CN116014827A - Remote control power supply, power supply assembly, power utilization device, system and control method of power utilization device - Google Patents

Abstract

The invention provides a remote control power supply, a power supply assembly, a power utilization device, a system and a control method thereof, wherein the remote control power supply comprises: a battery or battery pack for providing electrical energy to the power device; the wireless communication unit is used for wirelessly communicating with the cloud and is in wireless communication connection with the mobile communication equipment; the control unit is used for receiving the control instruction sent by the cloud through the wireless communication unit and executing the control instruction, wherein the control instruction at least comprises a power-on instruction, and the control unit is used for driving the battery or the battery pack to start the power-on device according to the power-on instruction; the acquisition unit is used for acquiring state information of the power utilization device and/or state information of the remote control power supply; the storage unit is used for temporarily storing the state information acquired by the acquisition unit under the condition of no network and sending the state information temporarily stored by the storage unit to the cloud through the wireless communication unit after the wireless communication unit is connected with the wireless network. The state information of the invention is not easy to lose.

Description

Remote control power supply, power supply assembly, power utilization device, system and control method of power utilization device

Technical Field

The invention relates to the field of power supply, in particular to a remote control power supply, a power supply assembly, a power utilization device, a system thereof and a control method.

Background

The traditional power that provides the electric energy for the power consumption device is mostly battery or group battery structural design, and battery package that like traditional garden instrument battery package or family cleaning tool used does not possess networking communication and memory function mostly, and the user needs the consumer direct contact when the operation is used to control the consumer, and when no network state in addition, the real-time state information of consumer and battery package can't convey away, because state information can't store, the condition of losing appears easily.

Disclosure of Invention

The invention provides a remote control power supply, a power supply assembly, a power utilization device, a system thereof and a control method.

Specifically, the invention is realized by the following technical scheme:

a first aspect of the present invention provides a remote control power supply for an electrical device, comprising:

a battery or battery pack for providing electrical energy to the power device;

the wireless communication unit is used for wirelessly communicating with the cloud and is in wireless communication connection with the mobile communication equipment;

the control unit is used for receiving a control instruction sent by the mobile communication equipment through the wireless communication unit and executing the control instruction, wherein the control instruction at least comprises a power-on instruction, and the control unit is used for driving the battery or the battery pack to start the power utilization device according to the power-on instruction;

The acquisition unit is used for acquiring state information of the power utilization device and/or state information of the remote control power supply;

the storage unit is used for temporarily storing the state information acquired by the acquisition unit under the condition of no network and sending the state information temporarily stored by the storage unit to the cloud through the wireless communication unit after the wireless communication unit is connected with a wireless network.

A second aspect of the present invention provides a power supply assembly for an electrical device, the power supply assembly comprising:

the remote control power supply of the first aspect.

A third aspect of the present invention provides an electric device comprising:

an electricity consumption component; and

the power supply assembly of the second aspect is configured to provide electrical energy to the power utilization assembly.

A fourth aspect of the invention provides an electrical power consumption system comprising:

a mobile communication device;

the cloud end is in wireless communication connection with the mobile communication equipment; and

the power supply assembly of the second aspect, wherein a remote control power supply of the power supply assembly is in wireless communication connection with the mobile communication device through the cloud end, or the remote control power supply of the power supply assembly is in wireless communication connection with the cloud end through the mobile communication device.

A fifth aspect of the present invention provides a control method of an electricity consumption system implemented by a mobile communication device, the electricity consumption system including a remote control power supply and an electricity consumption apparatus, the remote control power supply being configured to supply electric power to the electricity consumption apparatus; the method comprises the following steps:

the method comprises the steps that a request of inquiring an instruction is sent to a cloud, wherein the mobile communication equipment is in wireless communication connection with the cloud, the cloud is in wireless communication connection with a remote control power supply, when no network exists, the remote control power supply temporarily stores state information of an electric device and state information of the remote control power supply collected by the remote control power supply, after the remote control power supply is connected with a wireless network, the remote control power supply sends the temporarily stored state information to the cloud through the wireless network, and the cloud stores the temporarily stored state information;

and receiving state information corresponding to the query instruction in the state information stored in the cloud end and returned by the cloud end aiming at the request of the query instruction.

A sixth aspect of the present invention provides a mobile communication device comprising:

the communication device is used for establishing communication with the cloud end through a wireless network;

Processing means for carrying out the method of the fifth aspect;

and a memory for processing or storing the signals as a physical storage state.

A seventh aspect of the present invention provides a control method of an electricity consumption system, the method being implemented by a cloud, the electricity consumption system including a remote control power supply and an electricity consumption device, the remote control power supply being configured to provide electric energy to the electricity consumption device; the method comprises the following steps:

after the remote control power supply is connected with a wireless network, state information of the power utilization device and state information of the remote control power supply, which are acquired by the remote control power supply and are temporarily stored when the remote control power supply is not connected with the wireless network, are received;

and storing the received temporarily stored state information.

An eighth aspect of the present invention provides a cloud end, comprising:

one or more central processing units for implementing the method of the seventh aspect;

one or more memories and/or storage devices;

one or more wired or wireless network interfaces.

A ninth aspect of the present invention provides a control method of an electric device, the electric system including a remote control power supply and an electric device, the remote control power supply being configured to supply electric power to the electric device, the method being implemented by the and remote control power supply; the method comprises the following steps:

When the remote control power supply supplies electric energy to the power utilization device, acquiring state information of the power utilization device and state information of the remote control power supply through an acquisition unit of the remote control power supply;

under the condition of no network, temporarily storing the state information collected by the acquisition unit through a storage unit of the remote control power supply;

and after the remote control power supply is connected with a wireless network, the temporarily stored state information is sent to the cloud through the wireless network.

A tenth aspect of the present invention provides a remote control power supply, comprising:

a control unit for implementing the method according to the ninth aspect.

According to the technical scheme provided by the embodiment of the invention, when the remote control power supply is not in a network, the state information of the power utilization device and the state information of the remote control power supply are temporarily stored through the storage unit of the remote control power supply, and after the wireless network is connected, the state information temporarily stored by the storage unit is uploaded to the cloud through the wireless communication unit, so that the state information is not easy to lose, and a user can conveniently check the state information.

It is to be understood that both the foregoing general description and the following detailed description are exemplary and explanatory only and are not restrictive of the invention as claimed.

Drawings

The accompanying drawings, which are incorporated in and constitute a part of this specification, illustrate embodiments consistent with the invention and together with the description, serve to explain the principles of the invention.

Fig. 1 is a schematic diagram of a control principle module of a remote control power supply according to an embodiment of the present invention;

FIG. 2 is a schematic diagram of a functional module of a remote control power supply according to an embodiment of the present invention;

FIG. 3a is a schematic diagram of a remote control power supply according to an embodiment of the present invention;

FIG. 3b is a schematic diagram of a remote control power supply according to an embodiment of the present invention with three batteries;

FIG. 3c is a schematic diagram of a remote control power supply according to an embodiment of the present invention with five batteries;

FIG. 3d is a schematic diagram of a combination of remote control power supplies in the form of a plurality of single batteries according to an embodiment of the present invention;

FIG. 3e is a schematic diagram of a remote control power supply according to an embodiment of the present invention;

FIG. 4a is a schematic diagram illustrating an assembly of a remote control power supply and an indoor fan according to an embodiment of the present invention;

FIG. 4b is a schematic diagram of a remote control power supply assembly for an indoor fan according to an embodiment of the present invention;

FIG. 4c is a schematic diagram of a remote control power supply assembly for a cleaning robot according to an embodiment of the present invention;

FIG. 4d is a schematic diagram of a remote control power supply assembly according to an embodiment of the present invention, suitable for an outdoor vehicle-mounted refrigerator;

fig. 4e is a schematic diagram of a remote control power supply in the form of an energy storage power station according to an embodiment of the present invention, which is suitable for an outdoor vehicle-mounted refrigerator;

FIG. 5 is a flowchart of a control method of an electric power consumption system according to an embodiment of the present invention;

FIG. 6 is another flowchart of a control method of an electric power consumption system according to an embodiment of the present invention;

FIG. 7 is another flowchart of a control method of an electric power consumption system according to an embodiment of the present invention;

FIG. 8 is a flowchart of another type of power-off step in a control method of an electric power consumption system according to an embodiment of the present invention;

FIG. 9 is a schematic diagram of another control principle module of the remote control power supply according to the embodiment of the present invention;

FIG. 10 is a schematic diagram of a functional module of a second power supply according to an embodiment of the present invention;

FIG. 11 is another flow chart of a control method of another power utilization system according to an embodiment of the present invention;

FIG. 12 is another flow chart of a control method of another power utilization system according to an embodiment of the present invention;

FIG. 13 is another flow chart of a control method of another power utilization system according to an embodiment of the present invention;

FIG. 14 is a schematic diagram of a remote control power supply according to another embodiment of the present invention;

FIG. 15 is a schematic diagram of a functional module of a third power supply according to an embodiment of the present invention;

FIG. 16 is another flow chart of a control method of a further power utilization system according to an embodiment of the present invention;

FIG. 17 is another flow chart of a control method of a further power utilization system according to an embodiment of the present invention;

FIG. 18 is another flow chart of a control method of a further power utilization system according to an embodiment of the present invention;

FIG. 19 is a schematic diagram of a control principle module of a remote control power supply according to an embodiment of the present invention;

FIG. 20 is another flow chart of a control method of a further power utilization system according to an embodiment of the present invention;

FIG. 21 is another flow chart of a control method of a further power utilization system according to an embodiment of the present invention;

FIG. 22 is another flow chart of a control method of a further power utilization system according to an embodiment of the present invention;

FIG. 23 is a schematic diagram of a control principle module of a remote control power supply according to an embodiment of the present invention;

FIG. 24 is another flow chart of a control method of a further power utilization system according to an embodiment of the present invention;

FIG. 25 is another flow chart of a control method of a further power utilization system according to an embodiment of the present invention;

FIG. 26 is another flow chart of a control method of a further power utilization system according to an embodiment of the present invention;

FIG. 27 is a schematic diagram of a control principle module of a remote control power supply according to an embodiment of the present invention;

FIG. 28 is another flow chart of a control method of a further power utilization system according to an embodiment of the present invention;

FIG. 29 is another flow chart of a control method of a further power utilization system according to an embodiment of the present invention;

fig. 30 is another flowchart of a control method of a further power utilization system according to an embodiment of the present invention.

Detailed Description

Reference will now be made in detail to exemplary embodiments, examples of which are illustrated in the accompanying drawings. When the following description refers to the accompanying drawings, the same numbers in different drawings refer to the same or similar elements, unless otherwise indicated. The implementations described in the following exemplary examples do not represent all implementations consistent with the invention. Rather, they are merely examples of apparatus and methods consistent with aspects of the invention as detailed in the accompanying claims.

The terminology used herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention. As used in this specification and the appended claims, the singular forms "a," "an," and "the" are intended to include the plural forms as well, unless the context clearly indicates otherwise. It should also be understood that the term "and/or" as used herein refers to and encompasses any or all possible combinations of one or more of the associated listed items.

It should be understood that although the terms first, second, third, etc. may be used herein to describe various information, these information should not be limited by these terms. These terms are only used to distinguish one type of information from another. For example, first information may also be referred to as second information, and similarly, second information may also be referred to as first information, without departing from the scope of the invention. The word "if" as used herein may be interpreted as "at … …" or "at … …" or "responsive to a determination", depending on the context.

The features of the following examples and embodiments may be combined with each other without any conflict.

As shown in fig. 1, the remote control power supply 100 of the power consumption device 200 is configured to provide power to the power consumption device 200, and simultaneously receive a control command sent from the cloud 300 through a wireless network and execute the control command.

The electric device 200 may be an electric tool, such as an electric drill, an electric angle grinder, an electric hammer, a sprayer, etc., an electric gardening tool, such as a pruning machine, a grass cutting machine, a chain saw, etc., or an electric household tool, such as a dust collector, a coffee machine, an electric fan, a juice extractor, etc., or other types of electric equipment, such as a glue gun, an air pump, an emergency lamp, etc., and in general, the electric device 200 may refer to an operation device using a secondary battery or a battery pack (such as an energy storage power source/an energy storage power station) as a power source; when the power utilization device 200 is operated, the power supply is required to provide electric energy to drive the power utilization device to operate.

Specifically, the remote control power supply 100 is adapted to an indoor fan as shown in fig. 4a and 4 b; the remote control power supply 100 may also be adapted to a cleaning robot as shown in fig. 4 c; the remote power supply assembly may also be adapted for use in an outdoor vehicle-mounted refrigerator as shown in fig. 4d and 4 e.

The remote control power supply 100 may be built in the power utilization device 200, and the power utilization device 200 may operate to provide electric energy; the power consumption device 200 may also be externally arranged, for example, when the remote control power supply 100 is used as a specific energy storage power supply 100e, the energy storage power supply 100e is externally arranged and is connected to a power line or a data line of the power consumption device 200 for supplying power (as shown in fig. 4 e).

As shown in fig. 2, the remote control power supply includes:

a battery 10 or battery pack for providing electric power to the power utilization device 200;

the wireless communication unit is used for being in wireless communication connection with the cloud 300 and being in wireless communication connection with the mobile communication equipment;

the control unit is used for receiving the control instruction sent by the mobile communication equipment through the wireless communication unit and executing the control instruction;

the acquisition unit is used for acquiring state information of the power utilization device and/or state information of the remote control power supply;

and the storage unit is used for temporarily storing the acquired state information under the condition of no network.

After the wireless network is connected, the storage unit sends the temporarily stored state information to the cloud through the wireless communication unit.

In some embodiments, the mobile communication device is indirectly connected to the wireless communication unit of the remote control power supply 100 in a wireless communication manner, as shown in fig. 1, the mobile communication device is connected to the cloud 300 in a wireless communication manner, the cloud 300 is connected to the wireless communication unit of the remote control power supply 100 in a wireless communication manner, and the wireless communication between the mobile communication device and the wireless communication unit of the remote control power supply 100 is achieved through the transfer of the cloud 300. The control instruction sent by the mobile communication device is forwarded to the wireless communication unit of the remote control power supply 100 through the cloud 300, and then the wireless communication unit of the remote control power supply 100 forwards the control instruction to the control unit of the remote control power supply 100. In other embodiments, the mobile communication device is directly connected to the wireless communication unit of the remote control power supply 100 in a wireless communication manner, and the control command sent by the mobile communication device is directly transmitted to the wireless communication unit of the remote control power supply 100, and then the wireless communication unit of the remote control power supply 100 forwards the control command to the control unit of the remote control power supply 100.

The control command in the embodiment of the invention at least includes a power-on command, and the control unit is configured to drive the battery or the battery pack to start the power utilization device 200 according to the power-on command, where the power utilization device 200 is in a power utilization state.

In some embodiments, the control instruction may further include a power-off instruction and/or a parameter setting instruction, where when the control unit receives the power-off instruction sent by the mobile communication device through the wireless unit, the control unit controls the battery 10 or the battery pack to power off the power utilization device 200, and the power utilization device 200 is powered off; when the control unit receives a parameter setting instruction sent by the mobile communication device through the wireless unit, the control unit performs parameter setting on the remote control power supply and/or the power utilization device, for example, the control unit can set parameters such as output current and/or output voltage of the remote control power supply and/or set working modes, working parameters and the like of the power utilization device according to the parameter setting instruction.

The status information of the remote power supply may include status information of the battery/battery pack, and may also include other status information of the remote power supply.

In some embodiments, the cloud 300 directly stores the state information transmitted from the storage unit, for example, to a mass storage device such as a solid state disk. In other embodiments, the cloud 300 classifies the status information transmitted from the storage unit and stores the classified status information in a mass storage device such as a solid state disk. For example, the cloud 300 may classify the state information transmitted from the storage unit into the state information of the power consumption device 200, the state information of the remote control power supply 100, and store in two folders or different storage areas of the storage device, respectively.

Referring to fig. 2, the remote control power supply 100 includes a control unit, an acquisition unit, a storage unit, a communication interface, and an input device, where the control unit, the acquisition unit, and the storage unit are all communicably connected to the communication interface. The control unit includes a microprocessor for processing data; the cloud terminal can be in bidirectional communication with the cloud terminal through the communication interface, and can also be in bidirectional communication with the mobile communication device through the communication interface. The user may input instructions or information into the control unit through the input means to cause the control unit to execute the contents of the instructions or information.

The battery 10 or the battery pack at least has one battery, such as 1 21700 battery, and 3 21700 batteries or 5 21700 batteries can be connected in series, so as to meet the requirements of the power utilization devices of different voltage platforms. It should be noted that the foregoing is merely illustrative, and is not limited to use with 21700 batteries, and that other types of batteries, such as 18650 batteries, may be employed.

The battery pack may further include at least one battery module composed of a plurality of batteries connected in series or parallel to each other, so as to be used as the energy storage power source or the energy storage power station 100 e.

Specifically, the remote control power supply 100 has various forms, such as:

Referring to fig. 3a, a remote control power supply 100a is a schematic diagram of a single battery configuration, in which only 1 21700 battery 10 is incorporated;

referring to fig. 3b, the remote control power supply 100b is a three-battery schematic diagram, in which 3 21700 batteries 10 are connected in series;

referring to fig. 3c, the remote control power supply 100c is a schematic diagram of five batteries, in which 5 21700 batteries 10 are connected in series;

the remote control power supply 10d shown in fig. 3d is a schematic diagram of a configuration in which a plurality of remote control power supplies (as shown in fig. 3 a) in a single battery configuration are combined with each other, and includes a plurality of remote control power supplies 100a specifically shown as 4 remote control power supplies 100a connected in series or in parallel with each other, and may be configured by a plurality of remote control power supplies 100b or 100c connected in series or in parallel with each other.

Referring to fig. 3e, a remote control power supply is a schematic form of an energy storage power station, which includes at least one battery module, wherein the battery module is formed by a plurality of batteries 10, and the batteries or the battery pack is used as an energy storage power supply or an energy storage power station.

The wireless communication unit is configured to implement wireless communication with the cloud 300, and the wireless communication unit at least includes a communication module, and the communication module may be a cellular (e.g. 2G/3G/4G/5G/NB-IOT/LTE-M) or a non-cellular (e.g. WiFi/bluetooth/ZigBee/Lora/Sigfox) or both.

The wireless communication unit may have a 4G/5G communication function, or a WiFi/bluetooth connection function, and may also have both a 4G/5G communication function and a WiFi/bluetooth connection function.

The cloud is a server, which is herein understood to be a service point providing processing, database, communication facilities. For example, a server may refer to a single physical processor with associated communication and data storage and database facilities, or it may refer to an aggregate of networked or aggregated processors, associated networks, and storage devices, and operate on software and one or more database systems and application software supporting services provided by the server. Servers may vary widely in configuration or performance, but servers may generally include one or more central processing units and memory. The Server also includes one or more mass storage devices, one or more power supplies, one or more wired or wireless network interfaces, one or more input/output interfaces, or one or more operating systems, such as Windows Server, mac OS X, unix, linux, freeBSD, and the like.

According to some embodiments of the invention, the cloud may be an integral server or a distributed server across multiple computers or computer data centers. The server may be of various types such as, but not limited to, a web server, news server, mail server, message server, advertisement server, file server, application server, interaction server, database server, or proxy server. In some embodiments, each server may include hardware, software, or embedded logic components or a combination of two or more such components for performing the appropriate functions supported by or implemented by the server. In the present invention, the server is used to provide all functions necessary to support remote control of the above remote control power supply.

The cloud end at least comprises: one or more central processing units; one or more memories and/or mass storage devices; one or more wired or wireless network interfaces.

The cloud end establishes communication with the mobile communication equipment through the wireless network, the mobile communication equipment controls a remote control power supply through the cloud end, and the remote control power supply reports state information to the cloud end at regular time.

The mobile communication device at least comprises a communication device, a processing device and a memory; the communication device is used for sending or receiving signals through a wired or wireless network; the processing device comprises an application processing part and a radio frequency/digital signal processor; the memory is used for processing or storing the signals as physical storage states; such as mobile phones, pad, notebooks, etc.

In some embodiments, the collecting unit is configured to collect, when the power supply supplies power to the power consumption device, state information of the power consumption device and/or state information of the remote control power supply, where the state information collected by the collecting unit optionally includes information when the remote control power supply executes the control instruction (such as whether the remote control power supply successfully executes the control instruction or information obtained by the remote control power supply based on the control instruction).

The collecting unit can be a plurality of sensors which can be built in the power utilization device and are used for detecting each state information of the power utilization device; the sensor is also arranged in the battery/battery pack and used for detecting each state information of the battery/battery pack; and when the value detected by the sensor exceeds a preset threshold value, automatically closing a power supply circuit between the power utilization device and the remote control battery.

The state information comprises state information of an electric device and/or state information of a remote control power supply, and the state information of the electric device comprises one or more of electric state information, power-off state information, working state information, position information, residual electric quantity information and temperature information; the state information of the remote control power supply includes one or more of temperature information, remaining power information, position information, and charging information.

The storage unit can be a FLASH chip, a random dynamic memory or a cache chip, and can be any other memory component for storing data information.

As shown in fig. 5, when no wireless network state exists, the automatic acquisition and storage flow of the state information is as follows: in step S1, an acquisition unit acquires status information of an electric device and/or a remote control power supply; in step S2, the acquired state information is stored in a storage unit; after connecting to the wireless network, the following flows also exist: in step S3, the storage unit transmits the state information to the cloud end through the wireless communication unit, and the cloud end stores the state information in a classified manner.

As shown in fig. 6, when a wireless network state exists, in step S10, the acquisition unit acquires state information of the power utilization device and/or the remote control power supply; in step S20, the collected state information is transmitted to the cloud end through the wireless communication unit, and the cloud end stores the state information in a classified manner.

As shown in fig. 7, the query flow of the state information is as follows: in step S100, the mobile communication device sends a request for querying an instruction to the cloud 300; in step S200, after receiving a request of a query instruction, the cloud end searches for corresponding state information; in step S300, the found status information feedback is sent to the mobile communication device.

As shown in fig. 8, the flow of executing the control instruction is: in step S1000, the mobile communication device sends a request for a control instruction to the cloud 300; in step S2000, after receiving the request of the control command, the cloud 300 sends the control command to the remote control power supply 100 to control the command; in step S3000, the remote control power supply 100 transmits status information of the execution control command to the cloud end 300; in step S4000, the cloud 300 sends status information feedback of the execution control instruction to the mobile communication device.

In some embodiments, after the remote control power supply 100 is connected to the wireless network through the wireless communication unit, the collecting unit collects the state information of the power consumption device 200 and/or the state information of the remote control power supply, and sends the state information collected in real time to the cloud end 300 through the wireless network, that is, the remote control power supply 100 transmits the collected state information to the cloud end 300 in real time through the wireless network under the condition that the wireless network exists, without temporarily storing the collected state information through the storage unit.

Another embodiment of the remote control power supply, as shown in fig. 9, includes a first power supply 700 (the first power supply 700 shown in fig. 9 may be referred to as a charging power supply) and a second power supply 800, which are connected in series or parallel to each other, where the second power supply 800 is connected to the power consumption device 200 to supply power to the power consumption device 200. The first power supply 700 has a wireless communication unit for wireless communication with the cloud end 300, wherein the wireless communication unit at least has a communication module, specifically, the communication module is a cellular (e.g. 2G/3G/4G/5G/NB-IOT/LTE-M);

the first power supply 700 preferably takes the form of an energy storage power station, i.e. as shown in fig. 3e, and comprises at least one battery module, which is formed by a plurality of batteries 10, wherein the batteries or battery packs are used as an energy storage power source or energy storage power station (also called outdoor power source).

According to the existing energy storage power station technology, a conventional energy storage power station or an outdoor power supply has DC output and AC output functions, and is provided with a cigarette lighting port (vehicle charging port), a mains supply charging port, a solar panel charging port, a PD bidirectional charging and discharging port, an intelligent display screen and the like; it will be appreciated that the first power supply 700, when in the form of an energy storage power station, will also have the conventional requisite functions and configurations of existing energy storage power stations.

The first power supply 700 may be adapted to charge the second power supply 800, preferably, the capacity (Ah) of the first power supply 700 is larger than the capacity (Ah) of the second power supply; or the first power source 700 has a greater energy (WH) than the second power source.

The second power supply 800 also has a wireless communication unit for implementing wireless communication with the first power supply 700, where the wireless communication unit has at least a communication module, specifically, the communication module is non-cellular (e.g. WiFi/bluetooth/ZigBee/Lora/Sigfox).

The second power supply 800 may be built in the power utilization device 200, and the power utilization device may operate to provide electric energy; the power consumption device 200 may also be externally arranged, for example, when the second power supply 800 is used as a specific energy storage power supply 100e, the energy storage power supply 100e is externally arranged and connected to a power line or a data line of the power consumption device 200 for supplying power (as shown in fig. 4 e).

Of course, it is preferable that the second power supply 800 is detachably mounted on the electric device 200, and the second power supply 800 is suitable for different types of electric devices 200, i.e., the second power supply 800 may be used by electric tools, electric gardening tools, and electric home tools, such as:

the user has a second power supply 800 of 3.6V, 12V or 20V, which not only can be used for a power drill, but also can be used for a pruning machine, in addition, can be used for a dust collector or an emergency lamp, and thus, the second power supply 800 can meet different use scenes of the user.

When the second power supply 800 is assembled and connected to the power utilization device 200, the second power supply 800 is adapted to be mechanically and electrically connected to the power utilization device 200, secured by the mechanical connection, and to provide electrical power to the power utilization device 200 by the electrical connection.

As shown in fig. 10, the second power supply 800 includes:

a battery 10 or battery pack for providing electric power to the power utilization device 200;

the wireless communication unit is used for wirelessly communicating with the cloud 300 and is in wireless communication connection with the mobile communication equipment;

a control unit for receiving a control instruction from the mobile communication device forwarded through the first power supply 700 through the wireless communication unit of the second power supply 800 and executing the control instruction;

the acquisition unit is used for acquiring state information of the power utilization device and/or state information of the remote control power supply;

the storage unit is used for temporarily storing the acquired state information and the information fed back by the control unit under the condition of no network.

After connecting to the wireless network, the second power supply 800 sends the status information to the first power supply 700 through the wireless communication unit of the second power supply 800, and the first power supply 700 transmits the status information to the cloud.

In some embodiments, the mobile communication device is indirectly connected to the first power supply 700 in a wireless communication manner, as shown in fig. 9, the mobile communication device is connected to the cloud 300 in a wireless communication manner, and the wireless communication between the cloud 300 and the wireless communication unit of the first power supply 700 is achieved through the transfer of the cloud 300. The control command sent by the mobile communication device is forwarded to the first power supply 700 through the cloud 300, and then the first power supply 700 forwards the control command to the wireless communication unit of the second power supply 800.

In other embodiments, the mobile communication device is directly connected to the first power supply 700 in a wireless communication manner, and the control command sent by the mobile communication device is directly transmitted to the first power supply 700, and then the first power supply 700 forwards the control command to the wireless communication unit of the second power supply 800. The control command may at least include a power-on command, and the control unit is configured to drive the battery or the battery pack to start the power utilization device 200 according to the power-on command, where the power utilization device 200 is in a power utilization state.

In some embodiments, the control instruction may further include a power-off instruction and/or a parameter setting instruction, where when the control unit receives the power-off instruction sent by the mobile communication device through the wireless unit, the control unit controls the battery 10 or the battery pack to power off the power utilization device 200, and the power utilization device 200 is powered off; when the control unit receives a parameter setting instruction sent by the mobile communication device through the wireless unit, the control unit performs parameter setting on the remote control power supply and/or the power utilization device, for example, the control unit can set parameters such as output current and/or output voltage of the remote control power supply and/or set working modes, working parameters and the like of the power utilization device according to the parameter setting instruction.

The cloud 300 sends a power-off instruction to the first power supply 700, the first power supply 700 forwards the power-off instruction to the second power supply 800, and the control unit of the second power supply 800 controls the battery 10 or the battery pack to turn off the power consumption device 200 according to the power-off instruction, so that the power consumption device 200 is powered off.

In some embodiments, the cloud 300 directly stores the state information transmitted from the storage unit, for example, to a mass storage device such as a solid state disk. In other embodiments, the cloud 300 classifies the status information transmitted from the storage unit and stores the classified status information in a mass storage device such as a solid state disk. For example, the cloud 300 may classify the state information transmitted from the storage unit into the state information of the power consumption device 200, the state information of the remote control power supply, and store in two folders or different storage areas of the storage apparatus, respectively.

The second power supply 800 may be configured by at least connecting a first remote control power supply and a second remote control power supply in series or in parallel.

Specifically, the second power supply 800 may have various forms, such as:

a single cell configuration as shown in fig. 3 a; or, a three battery configuration as shown in fig. 3 b; or, five battery morphology diagrams as shown in fig. 3 c; or, as shown in fig. 3d, a plurality of remote control power sources in the form of single batteries (as shown in fig. 3 a) are combined with each other; or, the energy storage power station configuration as shown in fig. 3 e.

The collecting unit can be a plurality of sensors which can be built in the power utilization device and are used for detecting each state information of the power utilization device; the sensor is also arranged in the battery/battery pack and used for detecting each state information of the battery/battery pack; and when the value detected by the sensor exceeds a preset threshold value, automatically closing a power supply circuit between the power utilization device and the remote control battery.

The state information comprises state information of an electric device and/or state information of a remote control power supply, and the state information of the electric device comprises one or more of electric state information, power-off state information, working state information, position information, residual electric quantity information and temperature information; the state information of the remote control power supply includes one or more of temperature information, remaining power information, position information, and charging information.

The storage unit can be a FLASH chip, a random dynamic memory or a cache chip, and can be any other memory component for storing data information.

As shown in fig. 11, when no wireless network state exists, the automatic acquisition and storage flow of the state information is as follows: in step S1, an acquisition unit acquires status information of an electric device and/or a remote control power supply; in step S2, the acquired state information is stored in a storage unit; after connecting to the wireless network, the following flows also exist: in step S3, the storage unit transmits the status information to the first power source 700 through the wireless communication unit of the second power source 800; in step S4, the first power supply 700 transmits the state information to the cloud end through the wireless network, and the cloud end stores the state information in a classified manner.

As shown in fig. 12, when a wireless network state exists, the automatic acquisition and storage flow of the state information is as follows: in step S10, the collecting unit collects status information of the power consumption device and/or the remote control power supply; in step S20, when the wireless network state exists, the collected state information is transmitted to the first power supply 700 through the wireless communication unit of the second power supply 800; in step S30, the first power supply 700 transmits the status information to the cloud end via the wireless network, and the cloud end stores the status information in a classified manner.

The flow of this query for status information is shown in fig. 7.

As shown in fig. 13, the flow of executing the control instruction is: in step S100, the mobile communication device sends a request for a control instruction to the cloud 300; in step S200, after receiving the request of the control instruction, the cloud 300 sends the control instruction to the first power supply; in step S300, after receiving the control instruction, the first power supply sends the control instruction to the second power supply to execute the control instruction; in step S400, the second power supply transmits status information of the execution control instruction to the cloud 300; in step S500, the cloud 300 sends status information feedback of the execution control instruction to the mobile communication device.

In another embodiment of the remote control power supply described above, as shown in fig. 14, the remote control power supply includes a first power supply 700, a second power supply 800, and a third power supply 900.

The first power supply 700 or the second power supply 800 has a wireless communication unit for implementing wireless communication with the cloud 300, and the wireless communication unit at least has a communication module. Specifically, the wireless cellular communication function of the first power supply 700 or the second power supply 800 needs to be activated after the first power supply 700 is electrically connected with the second power supply 800, the first power supply 700 has a mounting portion 700a suitable for the electrical connection of the second power supply 800, the second power supply 800 is adapted to be mounted and connected to the mounting portion 700a, at this time, the second power supply 800 is positioned and mounted and connected with the first power supply 700 while the electrical connection is achieved, more specifically, the mounting portion is provided with another electrical terminal electrically matched with the electrical terminal of the second power supply 800, at this time, the control unit of the first power supply 700 or the second power supply 800 detects the electrical signal adapted to the two, and activates the wireless cellular communication function of the first power supply 700 or the second power supply 800.

Or, the second power supply 800 is connected to the first power supply 700 in a positioning and mounting manner, and meanwhile, signal connection is achieved, more specifically, the mounting portion is provided with another signal terminal which is connected to the signal terminal of the second power supply 800 in an electrical signal manner, when the two are connected in a mounting manner, handshake identification is performed on signals of the two, and a wireless cellular communication function of the first power supply 700 or the second power supply 800 is activated.

The third power supply 900 also has a wireless communication unit for implementing wireless communication with the first power supply 700 or the second power supply 800 that is activated with a wireless cellular communication function, where the wireless communication unit at least has a communication module, specifically, the communication module is a non-cellular type (such as WiFi/bluetooth/ZigBee/Lora/Sigfox);

and the same is done; the third power supply 900 is connected to the power consumption device 200, and is used for providing electric energy to the power consumption device 200, and similarly, the power consumption device 200 may be an electric tool, such as an electric drill, an electric angle grinder, an electric hammer, a sprayer, or an electric gardening tool, such as a pruning machine, a grass cutting machine, a chain saw, or an electric household tool, such as a dust collector, a coffee machine, an electric fan, a juice extractor, or other types of electric equipment, such as a glue gun, an air pump, an emergency lamp, or the like, and in general, the power consumption device 200 may be an operation device using a secondary battery or a battery pack (such as an energy storage power supply/an energy storage power station) as a power source; when the power utilization device 200 is operated, the power supply is required to provide electric energy to drive the power utilization device to operate.

The third power supply 900 may be built in the power utilization device 200, and the power utilization device may operate to provide electric energy; the power consumption device 200 may also be externally arranged, for example, when the third power supply 900 is used as a specific energy storage power supply 100e, the energy storage power supply 100e is externally arranged and connected with a power line or a data line of the power consumption device 200 to supply power (as shown in fig. 4 e);

Of course, it is preferable that the third power supply 900 is detachably mounted on the electric device 200, and the third power supply 900 is suitable for different types of electric devices 200, i.e., the third power supply 900 may be shared by electric tools, electric gardening tools, and electric home tools, such as:

the user has a third power supply 900 of 3.6V, 12V or 20V, which not only can be used for a power drill, but also can be used for a pruning machine, in addition, can be used for a dust collector or an emergency lamp, and thus, the third power supply 900 can meet different use scenes of the user.

When the third power supply 900 is assembled and connected to the electric device 200, the third power supply 900 is adapted to be mechanically and electrically connected to the electric device 200, secured by the mechanical connection, and to supply electric power to the electric device 200 by the electrical connection.

As shown in fig. 15, the third power supply 900 includes:

a battery 10 or battery pack for providing electric power to the power utilization device 200;

the wireless communication unit is used for being in wireless communication connection with the cloud 300 and being in wireless communication connection with the mobile communication equipment;

a control unit for receiving a control instruction from the mobile communication device forwarded via the first power supply 700 or the second power supply 800 activated with the wireless cellular communication function through the wireless communication unit of the third power supply 900, and executing the control instruction;

The acquisition unit is used for acquiring state information of the power utilization device and/or state information of the remote control power supply;

the storage unit is used for temporarily storing the acquired state information and the information fed back by the control unit under the condition of no network.

After connecting to the wireless network, the third power supply 900 sends the status information to the first power supply 700 or the second power supply 800 with the activated wireless cellular communication function through the wireless communication unit of the third power supply 900, and the first power supply 700 or the second power supply 800 with the activated wireless cellular communication function sends the status information to the cloud end 300.

In some embodiments, the mobile communication device is indirectly connected to the first power supply 700 or the second power supply 800 with the activated wireless cellular communication function in a wireless communication manner, as shown in fig. 14, the mobile communication device is connected to the cloud 300 in a wireless communication manner, the cloud 300 is connected to the wireless communication unit of the first power supply 700 or the second power supply 800 with the activated wireless cellular communication function in a wireless communication manner, and the mobile communication device is connected to the first power supply 700 or the second power supply 800 with the activated wireless cellular communication function in a wireless communication manner through the transfer of the cloud 300. The control instruction sent by the mobile communication device is forwarded to the first power supply 700 or the second power supply 800 with the activated wireless cellular communication function through the cloud 300, and then the first power supply 700 or the second power supply 800 with the activated wireless cellular communication function forwards the control instruction to the wireless communication unit of the third power supply 900.

In other embodiments, the mobile communication device is directly connected to the first power supply 700 or the second power supply 800 of the activated wireless cellular communication function in a wireless communication manner, and the control command sent by the mobile communication device is directly transmitted to the first power supply 700 or the second power supply 800 of the activated wireless cellular communication function, and then the first power supply 700 or the second power supply 800 of the activated wireless cellular communication function forwards the control command to the wireless communication unit of the third power supply 900.

The control command may at least include a power-on command, and the control unit is configured to drive the battery or the battery pack to start the power utilization device 200 according to the power-on command, where the power utilization device 200 is in a power utilization state.

In some embodiments, the control instruction may further include a power-off instruction and/or a parameter setting instruction, where when the control unit receives the power-off instruction sent by the mobile communication device through the wireless unit, the control unit controls the battery 10 or the battery pack to power off the power utilization device 200, and the power utilization device 200 is powered off; when the control unit receives a parameter setting instruction sent by the mobile communication device through the wireless unit, the control unit performs parameter setting on the remote control power supply and/or the power utilization device, for example, the control unit can set parameters such as output current and/or output voltage of the remote control power supply and/or set working modes, working parameters and the like of the power utilization device according to the parameter setting instruction.

In some embodiments, the cloud 300 directly stores the state information transmitted from the storage unit, for example, to a mass storage device such as a solid state disk. In other embodiments, the cloud 300 classifies the status information transmitted from the storage unit and stores the classified status information in a mass storage device such as a solid state disk. For example, the cloud 300 may classify the state information transmitted from the storage unit into the state information of the power consumption device 200, the state information of the remote control power supply, and store in two folders or different storage areas of the storage apparatus, respectively.

As shown in fig. 16, when no wireless network state exists, the automatic acquisition and storage flow of the state information is as follows: in step S1, an acquisition unit acquires status information of an electric device and/or a remote control power supply; in step S2, the acquired state information is stored in a storage unit; after being connected to the wireless network, the following procedures also exist: in step S3, the state information stored in the storage unit is transmitted to the first power source or the second power source through the wireless communication unit of the third power source 900; in step S4, the first power source or the second power source transmits the state information to the cloud end through the wireless network, and the cloud end stores the state information in a classified manner.

As shown in fig. 17, when a wireless network state exists, the automatic acquisition and storage flow of the state information is as follows: in step S10, the collecting unit collects status information of the power consumption device and/or the remote control power supply; in step S20, the collected state information is transmitted to the first power supply 700 or the second power supply 800 through the wireless communication unit of the third power supply 900; in step S30, the first power supply 700 or the second power supply 800 transmits the status information to the cloud end via the wireless network, and the cloud end stores the status information in a classified manner.

The flow of this query for status information is shown in fig. 7.

As shown in fig. 18, the flow of executing the control instruction is: in step S100, the mobile communication device sends a request for a control instruction to the cloud 300; in step S200, after receiving the request of the control instruction, the cloud 300 sends the control instruction to the first power supply 700 or the second power supply 800; in step S300, after receiving the control instruction, the first power supply 700 or the second power supply 800 sends the control instruction to the third power supply 900 to execute the control instruction; in step S400, the third power supply 900 transmits the status information of the execution control instruction to the cloud end 300; in step S500, the cloud 300 sends status information feedback of the execution control instruction to the mobile communication device.

As shown in fig. 19, the remote control power supply 100 of the power consumption device 200 is configured to supply power to the power consumption device 200, and at the same time, receive a control command sent from the mobile communication apparatus through the wireless network and execute the control command.

The remote control power supply 100 in fig. 19 is directly connected to the mobile communication device in a wireless communication manner, and the remote control power supply 100 is configured to receive a control command sent from the mobile communication device and feedback status information of the power consumption device 200 and/or the remote control power supply 100 to the mobile communication device. The remote control power supply 100 temporarily stores the acquired state information when no network exists, and transmits the temporarily stored state information to the mobile communication device after connecting to the wireless network. It will be appreciated that when the remote control power supply 100 is in a wireless network connection state, the state information of the power consumption device 200 and/or the remote control power supply 100 is also collected, and the collected state information is sent to the mobile communication device in real time.

The remote control power supply 100 has a wireless communication unit, and the wireless communication unit has at least a wireless communication module, and the wireless communication module can be a cellular type (such as 2G/3G/4G/5G/NB-IOT/LTE-M) or a non-cellular type (such as WiFi/Bluetooth/ZigBee/Lora/Sigfox), or both.

The functional module of the remote control power supply is shown in fig. 2.

The mobile communication device is in wireless communication connection with the cloud end, and is configured to transmit the status information transmitted from the remote control power supply 100 to the cloud end, where the cloud end stores or classifies the status information, and the wireless communication unit at least has a wireless communication module, where the wireless communication module is a cellular type (e.g., 2G/3G/4G/5G/NB-IOT/LTE-M).

As shown in fig. 20, when the wireless network state does not exist, the automatic data recording flow of the state information is as follows: in step S1, an acquisition unit acquires status information of an electric device and/or a remote control power supply; in step S2, the acquired state information is stored in a storage unit; after connecting to the wireless network, the following flows also exist: transmitting the state information stored in the storage unit to the mobile communication device through the wireless communication unit in step S3; in step S4, the mobile communication device transmits the state information to the cloud end through the wireless communication network, and the cloud end stores the state information in a classified manner.

As shown in fig. 21, when the wireless network state exists, the automatic data recording flow of the state information is as follows: in step S10, the collecting unit collects status information of the power consumption device and/or the remote control power supply; in step S20, the acquired status information is transmitted to the mobile communication device through the wireless communication unit; in step S30, the mobile communication device transmits the state information to the cloud end through the wireless communication network, and the cloud end stores the state information in a classified manner.

The flow of the query for status information is shown in fig. 7.

As shown in fig. 22, the flow of executing the control instruction is: in step S100, the mobile communication device transmits a request for a control instruction to the remote control power supply, and the remote control power supply executes the control instruction; in step S200, the remote control power supply 100 transmits status information of the execution control instruction (i.e., a case where the remote control power supply 100 executes the control instruction) to the mobile communication device; in step S300, the mobile communication device transmits the state information of the execution control instruction to the cloud end 300, and the cloud end stores the state information in a classified manner; meanwhile, in step S400, the mobile communication device further transmits the request information of the control instruction to the cloud end, and the cloud end stores the request information in a classified manner.

As shown in fig. 23, the remote control power supply includes a first power supply 700 and a second power supply 800, which are connected in series or parallel to each other, and the second power supply 800 is connected to the power consumption device 200 to supply power to the power consumption device 200.

The first power supply 700 in fig. 23 has a wireless communication unit for implementing wireless communication with a mobile communication device, where the wireless communication unit has at least a communication module, specifically, the communication module is a cellular (e.g. 2G/3G/4G/5G/NB-IOT/LTE-M) or a non-cellular (e.g. WiFi/bluetooth/ZigBee/Lora/Sigfox) or both.

The functional blocks of the second power supply are shown in fig. 10.

The first power supply 700 in fig. 23 is directly connected to the mobile communication device in a wireless communication manner, the first power supply 700 is configured to receive a control instruction sent from the mobile communication device, forward the control instruction to the second power supply 800, and execute the control instruction by the second power supply 800; and the first power supply 700 also forwards the status information of the power consumption device 200 and/or the remote control power supply 100 fed back by the second power supply 800 to the mobile communication apparatus. The second power supply 800 temporarily stores the collected state information under the condition of no network, and forwards the temporarily stored state information to the mobile communication device through the first power supply 700 after connecting to the wireless network. It will be appreciated that when the second power supply 800 is in the wireless network connection state, the state information of the power utilization device 200 and/or the remote control power supply is also collected, and the collected state information is forwarded to the mobile communication device in real time through the first power supply 700. The status information of the remote control power supply in this embodiment may include status information of the first power supply 700 and/or the second power supply 800, such as status information of the power, temperature, position, etc. of the corresponding power supply.

As shown in fig. 24, when no wireless network state exists, the automatic acquisition and storage flow of the state information is as follows: in step S1, the acquisition unit of the second power supply 800 acquires status information of the power utilization device and/or the remote control power supply; in step S2, the collected state information is temporarily stored in the storage unit of the second power supply 800; after connecting to the wireless network, the following flows also exist: in step S3, the storage unit of the second power supply 800 transmits the temporarily stored state information to the first power supply 700 through the wireless communication unit of the second power supply 800; in step S4, the first power supply 700 transmits the temporarily stored state information to the mobile communication device through the wireless network; in step S5, the mobile communication device transmits the temporarily stored state information to the cloud end through the wireless network, and the cloud end stores the state information in a classified manner.

As shown in fig. 25, when a wireless network state exists, the automatic acquisition and storage flow of the state information is as follows: in step S10, the acquisition unit of the second power supply 800 acquires status information of the power utilization device and/or the remote control power supply; in step S20, when the wireless network state exists, the collected state information is transmitted to the first power supply 700 through the wireless communication unit of the second power supply 800; in step S30, the first power supply 700 transmits the status information to the mobile communication device through the wireless network; in step S40, the mobile communication device transmits the state information to the cloud end through the wireless network, and the cloud end stores the state information in a classified manner.

The flow of this state information query is shown in fig. 7.

As shown in fig. 26, the flow of executing the control instruction is: in step S100, the mobile communication device transmits a request for a control instruction to the first power supply 700; in step S200, after receiving the control instruction, the first power supply sends the control instruction to the second power supply 800 to execute the control instruction; in step S300, the second power supply 800 transmits status information for executing the control instruction to the mobile communication device via the first power supply 700; in step S400, the mobile communication device transmits the state information of the execution control instruction to the cloud end 300, and the cloud end stores the state information in a classified manner; in addition, the method may further include the step of, in step S500, transmitting the request information of the control instruction to the cloud end 300 by the mobile communication device, and storing the request information in a classified manner by the cloud end.

As shown in fig. 27, the remote control power supply includes a first power supply 700, a second power supply 800, and a third power supply 900, and the third power supply 900 is connected to the power consumption device 200 to supply power to the power consumption device 200.

The first power supply 700 or the second power supply 800 in fig. 27 has a wireless communication unit for implementing wireless communication with a mobile communication device, where the wireless communication unit has at least a communication module. Alternatively, the wireless cellular communication function of the first power supply 700 or the second power supply 800 may need to be activated after the first power supply 700 is electrically connected to the second power supply 800. The manner in which the wireless cellular communication functions of the first power supply 700 and the second power supply 800 are activated is as described in the corresponding portions of the above embodiments.

The functional blocks of the third power supply 900 are shown in fig. 15.

The first power supply 700 or the second power supply 800 of the activated wireless cellular communication function in fig. 27 is directly connected to the mobile communication device in wireless communication, and the first power supply 700 or the second power supply 800 of the activated wireless cellular communication function is configured to receive a control instruction sent from the mobile communication device, forward the control instruction to the third power supply 900, and execute the control instruction by the third power supply 900; and the first power supply 700 or the second power supply 800, which is activated with the wireless cellular communication function, also forwards the status information of the power consumption device 200 and/or the remote control power supply fed back by the third power supply 900 to the mobile communication apparatus. The third power supply 900 temporarily stores the acquired state information in the absence of a network, and forwards the temporarily stored state information to the mobile communication device through the first power supply 700 or the second power supply 800 activated with the wireless cellular communication function after connecting to the wireless network. It will be appreciated that when the third power supply 900 is in the wireless network connection state, the state information of the power consumption device 200 and/or the remote control power supply is also collected, and the collected state information is forwarded to the mobile communication device in real time through the first power supply 700 or the second power supply 800 that activates the wireless cellular communication function. The status information of the remote control power supply in this embodiment may include status information of the first power supply 700 and/or the second power supply 800 and/or the third power supply 900, such as status information of the power, temperature, position, etc. of the corresponding power supply.

As shown in fig. 28, when no wireless network state exists, the automatic acquisition and storage flow of the state information is as follows: in step S1, the acquisition unit of the third power supply 900 acquires status information of the power utilization device or the remote control power supply; in step S2, the collected state information is temporarily stored in the storage unit of the third power supply 900; after connecting to the wireless network, the following flows also exist: in step S3, the storage unit of the third power supply 900 transmits the temporarily stored state information to the first power supply 700 or the second power supply 800 activated with the wireless cellular communication function through the wireless communication unit of the second power supply 800; in step S4, the first power supply 700 or the second power supply 800, which is activated with the wireless cellular communication function, transmits the temporary storage state information to the mobile communication device through the wireless network; in step S5, the mobile communication device transmits the temporary storage status information to the cloud end 300 through the wireless network, and the cloud end 300 stores the status information in a classified manner.

As shown in fig. 29, when a wireless network state exists, the automatic acquisition and storage flow of the state information is as follows: in step S10, the collection unit of the third power supply 900 collects state information of the power utilization device and/or the remote control power supply; in step S20, when the wireless network state exists, the acquired state information is transmitted to the first power supply 700 or the second power supply 800 activated with the wireless cellular communication function through the wireless communication unit of the third power supply 900; in step S30, the first power supply 700 or the second power supply 800, which is activated with the wireless cellular communication function, transmits status information to the mobile communication device through the wireless network; in step S40, the mobile communication device transmits the state information to the cloud end 300 through the wireless network, and the cloud end 300 stores the state information in a classified manner.

The flow of this state information query is shown in fig. 7.

As shown in fig. 30, the flow of executing the control instruction is: in step S100, the mobile communication device transmits a request of a control instruction to the first power supply 700 or the second power supply 800, which is activated with the wireless cellular communication function; in step S200, after receiving the control instruction, the first power supply 700 or the second power supply 800 activated with the wireless cellular communication function sends the control instruction to the third power supply 900 to execute the control instruction; in step S300, the third power supply 900 transmits status information of the execution control instruction to the mobile communication device via the first power supply 700 or the second power supply 800 activated wireless cellular communication function; in step S400, the mobile communication device transmits the state information of the execution control instruction to the cloud end 300, and the cloud end 300 stores the state information in a classified manner; in addition, the method may further include the step of, in step S500, transmitting the request information of the control instruction to the cloud end 300 by the mobile communication device, and storing the request information in a classified manner by the cloud end 300.

According to another aspect of the present invention, a power supply assembly is provided, which may include the remote control power supply of the above-described embodiments.

In the embodiment shown in fig. 1, the remote control power supply 100 directly communicates with the cloud end 300 through a wireless network, and the cloud end 300 is in wireless communication connection with the mobile communication device, and the remote control power supply 100 is in wireless communication connection with the mobile communication device through the cloud end 300.

In the embodiment shown in fig. 9, the remote control power supply is a second power supply 800, the power supply assembly further includes a first power supply 700 (the first power supply 700 may also be referred to as a charging power supply), and the first power supply 700 is configured to be in wireless communication connection with the cloud 300 and be in wireless communication connection with a wireless communication unit of the second power supply 800, so as to implement wireless communication between the second power supply 800 and the cloud 300; wherein the first power supply 700 is capable of charging the second power supply 800. In this embodiment, the second power supply 800 is connected to the cloud 300 via the first power supply 700. In addition, the cloud 300 is in wireless communication connection with the mobile communication device, and the second power supply 800 is in wireless communication connection with the mobile communication device through the first power supply 700 and the cloud 300 in sequence.

In the embodiment shown in fig. 14, where the remote control power source is the third power source 900, the power supply assembly may further include a first power source 700 (the first power source 700 may also be referred to as a charging power source) and a second power source 800 (the second power source 800 may also be referred to as a switching power source), where when the first power source 700 is electrically connected to the second power source 800, a wireless communication function of the first power source 700 or the second power source 800 is activated, such that the first power source 700 or the second power source 800 is wirelessly connected to the cloud 300, and such that the first power source 700 or the second power source 800 is wirelessly connected to a wireless communication unit of the third power source 900, so as to implement wireless communication between the third power source 900 and the cloud 300. In addition, the cloud 300 is in wireless communication connection with the mobile communication device, and the third power supply 900 is in wireless communication connection with the mobile communication device through one of the first power supply 700 and the second power supply 800 and the cloud 300 in sequence.

In the embodiment shown in fig. 19, the remote control power supply 100 directly communicates with the mobile communication device via a wireless network. In addition, the mobile communication device is in wireless communication connection with the cloud 300, and the remote control power supply 100 is in wireless communication connection with the cloud 300 through the mobile communication device.

In the embodiment shown in fig. 23, the remote control power supply is a second power supply 800, and the power supply assembly further includes a first power supply 700 (the first power supply 700 may also be referred to as a charging power supply), where the first power supply 700 is used to be connected in wireless communication with the mobile communication device and is connected in wireless communication with a wireless communication unit of the second power supply 800, so as to implement wireless communication between the second power supply 800 and the mobile communication device; wherein the first power supply 700 is capable of charging the second power supply 800. In this embodiment, the second power supply 800 is adapted to implement wireless communication with the mobile communication device via the first power supply 700. In addition, the mobile communication device is in wireless communication connection with the cloud 300, and the second power supply 800 is in wireless communication connection with the cloud 300 sequentially through the first power supply 700 and the mobile communication device.

In the embodiment shown in fig. 27, where the remote control power source is the third power source 900, the power supply assembly may further include a first power source 700 (the first power source 700 may also be referred to as a charging power source) and a second power source 800 (the second power source 800 may also be referred to as a switching power source), where when the first power source 700 is electrically connected to the second power source 800, a wireless communication function of the first power source 700 or the second power source 800 is activated, such that the first power source 700 or the second power source 800 is wirelessly connected to the mobile communication device, and such that the first power source 700 or the second power source 800 is wirelessly connected to a wireless communication unit of the third power source 900, so as to implement wireless communication between the third power source 900 and the mobile communication device. In addition, the mobile communication device is in wireless communication connection with the cloud 300, and the third power supply 900 is in wireless communication connection with the cloud 300 through one of the first power supply 700 and the second power supply 800 and the mobile communication device in sequence.

In another aspect of the embodiments of the present invention, there is provided an electric device, which may include:

an electricity consumption component; and

the power supply assembly in any of the above embodiments, wherein a remote control power supply of the power supply assembly is in wireless communication connection with the cloud 300; the mobile communication device is configured to send a request for a control command to the cloud 300, so as to trigger the cloud 300 to send the control command to the remote control power supply.

In some embodiments, the power device further comprises a housing, the remote power source being removably mounted to the housing.

The remote control power supply is suitable for an electric tool, such as an electric gardening tool and/or an electric household tool, for example, the electric assembly of the embodiment of the invention may include the electric tool, such as an electric drill, an electric angle grinder, an electric hammer, a sprayer, and the like, where the electric tool may be an electric gardening tool, such as a pruner, a grass trimmer, a chain saw, and the like, or an electric household tool, such as a dust collector, a coffee machine, an electric fan, a juice extractor, and may be other types of electric equipment, such as a glue gun, an air pump, an emergency lamp, and the like, and generally, the electric assembly may refer to an operation device using a secondary battery or a battery pack (such as an energy storage power supply/an energy storage power station) as a power source.

In another aspect of the embodiment of the present invention, an electrical system is provided, which includes a mobile communication device, a cloud end and a power supply assembly in the foregoing embodiment, where the cloud end is in wireless communication connection with the mobile communication device, and a remote control power supply is in wireless communication connection with the mobile communication device via the cloud end, or a remote control power supply of the power supply assembly is in wireless communication connection with the cloud end via the mobile communication device.

In another aspect of the embodiments of the present invention, a method for controlling an electric power consumption system is provided. The power utilization system comprises the remote control power supply and the power utilization device in the embodiment.

The control method of the power utilization system at the mobile communication equipment side can comprise the following steps:

(1) The method comprises the steps that a request of inquiring an instruction is sent to a cloud end, wherein mobile communication equipment is in wireless communication connection with the cloud end, the cloud end is in wireless communication connection with a remote control power supply, when no network exists, the remote control power supply temporarily stores state information of a power utilization device and state information of the remote control power supply, after the remote control power supply is connected with a wireless network, the remote control power supply sends the temporarily stored state information to the cloud end through the wireless network, and the cloud end stores the temporarily stored state information;

(2) And receiving state information corresponding to the query instruction in state information stored in the cloud end and returned by the cloud end aiming at the request of the query instruction.

In some embodiments, the method further comprises: and sending a request of the control instruction to the cloud end to trigger the cloud end to send the control instruction to the remote control power supply, so that the remote control power supply executes the control instruction.

In some embodiments, the status information of the powered device includes one or more of power status information, power off status information, operational status information, location information, remaining power information, temperature information; and/or, the state information of the remote control power supply includes one or more of temperature information, remaining power information, position information, and charging information.

Correspondingly, the embodiment of the invention also provides mobile communication equipment comprising:

the communication device is used for establishing communication with the cloud end through a wireless network;

a processing device for implementing the control method of the power utilization system of the mobile communication equipment side;

and a memory for processing or storing the signals as a physical storage state.

On the cloud side, the control method of the power utilization system may include the following steps:

(1) After the remote control power supply is connected with a wireless network, receiving state information of the power utilization device and state information of the remote control power supply, which are temporarily stored by the remote control power supply when the remote control power supply is not connected with the wireless network, wherein the state information of the power utilization device and the state information of the remote control power supply are transmitted by the remote control power supply through the wireless network;

(2) And storing the received temporarily stored state information.

In some embodiments, at the cloud side, the control method of the power consumption system may further include the following steps:

receiving a request of a query instruction sent by mobile communication equipment, wherein the mobile communication equipment is in wireless communication connection with a cloud;

according to the query instruction, acquiring state information corresponding to the query instruction from state information stored in the cloud;

and sending state information corresponding to the query instruction to the mobile communication equipment. In some embodiments, storing the received temporarily stored state information includes: and classifying and storing the received temporarily stored state information.

In some embodiments, the method further comprises: receiving a request of a control instruction sent by mobile communication equipment; and sending a control instruction to a remote control power supply through a wireless network, so that the remote control power supply executes the control instruction, wherein the control instruction at least comprises a power-on instruction, and the control unit is used for driving the battery or the battery pack to start the power utilization device according to the power-on instruction.

In some embodiments, the status information of the powered device includes one or more of power status information, power off status information, operational status information, location information, remaining power information, temperature information; and/or, the state information of the remote control power supply includes one or more of temperature information, remaining power information, position information, and charging information.

Correspondingly, the embodiment of the invention also provides a cloud end, which comprises the following steps:

the one or more central processing units are used for implementing a control method of the power utilization system at the cloud side;

one or more memories and/or storage devices;

one or more wired or wireless network interfaces.

On the remote control power source side, the control method of the power utilization system can comprise the following steps:

(1) When the remote control power supply supplies electric energy to the power utilization device, the state information of the power utilization device and the state information of the remote control power supply are acquired through an acquisition unit of the remote control power supply;

(2) Under the condition of no network, temporarily storing the state information collected by the acquisition unit through a storage unit of a remote control power supply;

(3) And after the remote control power supply is connected with the wireless network, the temporarily stored state information is sent to the cloud through the wireless network.

In some embodiments, the method further comprises: and receiving a control instruction execution control instruction sent by the mobile communication equipment through the wireless network.

In some embodiments, the status information of the powered device includes one or more of power status information, power off status information, operational status information, location information, remaining power information, temperature information; and/or, the state information of the remote control power supply includes one or more of temperature information, remaining power information, position information, and charging information.

Correspondingly, the embodiment of the invention also provides a remote control power supply, which comprises:

and the control unit is used for implementing a control method of the power utilization system at the remote control power supply side.

The foregoing description of the preferred embodiments of the invention is not intended to be limiting, but rather to enable any modification, equivalent replacement, improvement or the like to be made within the spirit and principles of the invention.

Claims (27)

1. A remote control power supply for an electrical device, comprising:

a battery or battery pack for providing electrical energy to the power device;

the wireless communication unit is used for being in wireless communication connection with the cloud and being in wireless communication connection with the mobile communication equipment;

the control unit is used for receiving a control instruction sent by the mobile communication equipment through the wireless communication unit and executing the control instruction, wherein the control instruction at least comprises a power-on instruction, and the control unit is used for driving the battery or the battery pack to start the power utilization device according to the power-on instruction;

the acquisition unit is used for acquiring state information of the power utilization device and/or state information of the remote control power supply;

the storage unit is used for temporarily storing the state information acquired by the acquisition unit under the condition of no network and sending the state information temporarily stored in the storage unit to the cloud through the wireless communication unit after the wireless communication unit is connected with a wireless network.

2. The remote control power supply of an electric device according to claim 1, wherein the storage unit is a FLASH chip or a random dynamic memory or a cache chip.

3. The remote control power supply of an electric device according to claim 1, wherein the status information of the electric device includes one or more of power status information, power off status information, operation status information, position information, remaining power information, temperature information; and/or the number of the groups of groups,

the state information of the remote control power supply comprises one or more of temperature information, residual electric quantity information, position information and charging information.

4. The remote control power supply of an electric device according to claim 1, wherein the wireless communication unit is in wireless communication with the mobile communication apparatus via the cloud, the control instruction is forwarded to the wireless communication unit via the cloud, and the wireless communication unit sends the control instruction to the control unit; or alternatively, the process may be performed,

the wireless communication unit is in wireless communication with the cloud end through the mobile communication device, and after the wireless communication unit is connected with a wireless network, the state information temporarily stored in the storage unit is sent to the mobile communication device through the wireless communication unit and forwarded to the cloud end through the mobile communication device.

5. The remote control power supply of an electrical device according to claim 4, wherein the control instructions further comprise power off instructions and/or parameter setting instructions;

the control unit is used for driving the battery or the battery pack to close the power utilization device according to the power supply closing instruction and/or carrying out parameter setting on the remote control power supply and/or the power utilization device according to the parameter setting instruction.

6. A power assembly for an electrical device, the power assembly comprising:

a remote control power supply as claimed in any one of claims 1 to 5.

7. The power assembly of an electrical device of claim 6, further comprising:

the charging power supply is in wireless communication connection with the cloud and the mobile communication equipment and is in wireless communication connection with the wireless communication unit of the remote control power supply so as to realize wireless communication between the remote control power supply and the cloud and the mobile communication equipment respectively;

the charging power supply can charge the remote control power supply.

8. The power assembly of an electrical device of claim 7, further comprising:

Switching a power supply;

when the charging power supply is electrically connected with the switching power supply, the wireless communication function of the charging power supply or the switching power supply is activated, so that the charging power supply or the switching power supply is in communication connection with the cloud end and the mobile communication device, and the charging power supply or the switching power supply is in wireless communication connection with the wireless communication unit of the remote control power supply, so that wireless communication between the remote control power supply and the cloud end and the mobile communication device is realized.

9. An electrical device, comprising:

an electricity consumption component; and

the power assembly of any one of claims 6-8, said power assembly configured to provide electrical energy to said power assembly.

10. The electrical device of claim 9, further comprising a housing, wherein the remote power source is removably mounted to the housing.

11. The power device of claim 9, wherein the remote power source is adapted for a power tool.

12. The electrical device of claim 11, wherein the power tool comprises a power gardening tool and/or a power household tool.

13. An electrical power consumption system, comprising:

a mobile communication device;

the cloud end is in wireless communication connection with the mobile communication equipment; and

the power supply assembly of any one of claims 6-8, wherein a remote control power supply of the power supply assembly is in wireless communication connection with the mobile communication device via the cloud, or wherein a remote control power supply of the power supply assembly is in wireless communication connection with the cloud via the mobile communication device.

14. A control method of an electricity utilization system, characterized in that the method is implemented by a mobile communication device, the electricity utilization system comprising a remote control power supply and an electricity utilization device, the remote control power supply being used for providing electric energy to the electricity utilization device; the method comprises the following steps:

the method comprises the steps that a request of inquiring an instruction is sent to a cloud, wherein the mobile communication equipment is in wireless communication connection with the cloud, the cloud is in wireless communication connection with a remote control power supply, when no network exists, the remote control power supply temporarily stores state information of an electric device and state information of the remote control power supply collected by the remote control power supply, after the remote control power supply is connected with a wireless network, the remote control power supply sends the temporarily stored state information to the cloud through the wireless network, and the cloud stores the temporarily stored state information;

And receiving state information corresponding to the query instruction in the state information stored in the cloud end and returned by the cloud end aiming at the request of the query instruction.

15. The method of claim 14, wherein the method further comprises:

and sending a request of a control instruction to the cloud end to trigger the cloud end to send the control instruction to the remote control power supply, so that the remote control power supply executes the control instruction.

16. The method of claim 14, wherein the status information of the powered device includes one or more of power status information, power off status information, operational status information, location information, remaining power information, temperature information; and/or the number of the groups of groups,

the state information of the remote control power supply comprises one or more of temperature information, residual electric quantity information, position information and charging information.

17. A mobile communication device, comprising:

the communication device is used for establishing communication with the cloud end through a wireless network;

processing means for carrying out the method of any one of claims 14 to 16;

and a memory for processing or storing the signals as a physical storage state.

18. The control method of the power utilization system is characterized by being implemented through a cloud, wherein the power utilization system comprises a remote control power supply and a power utilization device, and the remote control power supply is used for providing electric energy for the power utilization device; the method comprises the following steps:

after the remote control power supply is connected with a wireless network, state information of the power utilization device and state information of the remote control power supply, which are acquired by the remote control power supply and are temporarily stored when the remote control power supply is not connected with the wireless network, are received;

and storing the received temporarily stored state information.

19. The method of claim 18, wherein the method further comprises:

receiving a request of a query instruction sent by mobile communication equipment, wherein the mobile communication equipment is in wireless communication connection with the cloud;

acquiring state information corresponding to the query instruction from the state information stored in the cloud according to the query instruction;

and sending state information corresponding to the query instruction to the mobile communication equipment.

20. The method of claim 18, wherein storing the received temporarily stored state information comprises:

And classifying and storing the received temporarily stored state information.

21. The method of claim 18, wherein the method further comprises:

receiving a request of a control instruction sent by mobile communication equipment;

and sending the control instruction to the remote control power supply through a wireless network so that the remote control power supply executes the control instruction, wherein the control instruction at least comprises a power-on instruction, and the control unit is used for driving a battery of the remote control power supply or a battery pack of the remote control power supply to start the power utilization device according to the power-on instruction.

22. The method of claim 18, wherein the status information of the powered device includes one or more of power status information, power off status information, operational status information, location information, remaining power information, temperature information; and/or the number of the groups of groups,

the state information of the remote control power supply comprises one or more of temperature information, residual electric quantity information, position information and charging information.

23. A cloud, comprising:

one or more central processing units for implementing the method of any one of claims 18 to 22;

One or more memories and/or storage devices;

one or more wired or wireless network interfaces.

24. A control method of an electric power consumption system, characterized in that the electric power consumption system comprises a remote control power supply and an electric power consumption device, wherein the remote control power supply is used for providing electric power for the electric power consumption device, and the method is implemented through the remote control power supply; the method comprises the following steps:

when the remote control power supply supplies electric energy to the power utilization device, acquiring state information of the power utilization device and state information of the remote control power supply through an acquisition unit of the remote control power supply;

under the condition of no network, temporarily storing the state information collected by the acquisition unit through a storage unit of the remote control power supply;

and after the remote control power supply is connected with a wireless network, the temporarily stored state information is sent to the cloud through the wireless network.

25. The method of claim 24, wherein the method further comprises:

receiving a control instruction sent by mobile communication equipment through a wireless network;

and executing the control instruction.

26. The method of claim 25, wherein the status information of the powered device includes one or more of power status information, power off status information, operational status information, location information, remaining power information, temperature information; and/or the number of the groups of groups,

The state information of the remote control power supply comprises one or more of temperature information, residual electric quantity information, position information and charging information.

27. A remote control power supply, comprising:

control unit for implementing the method according to any one of claims 24 to 26.

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