of the present invention to provide an auxiliary power supply system based on a base unit, wherein the base unit is directly powered by a wired power supply and a wireless power supply.

It is another object of the present invention to provide a base unit-based auxiliary power supply system wherein the base unit is powered by the base at a higher priority than the appliance.

Additional advantages and features of the invention will become apparent from the detailed description which follows, and may be realized by means of the instrumentalities and combinations particularly pointed out in the appended drawings.

In accordance with one aspect of the present invention, the foregoing and other objects and advantages are achieved in the present invention by an auxiliary power supply system based on a base unit, comprising:

at least one base unit, wherein the base unit includes at least one base and at least one base electric unit, the base electric unit being electrically connectable to the base in such a manner that the base electric unit can perform work remotely from the base; and

at least one device, wherein the base is electrically connectable to the base power device, the device being powered by the base, the device being operable to perform work remotely from the base.

According to one embodiment of the invention, at least one of said devices and at least one of said base electrical means are electrically connected in such a way as to be housed in said base.

According to one embodiment of the present invention, the base includes at least one base body, at least one receiving portion, and at least one charging portion, wherein the receiving portion is disposed in the receiving portion, the charging portion is electrically connected to the base body, at least one of the base electric device and the equipment is selected to be electrically connected to the charging portion, and the receiving portion includes at least one first receiving portion and at least one second receiving portion, wherein the base device is disposed in the first receiving portion, and at least one of the equipment is disposed in the second receiving portion.

According to an embodiment of the present invention, the base electric device is a cleaning device, and the cleaning device is accommodated in the first accommodating portion, and the position of the first accommodating portion is lower than the position of the second accommodating portion.

According to an embodiment of the present invention, the charging unit includes at least a first charging terminal and a power supply terminal, wherein the first charging terminal is electrically connected to the base electric device, the first receiving unit has at least a supporting surface, the base electric device is supported by the supporting surface of the first receiving unit, and the first charging terminal is higher than the supporting surface of the first receiving unit.

According to an embodiment of the present invention, the charging portion includes at least a second charging terminal and a power supply terminal, wherein the second charging terminal is electrically connected to the device, and wherein the charging terminal is disposed on the supporting surface of the first receiving portion.

According to one embodiment of the invention, the type of the apparatus is selected from at least one of a combination cleaning device, a mobile device, a power supply device, a communication device, a walking device and a cooking device, and the type of the base electric device is selected from at least one of a combination cleaning device, a mobile device, a power supply device, a communication device, a walking device and a cooking device.

According to one embodiment of the invention, different types of said devices and said apparatus are connected by said base station circuitry.

According to one embodiment of the invention, the base electrical device is a cleaning device, wherein the cleaning device is electrically connected to the base in such a way that the cleaning device can clean at least one area away from the base.

According to one embodiment of the invention, the cleaning device is selected from at least one of a combined sweeping robot, a vacuum cleaner and a floor washing machine.

According to one embodiment of the invention, the cleaning device is a scrubber comprising at least one operating head and at least one body, wherein the operating head of the scrubber is positioned lower on the base than the other devices are electrically connected to the base.

According to one embodiment of the invention, the device is at least one power supply device and the type of the power supply device is selected from the group of types of batteries and battery packs having at least two batteries.

According to one embodiment of the invention, the device is a smart battery pack having at least two pluggable batteries, wherein the smart battery pack supplies power to the other devices in a manner that is remote from the base, the smart battery pack being communicatively connectable to the other devices.

According to one embodiment of the invention, said devices and/or said apparatuses of different types are housed jointly in said base.

According to one embodiment of the invention, the apparatus is of more than 2 types, and the apparatus and the device are electrically connected to the base by at least one selected from the group consisting of a connector, and a connector.

Further objects and advantages of the invention will be fully apparent from the ensuing description and drawings.

Drawings

Fig. 1A is a perspective view and a left side view of a base of an auxiliary power supply system based on a base device according to a first preferred embodiment of the present invention, in a state where the base and the device are separated.

Fig. 1B is a perspective view illustrating the apparatus of the auxiliary power supply system based on the base device according to the above preferred embodiment of the present invention in a state of being accommodated by the base.

Fig. 2A is a perspective view of an auxiliary power supply system based on a base device according to another preferred embodiment of the present invention.

Fig. 2B is a perspective view of a base of an auxiliary power supply system based on a base device according to another preferred embodiment of the present invention.

Fig. 2C is a perspective view of the auxiliary power supply system based on the base device according to the above preferred embodiment of the present invention.

FIG. 2D is a right side view of the auxiliary power supply system based on the base unit according to the above preferred embodiment of the present invention.

Fig. 3A is a perspective view of a base of an auxiliary power supply system based on a base device according to another preferred embodiment of the present invention.

Fig. 3B is another perspective view of the base of the auxiliary power supply system based on the base device according to another preferred embodiment of the present invention.

Fig. 3C is a perspective view of a base of an auxiliary power supply system based on a base device according to a modified embodiment of another preferred embodiment of the present invention.

Fig. 3D is a perspective view of a base of an auxiliary power supply system based on a base device according to a modified embodiment of another preferred embodiment of the present invention.

Fig. 4 is a schematic diagram of an application of the auxiliary power supply system based on the base device according to another preferred embodiment of the invention.

Detailed Description

The following description is presented to disclose the invention so as to enable any person skilled in the art to practice the invention. The preferred embodiments described below are by way of example only, and other obvious variations will occur to those skilled in the art. The underlying principles of the invention, as defined in the following description, may be applied to other embodiments, variations, modifications, equivalents, and other technical solutions without departing from the spirit and scope of the invention.

It will be understood by those skilled in the art that in the present disclosure, the terms "longitudinal," "lateral," "upper," "lower," "front," "rear," "left," "right," "vertical," "horizontal," "top," "bottom," "inner," "outer," and the like are used in an orientation or positional relationship indicated in the drawings for convenience in describing the invention and simplicity in description, but do not indicate or imply that the device or component being referred to must have a particular orientation, be constructed in a particular orientation, and be constructed in a particular manner of operation, and thus, the terms are not to be construed as limiting the invention.

Referring to fig. 1 of the drawings, a base-based power receiving system according to a first preferred embodiment of the present invention is disclosed in detail and explained, wherein the base-based power receiving system includes at least one base 10, wherein the base 10 receives at least one device 20, the base 10 includes a base body 11, a receiving portion 12 and defines at least one receiving space 120, wherein the charging portion 13 is disposed on the base body 11 to define the receiving space 120, and when the device 20 is disposed in the receiving portion 12, the device 20 is received in the receiving space 120 of the receiving portion 12, so that at least one device 20 is received by the power receiving system.

Preferably, the number of said devices 20 is more than two. That is, at least two of the apparatuses 20 are placed in the housing space 120, and at least two of the apparatuses 20 are commonly housed in the base 10.

The base 10 includes the base body 11, the receiving portion 12 and at least one charging portion 13, wherein the charging portion 13 is electrically connected to the base body 11, when the device 20 is placed in the charging portion 13, the charging portion 13 supplies power to the device 20, and the receiving power supply system receives power from at least one device 20.

It should be noted that when at least two of the devices 20 are received in the base 10, at least one of the devices 20 is powered by the base 10.

It should be noted that in other variant embodiments of the invention, the base 10 can house at least three devices 20, and the invention is not limited thereto.

In other variant embodiments of the invention, the base 10 can be charged to at least three of the devices 20, without the invention being limited thereto.

Referring to the first preferred embodiment of the present invention, when 2 devices 20 are commonly placed in the corresponding positions of the charging unit 13, at least two devices 20 are commonly charged by the base 10, so that the base 10 accommodates at least two devices 20 for supplying power, thereby reducing the charging pressure of at least two charging sockets occupied by different devices 20 through different charging heads.

Further, the base body 11 of the base 10 includes a supporting body 111 and a power supply part 112, the power supply part 112 is disposed on the supporting body 111, and the power supply part 112 can be connected to an AC power source or a DC power source, so that the base 10 supplies power to at least two devices 20.

Preferably, the device 20 is a first device 21 and a second device 22, respectively, wherein the first device 21 and the second device 22 can be placed in the receiving portion 12 of different chambers, respectively.

The receiving portion 12 includes a first receiving body 121 and a second receiving body 122. The first apparatus 21 is supported by the first housing body 121, and the second housing body 122 is supported by the second housing body 122.

More preferably, the receiving portion 12 has at least a first receiving cavity 1210 and a second receiving cavity 1220, the first receiving cavity 1210 is defined by the receiving main body 121, and the second receiving cavity 1220 is defined by the second receiving main body 122. The first device 21 is received in the first receiving cavity 1210, and the second device 22 is received in the second receiving cavity 1220.

Further, the charging portion 13 is provided to at least one of the first housing body 121 and the second housing body 122.

Preferably, when the charging portion 13 charges at least one device 20, the charging portion 13 includes a first charging terminal 131, a second charging terminal 132 and at least one power supply terminal 130, the first charging terminal 131 and the second charging terminal 132 are respectively electrically connected to the power supply terminal 130, and the power supply terminal 130 of the charging portion 13 is electrically connected to the power supply portion 112, so that the at least one device 20 is electrically connected to the power supply portion 112.

The first charging terminal 131 is disposed in the first receiving cavity 1210, the second charging terminal 132 is disposed in the second receiving cavity 1220, the first charging terminal 131 is electrically connected to the first device 21, and the second charging terminal 132 is electrically connected to the second device 22.

Preferably, the first receiving cavity 1210 and the second receiving cavity 1220 are respectively circumferentially disposed at the side of the base main body 11. That is, the first device 21 and the second device 22 housed in the housing portion 12 are held at intervals, and mutual interference between products is reduced.

The first charging terminal 131 of the charging unit 13 may be electrically connected to the first device 21 in the same manner or different from the second charging terminal 132 to the second device 22 in the same manner, and may be selected according to the type of the device 20. It will be understood and appreciated by those skilled in the art that the electrical connection means may be embodied as contact point connections and non-contact point connections, and the present invention is not limited thereto. Further, the contact point connection may be through a contact point contact, a plug contact (e.g., such as a USB interface, TYPE C interface, lightning interface), and the non-contact point connection may be implemented as electromagnetic induction, magnetic resonance, microwave transmission, as will be understood and appreciated by those skilled in the art.

The first device 21 is selected from at least one of a combination cleaning device, a mobile device, a cooking device. The cleaning device is implemented, for example, as at least one of a sweeping robot, a vacuum cleaner, a scrubber. The mobile device may be implemented as at least one of a cell phone, an ipad, a game console, an AR device, an entertainment electronic device. For example, the cooking apparatus may be implemented as at least one of an automatic cooker, a baker, a thermo jug, a kettle.

The second device 22 is selected from at least one of a combination cleaning device, a mobile device, a cooking device. The cleaning device is implemented, for example, as at least one of a sweeping robot, a vacuum cleaner, a scrubber. The mobile device may be implemented as at least one of a cell phone, ipad, gaming machine, AR device, entertainment electronic device. For example, the cooking apparatus may be implemented as at least one of an automatic cooker, a baker, a thermo jug, a kettle.

In the first preferred embodiment of the present invention, the first charging terminal 131 is implemented as a contact. When the first device 21 is received in the first receiving cavity 1210, the first device 21 is electrically connected to the first charging terminal 131 in a direct contact manner.

Preferably, the second charging terminal 132 is implemented as a contact. Such that when the second device 22 is received in the second receiving cavity 1220, the second device 22 is electrically connected to the second charging terminal 132 in a direct contact manner.

In another variant embodiment of the present invention, the first charging terminal 131 is implemented as at least one of a USB interface, a TYPE C interface, and a Lightning interface, and the first charging terminal 131 is electrically connected by implementing a direct contact connection of the first device 21.

Optionally, the second charging terminal 132 is implemented as at least one of a USB interface, a TYPE C interface, and a Lightning interface. Such that when the second device 22 is received in the second receiving cavity 1220, the second device 22 is electrically connected to the second charging terminal 132 in a direct contact manner.

It should be noted that the first charging terminal 131 and the second charging terminal 132 can also be implemented as other interfaces, such as VGA data line, DVI data line, HDMI data line, not only for electrical connection, but also for transmission of other information, so that the base 10 can be communicatively connected to other devices 20, and the invention is not limited thereto.

In other modified embodiments of the present invention, the first charging terminal 131 is implemented as a non-contact connection, for example, electromagnetic induction, magnetic resonance, microwave transmission, for example, the first charging terminal 131 and the first device 21 are electrically connected in a magnetic resonance manner, and the present invention is not limited thereto.

Optionally, the second charging terminal 132 is implemented as a non-contact connection, for example, electromagnetic induction, magnetic resonance, microwave transmission, for example, the second charging terminal 132 and the first device 21 are electrically connected in a magnetic resonance manner, and the invention is not limited thereto.

Preferably, the first device 21 has a first charging port 210, and the second device 22 has a second charging port 220, wherein the first charging port 210 of the first device 21 is in contact connection with the first charging terminal 131 of the base 10, and the second charging port 220 of the second device 22 is in contact connection with the second charging terminal 132 of the base 10. The charging types of the first charging port 210 of the first device 21 and the second charging port 220 of the second device 22 are not limited herein, and may be designed according to specific situations.

Referring to fig. 1A and 1B, the first charging port 210 is disposed at the bottom of the first device 21, and the second charging port 220 is disposed at the bottom of the second device 22, which is not limited herein and may be specifically designed according to the types of the first device 21 and the second device 22.

It is worth mentioning that the housing power supply system is applied to the home environment, and the first device 21 and the second device 22 are applied to the home environment after being housed in the base 10. The type of the first device 21 and the second device 22 is not a limitation of the present invention.

When the accommodating power supply system is applied to a living room in the home environment, the accommodating power supply system may preferably be disposed at a height away from the ground so that a user may directly access at least two of the devices 20 accommodated in the accommodating power supply system, wherein the accommodating power supply system may be comfortably taken by the user. When the base 10 of the housing power supply system is placed on a tea table, the user can reach the equipment 20 housed in the housing power supply system.

Referring to fig. 2A of the drawings, another preferred embodiment of the present invention is disclosed and explained in detail, the second device 22 is implemented as a second cleaning device 22A, the first device 21 is implemented as a communication device 23A, the housing power supply system includes at least one second cleaning device 22A and at least one communication device 23A and a base 10, and the second cleaning device 22A is implemented as a holding portion 221C of an integral cleaner 22C. The first receiving cavity 1210 and the second receiving cavity 1220 are formed in an axial direction of the distal end of the support main 111. In other words, the second receiving cavity 1220 is formed at an axial end surface of the supporting main body 111 to support the second cleaning device 22A in a vertically supported manner, and the grip portion 221C of the single body cleaner 22C can be held in a supported manner by the supporting main body 111.

The communication device 23A is preferably implemented as a lan signal expander, wherein the communication device 23A is continuously charged by the base 10 when the communication device 23A can be connected to a lan within a short distance to provide a lan signal to the device 20 that remains within a certain distance.

It is worth mentioning that the communication device 23A has its own battery, and the communication device 23A can be taken to another location so that the communication device 23A is moved to another location to provide a local area network signal.

Alternatively, the communication device 23A may be implemented as a 4G/5G mobile signal device, and the communication device 23A may provide local area network signals for the devices 20 within a certain distance. More optionally, the communication device 23A is self-contained with a battery, such that the communication device 23A can be moved to other areas for providing a local area network.

In other variations, the battery of the communication device 23A may be rechargeable to a mobile device, and the communication device 23A may continuously provide lan and power.

Alternatively, the first receiving cavity 1210 is formed at the ground proximal end of the supporting main body 111, and the first receiving cavity 1210 is formed at a radial sidewall of the supporting main body 111, so that the second cleaning device 22A adapted to automatically walk is received.

In other variant embodiments of the invention, the base 10 can be kept at a height away from the ground, such as a wall set at a height or placed on a surface at a height, such as a table, a cabinet, etc. Alternatively, the second receiving cavity 1220 and the first receiving cavity 1210 are respectively formed at the proximal end of the support main body 111, and the second receiving cavity 1220 and the first receiving cavity 1210 are disposed at intervals on the radial sidewall of the support main body 111. The shapes of the first receiving cavity 1210 and the second receiving cavity 1220 are not limited by the present invention, and those skilled in the art should understand and know.

Referring to fig. 2C and 2D of the drawings, in another preferred embodiment of the present invention, the housing power supply system comprises the base 10 and at least two of the devices 20 continuously powered by the base 10.

Preferably, the housing power supply system comprises the base 10 and at least three of the devices 20 continuously powered by the base 10.

The housing power supply system includes at least a second cleaning device 22A, the communication device 23A and the base 10. The second cleaning device 22A and the communication device 23A are collectively housed in the base 10 and charged by the base 10. The second cleaning device 22A handles the water and the base 10 can charge the second cleaning device 22A and the communication device 23A in the presence of water.

The second cleaning device 22A is always used for floor cleaning by the first receiving cavity 1210 of the first receiving body 121, and thus the base 10 is placed on the floor so that the second cleaning device 22A is placed.

The base 10 further has a third housing body 123 and has a third housing cavity 1230, and the device 20 is implemented as a charging device 24A, and the charging device 24A is received in the third housing cavity 1230. The third housing body 123 and the second housing body 122 are held by the distal end surface of the base body 111. That is, the third receiving body 123 and the second receiving body 122 are formed on the top surface of the base body 111.

Preferably, the charging device 24A is implemented as at least two batteries 24B, and the batteries 24B are held above the base main body 111 in such a manner as to be supported by the third housing main body 123. The battery 24B may be directly accessible and the battery 24B may be used to power other of the devices 20 individually.

Preferably, the battery 24B is embedded to be charged by the base 10.

More preferably, the second housing body 122 is provided with an ejection mechanism so that the battery 24B can be ejected by a key.

Alternatively, at least two of the batteries 24B may be simultaneously one-key ejected.

The second cleaning device 22A is implemented as a scrubber 22D, and the scrubber 22D is held by the first storage body 121 in a position-limited manner.

Referring to fig. 2C of the drawings of the specification, the first receiving body 121 of the base 10 is disposed vertically upward. Preferably, the first receiving body 121 is disposed at one side of the base body 111 away from the base body 111 so that the scrubber 22D can be supported by the base 10, and the first power supply terminal 131 is formed at a sidewall of the base body 111 and is adapted to be directly contacted to charge a charging port of the scrubber 22D.

The floor washing machine 22D may have a part of the sewage remaining in the first receiving body 121, and the base body 111 may supply power to the communication device 23A and the charging device 24A while the first receiving body 121 receives water.

In a modified embodiment of this embodiment, the scrubber 22D may be self-cleaning in the first receiving body 121, and the first receiving body 121 collects the liquid flowing out of the scrubber 22D to prevent the sewage of the scrubber 22D from polluting the ground.

More optionally, the first housing body 121 is provided with a corresponding self-cleaning component to assist the floor washing machine 22D in cleaning.

Referring to fig. 2B of the drawings, when the first cleaning apparatus 21A is implemented as a floor washing machine, preferably, the base 10 further includes an auxiliary cleaning portion 14, wherein the auxiliary cleaning portion 14 is disposed in the first receiving cavity 1210, wherein the auxiliary cleaning portion 14 is adapted to clean a working head 220D of the floor washing machine 22D, so that the base 10 cleans the floor washing machine 22D without human intervention. Further, the charging device 24A is received in the second receiving cavity 1220, and the base 10 may continue to charge the charging device 24A and the scrubber 22D while the scrubber 22D is self-cleaned by the base 10.

It is worth mentioning that the auxiliary cleaning part 14 is formed in the first receiving cavity 1210. The receiving portion 12 further has a supporting surface 123 and at least one extending surface 124, and the first receiving portion 121 has the supporting surface 123 defining the first receiving portion 1210 and the extending surface 124 extending from the supporting surface 123. The second receiving portion 122 has the supporting surface 123 defining the first receiving portion 1210 and the extending surface 124 extending from the supporting surface 123.

Further, the auxiliary cleaning portion 14 is formed on the supporting surface 123 of the first receiving portion 121, when the cleaning device 21 is received in the first receiving cavity 1210 of the receiving portion 12, the floor washing machine 22D is supported by the supporting surface 123, and the floor washing machine 22D is radially limited by the extending surface 124, so that the working head 220D of the floor washing machine 22D is snugly supported by the supporting surface 123, during the self-cleaning of the working head 220D, the first receiving cavity 1210 defined by the extending surface 124 and the supporting surface 123 can carry the water and the dirt flowing out, and the water and the dirt flowing out from the cleaning device 21 are prevented from being contaminated on the ground, further, the auxiliary cleaning portion 14 is preferably disposed on the supporting surface 123, and further, when the working head 220D is driven to rotate for cleaning, the auxiliary cleaning portion 14 can be adapted to the self-cleaning of the working head.

It should be noted that the first charging terminal 131 is disposed on the extending surface 124 of the first receiving portion 121, wherein the first charging terminal 131 is higher than the supporting surface 123 of the first receiving portion 121.

It should be noted that the second charging terminal 132 is disposed on the supporting surface 123 of the second receiving portion 122, wherein the charging device 24A is powered by the second charging terminal 132 in a manner of being placed in the second receiving portion 122, and wherein the charging device 24A is directly electrically connected in a manner of being placed in without a plurality of actions.

It should be noted that the first receiving portion 121 is lower than the second receiving portion 122, and the working head 220D of the scrubber 22D is lower than the first charging end 131 because the working head 220D of the scrubber 22D may have impurities such as water and dirt. Further, the working head 220D and the first charging end 131 of the scrubber 22D are held at intervals.

Since the auxiliary cleaning unit 14 can assist in cleaning the floor washing machine 22D, the auxiliary cleaning unit 14 is provided on the support surface 123 of the first receiving portion 121.

Preferably, the auxiliary cleaning part 14 is a triangular protrusion formed on the supporting surface 123, so that the working head 220D can better discharge sewage and dirt when rotating.

It should be noted that when the auxiliary cleaning part 14 is driven to clean the working head 220D, the auxiliary cleaning part 14 is electrically connected to the power supply terminal 130. For example, the auxiliary cleaning portion 14 may also be an automatic rolling brush, so as to rotate and roll relatively in cooperation with the working head 220D, so as to drive the working head 220D to drain and discharge sewage. The auxiliary cleaning part 14 may be electrically connected by the charging part 13, which should be understood and known to those skilled in the art herein. In addition, the auxiliary cleaning part 14 may be implemented as a type group selected from various forms of grooves, gears, automatic vibration elements, and automatic rolling brush elements, and the present invention is not limited thereto.

Referring to fig. 3A of the drawings, a base unit-based auxiliary power supply system according to another preferred embodiment of the present invention is disclosed and explained in detail, wherein the base unit-based auxiliary power supply system further supplies power to at least two of the apparatuses without wasting a charging dock, compared to the conventional cradle, so that the apparatuses are better housed.

Referring to FIG. 3A of the drawings, the base unit-based auxiliary power system includes at least one base unit 100D and at least one other device 20, wherein the base unit 100D includes at least one base 10D and a base electric unit 30D, wherein the base electric unit 30D and the base 10D are adapted to be electrically connected, the base electric device 30D is adapted to be detachably mounted to the base 10D such that the base electric device 30D can be remotely powered to perform work, particularly, to serve a home space, after the base electric device 30D is powered by the base 10D. The device 20 is detachably mounted on the base 10D, wherein the device 20 is powered by the base unit 100D, so that the user can power the device 20 without occupying other sockets of the home, thereby alleviating the problem of power shortage of the home, and reducing the unexpected risks caused by extension power supply of the extension socket, such as unexpected disengagement of the socket, stumbling of children, splashing of the socket of the extension socket, and the like.

The base electric device 30D and the equipment 20 may be provided commonly to the base 10D, or may be powered commonly by the base electric device 30D. The base electric device 30D and the equipment 20 are powered by at least one selected from the group, and the present invention is not limited in any way in this respect.

Any one of the base electric device 30D and the equipment 20 can be placed on the base 10D to perform work, and any one of the base electric device 30D and the equipment 20 can perform work in a manner of being away from the base 10D, and the present invention is not limited in any way in this respect.

Referring to fig. 3A of the drawings, since the base 30D needs to be accommodated by the base 10D, the equipment 20 is powered by the base 10D of the base 30D, which effectively reduces the number of sockets required. More preferably, the base electric device 30D and the equipment 20 are wirelessly accommodated by the base 10D, so that the base electric device 30D and the equipment 20 can be powered without connecting to a plug board through messy wires, thereby further improving the neatness of home storage and the safety of home power supply.

When the electrical connection manner of the base 10D and the base electric device 30D is a wired connection, the electrical connection manner of the base 10D and the base electric device 30D is further implemented as a contact, for example, at least one of a USB interface, a TYPE C interface, and a Lightning interface.

When the electrical connection of the base foundation 10D and the base electrical device 30D is a wireless connection, the electrical connection of the base foundation 10D and the base electrical device 30D is further implemented as at least one of electromagnetic induction, magnetic resonance, and microwave transmission, as will be understood and appreciated by those skilled in the art.

Referring to the preferred embodiment of the present invention, the electrical connection is achieved by placing the base electrical device 30D on the base housing 10D. That is, the base electric device 30D is disposed in the base 10D to conduct the circuit of the base 10D, which is more convenient and compact.

Preferably, the base electric device 30D and the equipment 20 are not connected to the base 10D through other wires, and the base electric device 30D and the equipment 20 can be connected by a circuit by being respectively disposed on the base 10D, so that the charging manner is more convenient.

Preferably, the base electric device 30D is powered by the base 10D at a higher priority than the equipment 20 is powered by the base 10D. The base electric device 30D is wired-powered by the base 10D, thereby ensuring that the base electric device 30D is priority-powered.

Further, when the percentage of the power supplied to the base electric device 30D is lower than the first threshold, the base electric device 30D is preferentially supplied with power to ensure that the base electric device 30D is preferentially supplied with power.

Optionally, after the power percentage of the base electric device 30D reaches the first threshold, the base electric device 30D is suspended to keep the base 10D powered by the other equipment 20, and the base 10D is powered by the equipment 20 at a sub-optimal level.

It is worth mentioning that the first threshold value is implemented as 70% of the total charge of the base electric device 30D. Preferably, the first threshold value is implemented as 75% of the total charge of the base electric device 30D. Preferably, the first threshold value is implemented as 80% of the total charge of the base electric device 30D. More preferably, the first threshold value is implemented as 85% of the total charge of the base electric device 30D. Further preferably, the first threshold value is implemented as 90% of the total charge of the base electrical device 30D.

When the percentage of power supplied to the base electric device 30D is below a second threshold, at least one of the apparatuses 20 is suspended from power supply. The second threshold is lower than the first threshold.

The second threshold value is implemented as 30% of the total charge of the base electric device 30D. Preferably, the first threshold value is implemented as 25% of the total charge of the base electric device 30D. Preferably, the first threshold value is implemented as 20% of the total charge of the base electric device 30D. More preferably, the first threshold value is implemented as 15% of the total charge of the base electric device 30D. Further preferably, the first threshold value is implemented as 10% of the total charge of the base electrical device 30D.

The base electric device 30D is supplied with power in a priority manner. That is, the output power of the base electric device 30D supplied with power by the base 10D is larger than the output power of the apparatus 20 supplied with power by the base 10D.

Further, the base electric device 30D and the apparatus 20 may do work remotely from the base 10D. Work is a process of converting energy from one form to another, and any one of the base electric device 30D and the apparatus 20 may be implemented to convert electric energy into different types of energy, such as mechanical energy, light energy, and heat energy, and the present invention is not limited thereto.

The base device 100D can always be powered in real time. For example, when the type of the base electric device 30D is at least one power supply device 34D, the base 10D is accommodated in the power supply device 34D, the power supply device 34D is accommodated in the base 10D in the power supply manner, and meanwhile, the base 10D is powered by the other equipment 20 through the base 10D which is always powered, so that the base 10D is powered by the power supply device 34D, and then the base 10D is powered by the other equipment 20, thereby reducing the number of sockets and making the household cleaner.

When the base 30D is of the type having at least one cleaning device 32D, the base 10D is adapted to receive the cleaning device 32D, wherein the cleaning device 32D is received by the base 10D and adapted to receive power from the other device 20, wherein the cleaning device 32D is communicatively coupled to the other device 20, and wherein the cleaning device 32D and the device 20 are adapted to receive power from the base 10D. Furthermore, since the cleaning device 32D needs an adaptive base 10D, the extended function of the base 10D is added to add at least one charging potential to supply power to other devices 20, so as to extend the power supply capacity of the base 10D.

When the base electric device 30D is of the type of at least one mobile device 35D, the base 10D is adapted to receive the mobile device 35D. The mobile device 35D is accommodated to be powered by the base 10D, and the base 10D extends at least one power supply potential to power other devices 20. After the base electrical device 30D is powered by the base 10D, the base is powered to at least one other of the equipment 20, such that at least one of the equipment 20 and the base electrical device 30D are commonly housed and powered.

The base electrically powered device 30D is of the type embodied as a communication device 33D, wherein the communication device 33D means that the communication device 33D provides a local area network such that the communication device 33D is powered by the base 10D while the base 10D powers other devices 20, reducing the need for a large number of outlets and connecting lines for many devices 20 to be powered.

The base electric device 30D is implemented as a cooking device that is conductively connected to the cooking device, and the base 10D provides power to other devices 20 when the cooking device is received by the base 10D. That is, the cooking device and the apparatus 20 are respectively housed in the base 10D.

Alternatively, the type of the base electric device 30D may also be implemented as the walking device 36D, and the invention is not limited thereto.

It is worth mentioning that the walking device 36D transports the prepared food and drink to the target area.

More alternatively, the walking device 36D may be implemented as an intelligent conveying apparatus, such as a balance car, a slide board, an intelligent delivery robot, and an electric car, and the invention is not limited thereto.

Referring to fig. 3B of the drawings, another preferred embodiment of the present invention is disclosed and explained in detail, wherein the base electric device 30D of the base device 100D is implemented as the power supply device 34D, and the type of the power supply device 34D is different from that of the power supply apparatus 24D.

The power supply device 34D includes at least one external battery 341D. The power supply device 34D may be embedded to supply power to other devices 20, and the power supply device 34D may also be connected to other devices 20 by wire connection, where the type of device 20 is adapted to be electrically connected by the power supply device 34D.

More preferably, the number of the power supply devices 34D is 2 or more. The type of the power supply device 34D is not limited by the present invention, and the power of the power supply device 34D is designed according to specific situations.

Preferably, at least one of the power supply devices 34D is a battery pack 342D having at least two batteries 341D. The external battery 341D and the battery pack 342D are embedded to supply power to the other devices 20, respectively, and the external battery 341D and the battery pack 342D may also be connected to the other devices 20 by wires, respectively, where the type of the device 20 may be electrically connected to the external battery 341D and the battery pack 342D.

Preferably, the battery pack 342D is implemented as a smart battery pack having at least two batteries 341D, the external battery 341D and the smart battery pack may be embedded to supply power to other devices 20, respectively, and the external battery 341D and the smart battery pack may be connected to other devices 20 by wire connection, respectively, where the types of the devices 20 may be electrically connected to the external battery 341D and the smart battery pack. It should be noted that the smart battery pack refers to a device that can implement smart interaction or communication, for example, in a home environment, the smart battery pack can receive an instruction from a user and is communicatively connected to the other devices 30D or the other devices 20, and the smart battery pack not only can implement smart interaction, but also can provide power to the other devices 20.

It is worth mentioning that, since the base device 100D is always electrically connected to the mains and/or stored energy, the apparatus 20 can also be powered for a long time by means of the base 10D of the base device 100D. Further, the power supply device 34D and the apparatus 20 are powered at any time by the same base 10D.

Preferably, the power supply device 34D is powered by the base 10D at a higher priority than the device 20 is powered by the base 10D. The power supply device 34D is wired to be powered by the base station 10D, thereby ensuring that the power supply device 34D is powered preferentially.

Further, when the power supply percentage of the power supply device 34D is lower than the first threshold, the base electric device 30D is preferentially powered to ensure that the power supply device 34D is preferentially powered.

Optionally, after the power supply percentage of the power supply device 34D reaches the first threshold, the power supply device 34D is suspended to keep the base 10D powered by the other devices 20, and the base 10D is powered by the devices 20 at a sub-optimal level.

It is worth mentioning that the first threshold value is implemented as 70% of the total power of the power supply device 34D. Preferably, the first threshold value is implemented as 75% of the total power of the power supply device 34D. Preferably, the first threshold value is implemented as 80% of the total capacity of the power supply 34D. More preferably, the first threshold value is implemented as 85% of the total power of the power supply device 34D. Further preferably, the first threshold value is implemented as 90% of the total power of the power supply device 34D.

Referring to fig. 3B of the drawings, the power supply device 34D is configured to be inserted into a power supply, wherein the base 10D includes a base body 11D, a receiving portion 12D and at least one charging portion 13D, and the base 10D has at least one power supply space 110D, wherein the power supply space 110D of the base 10D is defined by the base body 11D, and the charging portion 13D is disposed in the power supply space 110D, so that the power supply device 34D is inserted into the power supply space 110D and then is powered by the charging portion 13D of the base 10D.

Preferably, the charging unit 13D and the power supply device 34D may be electrically connected by a wired connection or a wireless connection.

When the electrical connection manner of the charging part 13D and the power supply device 34D is a wired connection, the electrical connection manner of the charging part 13D and the power supply device 34D is further implemented as a contact, for example, at least one of a USB interface, a TYPE C interface, and a Lightning interface.

Alternatively, when the electrical connection manner of the charging part 13D and the power supply device 34D is a wireless connection, the electrical connection manner of the charging part 13D and the power supply device 34D is further implemented as at least one of electromagnetic induction, magnetic resonance, and microwave transmission, which can be understood and known by those skilled in the art.

The power feeding device 34D is electrically connected to the charging unit 13D so as to be embedded therein. It should be noted that the electrical connection direction of the power supply device 34D is an extending direction along the insertion direction.

Alternatively, the electrical connection direction of the power feeding device 34D is held in a radial direction of the insertion direction of the power feeding device 34D, that is, the power feeding device 31 is electrically connected so as to be attached to the charging unit 13D.

It is worth mentioning that the number of the power supply devices 34D is 2 or more. Further, the number of the power supply devices 34D may be at least one of 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21, 22, 23, 24, 25, 26, 27, 28, 29, 30, 31, 32, 33, 34, 35, 36, and the number of the power supply devices 34D simultaneously supplied with power by the base 10D is not limited in any way by the present invention.

It should be noted that the type of the power supply device 34D is not limited by the present invention, and at least one of the power supply devices 34D is selected from at least one of the combination external battery 341D and a battery pack including at least two external batteries 341D. In other words, the type of the power supply device 34D to be supplied with power from the base 10D is various, and the invention is not limited thereto.

The plurality of power supply devices 34D need at least one of the base bases 10D for centralized power supply, and the base 10D further supplies power to the device 20, so that the power supply device 24D and the plurality of power supply devices 34D are always powered in real time, and can be directly powered without searching a charging seat and a data line, which is more concise and convenient.

It is noted that the type of the device 20 is not limited in any way, and the device 20 may be implemented as a cleaning device 22D, a communication device 23D, a power supply device 24D, a mobile device 25D, a walking device 26D, or a cooking device, for example. The device 20 is preferably the device 20 that often needs to be charged.

Referring to fig. 3C of the drawings, in another preferred embodiment of the present invention, the base electric device 30D is implemented as a communication device 33D, and since the communication device 33D requires a long time to be powered, at least one other type of the device can be powered in real time by the base 10D of the communication device 33D. In other words, the base 10D, which needs to be powered, always supplies power to at least one base electric device 30D and at least one piece of equipment 20, and the base electric device 30D and the equipment 20 operate better.

The communication device 33D refers to a device providing a communication network, and the communication device 33D may provide a local area network using 4G/5G, and may also expand the local area network signals of other communication devices 33D to provide a local area network, which is not limited herein.

Preferably, in the preferred embodiment of the present invention, the communication device 33D is wirelessly connected to the base station 10D. In other words, the communication device 33D can be electrically connected to the base 10D without a wire.

By the communication device 33D being powered on for a long time, the communication device 33D can continue to provide a local area network. Further, by the base 10D of the power supply of the communication device 33D, the communication device 33D and the device 20 are supplied with power for a long time.

More preferably, the communication device 33D has a power storage capability, when the communication device 33D is far away from the base station 10D, the communication device 33D can continuously provide a local area network, the communication device 33D can be provided with a local area network far away from a power supply for a short time, and the communication device 33D can be provided with a local area network to be carried around, so that a user can always obtain the local area network even when the user needs a space with weak local area network signals.

Optionally, the communication device 33D is a 4G/5G communication signal, wherein the communication device 33D is continuously powered by the base station 10D, and when the communication device 33D is moved away from the base station 10D, the communication device 33D is operated as a personal WiFi to provide a local area network.

Optionally, the communication device 33D is a WiFi signal expander, the communication device 33D is continuously powered by the base station 10D, and the communication device 33D is within a WiFi signal range after the communication device 33D is moved away from the base station 10D to provide a local area network.

Preferably, the communication device 33D is powered by the charging section 13D of the base 10D at a higher priority than the device 20 is powered by the base 10D. The communication device 33D is powered by the base 10D by wire, thereby ensuring that the communication device 33D is powered by priority.

Further, the charging portion 13D of the base 10D further includes a first charging terminal 131D, a second charging terminal 132D and at least one power supply terminal 130D, the first charging terminal 131D and the second charging terminal 132D are respectively electrically connected to the power supply terminal 130D, the power supply terminal 130D of the charging portion 13D is electrically connected to the base body 11D, so that the at least one device 20 is electrically connected to the charging portion 13D.

Further, when the percentage of power supplied to the communication device 33D is lower than the first threshold, the base electric device 30D is preferentially powered to ensure that the communication device 33D is preferentially powered.

Optionally, after the percentage of power supplied to the communication device 33D reaches the first threshold, the communication device 33D is suspended from supplying power to keep the base station 10D powered by the other devices 20, and the base station 10D is powered by the devices 20 at a sub-optimal level.

Preferably, when the power supply percentage of the communication device 33D is lower than the second threshold, at least one of the devices 20 is suspended from supplying power. The second threshold is lower than the first threshold.

It is worth mentioning that the first threshold is implemented as 70% of the total power of the communication device 33D. Preferably, the first threshold value is implemented as 75% of the total power of the communication device 33D. Preferably, the first threshold value is implemented as 80% of the total power of the communication device 33D. More preferably, the first threshold value is implemented as 85% of the total power of the communication device 33D. Further preferably, the first threshold value is implemented as 90% of the total power of the communication device 33D.

The second threshold value is implemented as 30% of the total power of the communication device 33D. Preferably, the first threshold value is implemented as 25% of the total power of the communication device 33D. Preferably, the first threshold value is implemented as 20% of the total power of the communication device 33D. More preferably, the first threshold value is implemented as 15% of the total power of the communication device 33D. Further preferably, the first threshold value is implemented as 10% of the total power of the communication device 33D.

Referring to fig. 3D of the drawings, a base device-based auxiliary power supply system according to another preferred embodiment of the present invention is disclosed and explained in detail, and the type of the base device 100D is different from that of the previous preferred embodiment to become a new embodiment, wherein the type of the base device 100D is a clean power supply device. Further, the type of the base electric device 30D of the base device 100D is the cleaning device 32D, and the base 10D supplies power to the cleaning device 32D in real time.

It should be noted that, since the cleaning device 32D is generally bulky, and the base 10D is adapted to the cleaning device 32D and is preset to be connected to a socket, the base 10D and the cleaning device 32D always need to occupy one socket, and by means of the at least two charging portions 13D preset on the base 10D, the cleaning device 32D and the other devices 20 can be electrically connected to each other by occupying only one socket through the base 10D. Further, due to the charging portion 13D preset on the base 10D, the cleaning device 32D and the device 20 do not need to be connected by other wires, and the cleaning device 32D and the device 20 can be electrically connected by being respectively disposed on the base 10D, so that the charging manner is more convenient.

The cleaning device 32D is placed on the base 10D to make an electrical connection. That is, the cleaning device 32D is embedded in the circuit of the base 10D for convenience and simplicity.

Alternatively, the base electric device 30D is implemented as a mobile device 35D, and since the mobile device 35D needs to be charged frequently, the mobile device 35D can be charged for a long time by the base 10D, and cannot be served at any time. More preferably, the mobile device 35D may be implemented as a smart home control device, which is maintained at a distance from the user to serve the user.

Further, the type of the mobile device 35D and the apparatus 20 are preferably different, and the mobile device 35D and the apparatus 20 are always powered by the base 10D.

Preferably, the mobile device 35D is powered by the base 10D at a higher priority than the appliance 20 is powered by the base 10D. The mobile device 35D is powered by the base 10D on a wired basis, thereby ensuring that the mobile device 35D is powered on a prioritized basis.

Further, when the percentage of power supplied to the mobile device 35D is below the first threshold, at least one of the apparatuses 20 is suspended.

Optionally, after the power percentage of the mobile device 35D reaches the first threshold, the mobile device 35D is suspended to keep the base 10D powered on other devices 20, and the base 10D is powered on the devices 20 at a sub-optimal level.

It is worth mentioning that the first threshold is implemented as 70% of the total power of the mobile device 35D. Preferably, the first threshold value is implemented as 75% of the total power of the mobile device 35D. Preferably, the first threshold value is implemented as 80% of the total power of the mobile device 35D. More preferably, the first threshold value is implemented as 85% of the total charge of the mobile device 35D. Further preferably, the first threshold value is implemented as 90% of the total power of the mobile device 35D.

Preferably, the power supply device 24D is suspended from supplying power when the power supply percentage of the mopping machine 320D is below the second threshold.

The second threshold value is implemented as 30% of the total charge of the mobile device 35D. Preferably, the second threshold value is implemented as 25% of the total power of the mobile device 35D. Preferably, the second threshold value is implemented as 20% of the total power of the mobile device 35D. More preferably, the second threshold value is implemented as 15% of the total power of the mobile device 35D. Further preferably, the second threshold value is implemented as 10% of the total charge of the mobile device 35D.

Referring to fig. 4 of the drawings, in another preferred embodiment of the present invention, the base unit-based auxiliary power supply system comprises a base unit 100D and at least one device 20, wherein the base unit 100D further comprises the base 10D and at least one cleaning device 32D, wherein the device 20 is electrically connected to the base 10D in such a manner as to be disposed on the base 10D, wherein the cleaning device 32D and at least one of the device 20 are continuously powered jointly by the base 10D.

Preferably, the auxiliary power supply system based on the base device comprises two of the apparatuses 20 and the base device 100D, wherein the apparatuses 20 are at least one charging apparatus 24D and at least one communication apparatus 23D, respectively. Since the charging device 24D, the communication device 23D, the charging device 24D, and the cleaning device 32D all need to be powered for a long time, the charging device 24D, the communication device 33D, and the cleaning device 32D can be directly powered for a long time by the base 10D to which the cleaning device 32D is mated.

The charging device 24D is at least one detachable battery, and the cleaning device 32D is preferably implemented as a scrubber 320D, whereby the scrubber 320D is self-cleaning or charged by the base 10D to automatically remain clean, wherein the scrubber 320D is continuously powered by the base 10D, and since the base 10D needs to be charged for a long time in order to satisfy other functions of the scrubber 320D, the base 10D, which would otherwise require a long time circuit connection to the mains, is powered by the other devices 20 that need to be powered for a long time, in the preferred embodiment of the present invention, the devices 20 are at least one of the charging device 24D and the communication device 23D.

Further, the scrubber 320D includes at least an operating head 321D and a body 322D, wherein the operating head 321D extends from the body 322D, and the operating head 321D defines an operating head 3210D, wherein the operating head 3210D of the operating head 321D can conform to a cleaning surface. In other words, the operating head 3210D of the operating head 321D is attached to the operating head 3210D, wherein the operating head 321D is driven by the main body 322D to roll on the operating head 3210D, wherein the operating head 321D is driven by the main body 322D to wash the cleaning surface.

Preferably, the cleaning surface is a floor. The operating head 321D is used for cleaning the floor. The operating head 321D is contaminated with water, and in order to ensure safety of the base 10D for supplying power to the other devices 20, the power supply device 24D and the communication device 23D are held at intervals, and then the operating head 321D, the power supply device 24D and the communication device 23D are disposed at a position of the base 10D higher than the operating head 3210D of the washing machine 3210D held at the base 10D, and the power supply device 24D and the communication device 23D are supplied with power from the base 10D in such a manner as to be inserted into the base 10D, thereby reducing a possibility that the communication device 23D and the power supply device 24D are splashed with water. The communication device 23D and the power supply device 24D can be stably housed in the base 10D.

Preferably, the communication device 23D and the power supply device 24D are recessed into the base 10D for power, wherein the communication device 23D and the power supply device 24D and the mopping machine 320D may be continuously powered by the base 10D.

Referring to fig. 4 of the drawings, in the preferred embodiment of the present invention, the housing body 12D includes a first housing body 121D and at least two second housing bodies 122D, and the charging portions 13D are respectively disposed on the first housing body 121D and the second housing bodies 122D. The first housing body 121D of the base 10D is disposed vertically upward. Preferably, the first receiving body 121D is disposed at one side of the base body 11D away from the base body 11D, so that the floor washing machine 320D can be supported by the base 10D, and the power supply is formed at a sidewall of the base body 11D and is adapted to be directly contacted and charged by a charging port 3220D of the floor washing machine 320D.

The floor washing machine 320D may partially hold the first housing body 121D with the contaminated water, and the base body 11D may supply power to the communication device 23A and the charging device 24D when the first housing body 121D receives water.

In a modified embodiment of this embodiment, the scrubber 320D may be self-cleaning in the first receiving body 121D, and the first receiving body 121D collects the liquid flowing out of the scrubber 320D to prevent the sewage of the scrubber 320D from polluting the ground.

More optionally, the first receiving body 121D is provided with a corresponding self-cleaning assembly to assist the floor washing machine 320D in cleaning.

Referring to fig. 4 of the drawings, when the cleaning device 32D is implemented as a scrubber 320D, it is preferable that the base 10D further includes an auxiliary cleaning portion, wherein the auxiliary cleaning portion 14D is disposed in the first receiving cavity 1210D, wherein the auxiliary cleaning portion is adapted to clean an operating head 321D of the scrubber 320D, and thus the base 10D cleans the scrubber 320D without human intervention. Further, the charging device 24D is received in the second receiving cavity 1220D, and the base 10D may continue to charge the charging device 24D and the scrubber 320D during self-cleaning of the scrubber 320D by the base 10D.

The power supply device 24D can also supply power to the floor washing machine 320D in a mode of replacing power, so that the floor washing machine 320D can be continuously supplied with power even if being away from the charging position, the floor washing machine 320D is guaranteed to be always powered, and when the floor washing machine 320D needs to clean a large-area cleaning surface, the floor washing machine 320D can be always powered to clean without interrupting charging halfway.

The operating head 3210D of the scrubber 320D is disposed at a position lower on the base 10D than the other devices 20 electrically connected to the base 10D. That is, the second housing body 122D is located higher than the first housing body 121D.

Further, the base electric device 30D and the apparatus 20 may perform work in a manner remote from the base 10D. The work is a process of converting energy from one form to another, and the basic electric device 30D may be implemented as converting electric energy into different types of energy, such as mechanical energy, light energy, and heat energy, and the invention is not limited thereto. Further, the power supply device 24D releases electric power after storing electric power in a manner of being remote from the base 10D. The scrubber 320D is configured to convert at least one of mechanical energy, thermal energy, and light energy away from the base 10D.

Preferably, the mopping machine 320D is powered by the base 10D at a higher priority than the device 20 is powered by the base 10D. The mopping machine 320D is powered by the base 10D on a wired basis, thereby ensuring that the mopping machine 320D is powered on a prioritized basis.

Further, when the percentage of power supplied to the mopping machine 320D is below the first threshold, the base motor assembly 30D is preferentially powered to ensure that the mopping machine 320D is preferentially powered.

Optionally, after the power percentage of the mopping machine 320D reaches the first threshold, the mopping machine 320D is suspended to keep the base 10D powered on the other devices 20, and the base 10D is powered on the devices 20 at a sub-optimal level.

It is worth mentioning that the first threshold value is implemented as 70% of the total power of the mopping machine 320D. Preferably, the first threshold is implemented as 75% of the total power of the mopping machine 320D. Preferably, the first threshold is implemented as 80% of the total power of the mopping machine 320D. More preferably, the first threshold is implemented as 85% of the total power of the mopping machine 320D. Further preferably, the first threshold value is implemented as 90% of the total electric quantity of the motorgrader 320D.

Preferably, when the power supply percentage of the floor mopping machine 320D is lower than the second threshold, the power supply device 24D is suspended from supplying power.

The second threshold is implemented as 30% of the total power of the mopping machine 320D. Preferably, the second threshold value is implemented as 25% of the total power of the motorgrader 320D. Preferably, the second threshold is implemented as 20% of the total power of the mopping machine 320D. More preferably, the second threshold is implemented as 15% of the total power of the mopping machine 320D. Further preferably, the second threshold value is implemented as 10% of the total power of the mopping machine 320D.

In the preferred embodiment, the scrubber 320D, the communication device 23D, and the power unit 24D are powered simultaneously when the scrubber 320D has no work task reservation. The communication device 23D is preferentially powered when the communication device 23D is below the first threshold and above the second threshold. When the communication device 23D is below the first threshold, the power supply of the power supply device 24D is suspended. That is, the power supply device 24D is powered at a sub-optimal level. While at least one of the scrubber 320D, the communication equipment 23D, and the power supply equipment 24D is remote from the base 10D, the other of the equipment 20 and/or the base electric device 30D is commonly powered.

The priorities of the base electric device 30D and the apparatus 20 are specifically designed according to the types of both.

It is to be noted that different embodiments may be combined, and the invention is not limited in any way here.

It will be appreciated by persons skilled in the art that the embodiments of the invention described above and shown in the drawings are given by way of example only and are not limiting of the invention. The objects of the invention have been fully and effectively accomplished. The functional and structural principles of the present invention have been shown and described in the embodiments, and any variations or modifications may be made to the embodiments of the present invention without departing from the principles described.

Claims (15)

1. An auxiliary power supply system based on a base unit, comprising:

at least one base unit, wherein the base unit includes at least one base and at least one base electric unit, the base electric unit being electrically connectable to the base in such a manner that the base electric unit can perform work remotely from the base; and

at least one device, wherein the base is electrically connectable to the base power device, the device being powered by the base, the device being operable to perform work remotely from the base.

2. The base unit based auxiliary power supply system of claim 1 wherein at least one of said appliances and at least one of said base electrically powered units are electrically connected in such a manner as to be received in said base unit.

3. The base unit based auxiliary power supply system of claim 1, wherein said base includes at least a base body, at least a receiving portion and at least a charging portion, wherein said receiving portion is disposed in said receiving portion, said charging portion is electrically connected to said base body, said base electric device and said equipment are selected to be at least one of electrically connected to said charging portion, said receiving portion includes at least a first receiving portion and at least a second receiving portion, wherein said base unit is disposed in said first receiving portion, and at least one of said equipment is disposed in said second receiving portion.

4. The base unit based auxiliary power supply system of claim 3, wherein the base unit is a cleaning unit received in the first receiving portion at a position lower than the second receiving portion.

5. The device-based auxiliary power supply system according to claim 3, wherein the charging portion comprises at least a first charging terminal and a power supply terminal, wherein the first charging terminal is electrically connected to the base electric device, the first receiving portion has at least a supporting surface, the base electric device is supported by the supporting surface of the first receiving portion, and the first charging terminal is positioned higher than the supporting surface of the first receiving portion.

6. The auxiliary power supply system according to claim 3, wherein the charging part comprises at least a second charging terminal and a power supply terminal, wherein the second charging terminal is electrically connected to the device, and wherein the charging terminal is disposed on the supporting surface of the first receiving part.

7. The base unit based auxiliary power supply system of claim 1, wherein the type of the appliance is selected from at least one of a group consisting of a combination cleaning device, a mobile device, a power supply device, a communication device, a walking device, and a cooking device, and the type of the base electric device is selected from at least one of a group consisting of a combination cleaning device, a mobile device, a power supply device, a communication device, a walking device, and a cooking device.

8. The base unit based auxiliary power system as claimed in claim 1, wherein different types of said equipment and said units are connected by said base circuitry.

9. The base unit based auxiliary power supply system of claim 1 wherein said base unit is a cleaning unit, wherein said cleaning unit is electrically connected to said base unit in a manner that said cleaning unit is remotely located from said base unit to clean at least an area.

10. The base unit based auxiliary power supply system of claim 7, wherein the cleaning unit is selected from at least one of a combination sweeping robot, a vacuum cleaner, and a scrubber.

11. The base unit based auxiliary power system of claim 7, wherein the cleaning device is a scrubber machine comprising at least one operating head and at least one body, wherein the operating head of the scrubber machine is positioned at a lower level on the base than other of the equipment is electrically connected to the base.

12. The base unit based auxiliary power supply system of claim 5 wherein the device is at least one power supply device and the type of the power supply device is selected from the group of types of batteries and battery packs having at least two batteries.

13. The base unit based auxiliary power supply system of claim 12 wherein said appliance is a smart battery pack having at least two pluggable batteries, wherein said smart battery pack powers other said appliances in a manner that is remote from said base, said smart battery pack being communicatively connectable to other said appliances.

14. A base unit based auxiliary power supply system according to claim 1 wherein said devices and/or said units of different types are commonly housed in said base.

15. The auxiliary power supply system based on basic device as claimed in claim 1, wherein the types of the equipments are 2 or more, and the equipments and the devices are selected at least one of them to be electrically connected to the basic base.

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