CN116683620A - Power system, computing method thereof and instruction execution method - Google Patents

Abstract

The application provides a power system, a calculation method thereof and an instruction execution method thereof, wherein the power system comprises: the intelligent terminals are used for generating triggering conditions and/or executing instructions; the energy storage power supply is in wireless communication with the intelligent terminal and is used for generating an execution instruction and controlling the intelligent terminal to execute the instruction; the energy storage power supply includes: the battery module is used for supplying power to the intelligent terminal; the inversion module is used for converting direct current output by the battery module into alternating current; the wireless communication module is used for wirelessly communicating with the intelligent terminal and exchanging communication information; and the power calculation module is used for generating corresponding execution instructions according to the trigger conditions and the execution actions input by the user and controlling the execution of the instructions. According to the application, the energy storage power supply and the intelligent terminals are in wireless communication at the same time, so that a user can create a scene according to the needs of the user, the interestingness of outdoor camping is improved, and meanwhile, the user can control the intelligent terminals in wireless communication with the energy storage power supply through the power calculation module of the energy storage power supply.

Description

Power system, computing method thereof and instruction execution method

Technical Field

The application relates to a power system, a computing method thereof and an instruction execution method.

Background

The traditional power utilization device does not have a networking communication function, when a user needs to operate the power utilization device to work, the user needs to manually touch keys on the power utilization device, the power utilization device is not intelligent to use, particularly in outdoor leisure scenes, and the plurality of power utilization devices need to be respectively touched by the user to enable the plurality of power utilization devices to achieve the respective functions, so that linkage of the plurality of power utilization devices cannot be achieved.

Disclosure of Invention

The application provides a power system, a computing method thereof and an instruction execution method.

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

the present application provides a computing system comprising:

the intelligent terminals are used for generating triggering conditions and/or executing instructions; and

the energy storage power supply is in wireless communication with the intelligent terminal and is used for generating an execution instruction and controlling the intelligent terminal to execute the instruction;

the energy storage power supply includes:

the battery module is used for supplying power to the intelligent terminal;

the inversion module is used for converting direct current output by the battery module into alternating current;

the wireless communication module is used for wirelessly communicating with the intelligent terminal and exchanging communication information; and

the power calculation module is used for generating corresponding execution instructions according to the trigger conditions and the execution actions input by the user and controlling the execution of the instructions.

Further, the computing power module includes:

the processing unit is used for generating an execution instruction, processing information and controlling the execution of the instruction; and

and the storage unit is used for storing the trigger condition, the execution action and the execution instruction.

Further, the energy storage power supply further includes:

and the input module is used for inputting the trigger condition and executing the action by the user.

Further, the triggering condition and the information of the execution action are acquired from the cloud or the user terminal.

Further, the power calculation module is arranged in the shell of the energy storage power supply.

Further, the power calculation module is arranged outside the shell of the energy storage power supply.

Further, the power calculation module is detachably mounted on the energy storage power supply.

Further, the intelligent terminal is an outdoor camping device.

Further, the intelligent terminal at least comprises:

the electric equipment is used for working; and

the battery pack is used for supplying power to the electric equipment;

the electric equipment and/or the battery pack are/is provided with a wireless communication module, and the wireless communication module is used for wireless communication with the energy storage power supply.

Further, the battery pack is detachably mounted on the electric equipment.

The present application provides a computing system comprising:

the intelligent terminals are used for generating triggering conditions and/or executing instructions;

the energy storage power supply is used for wirelessly communicating with the intelligent terminal and exchanging information; and

the outdoor computing equipment is used for generating an execution instruction and controlling the instruction to execute;

the energy storage power supply includes:

the battery module is used for supplying power to the intelligent power supply;

the inversion module is used for converting direct current output by the battery module into alternating current; and

the wireless communication module is used for wirelessly communicating with the intelligent terminal and the outdoor computing equipment;

the outdoor power computing device includes:

the power calculation module is used for generating corresponding execution instructions according to the trigger conditions and the execution actions input by the user and controlling the execution of the instructions; and

and the wireless communication module is used for wirelessly communicating with the energy storage power supply.

Further, the computing power module includes:

the processing unit is used for generating an execution instruction; and

and the storage unit is used for storing the trigger condition, the execution action and the execution instruction.

Further, the energy storage power supply further includes:

and the input module is used for inputting the trigger condition and executing the action by the user.

Further, the outdoor computing device further includes:

and the input module is used for inputting the trigger condition and executing the action by the user.

Further, the outdoor computing device further includes:

and the battery module is used for providing electric energy for the power calculation module and the wireless communication module.

The application provides a calculation method of a calculation system, which is applied to the calculation system and comprises the following steps:

a setting step, wherein a user inputs a trigger condition and executes an action;

and in the calculation step, the calculation module generates corresponding execution instructions according to the trigger conditions and the execution actions, and stores the trigger conditions, the execution actions and the execution instructions.

Further, the computing method further includes:

and defining, namely defining the intelligent terminal generating the triggering condition as a triggering terminal by the power calculation module, and defining the intelligent terminal executing the instruction as an executing terminal.

The application provides an instruction execution method of a computing power system, which comprises the following steps:

a communication connection step, wherein the energy storage power supply is in wireless communication with the intelligent terminal;

a condition identification step, wherein the calculation module identifies whether a triggering condition exists in the state information sent from the triggering terminal;

an instruction reading step, wherein if the instruction exists, the force calculation module acquires an execution instruction corresponding to the trigger condition;

an instruction transmission step of transmitting an execution instruction to an execution terminal;

and the instruction execution step, wherein the execution terminal executes the action after receiving the execution instruction.

Further, the instruction execution method further comprises:

and a terminal identification step, wherein before the condition identification step is executed, the power calculation module identifies whether a triggering terminal and an executing terminal exist in the intelligent terminals which are in wireless communication with the energy storage power supply.

According to the technical scheme provided by the embodiment of the application, the energy storage power supply and the intelligent terminals are in wireless communication at the same time, so that a user can create a scene according to own needs, the interestingness of outdoor camping is improved, and meanwhile, the user can conveniently control all the intelligent terminals in wireless communication with the energy storage power supply through the power calculation module of the energy storage power supply.

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 application as claimed.

Drawings

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

FIG. 1 is a schematic diagram of a functional module of a computing system according to an embodiment of the present application;

fig. 2 is a schematic structural diagram of a battery module of an intelligent terminal according to an embodiment of the present application detachably installed in an electric fan;

fig. 2 is a schematic structural diagram of a battery module of an intelligent terminal according to an embodiment of the present application detachably installed in an electric fan;

fig. 3 is a schematic communication diagram of communication information transmitted between an energy storage power supply and a light string through an acoustic relay according to an embodiment of the present application;

FIG. 4 is a schematic diagram of a functional module of an energy storage power supply according to an embodiment of the present application;

FIG. 5 is a schematic diagram of a functional module of an energy storage power supply according to an embodiment of the present application having a plurality of groups of battery cells;

FIG. 6 is a schematic diagram of a plurality of computing systems formed by an energy storage power supply and a plurality of intelligent terminals according to an embodiment of the present application;

fig. 7 is a schematic diagram of an energy storage power supply according to an embodiment of the present application receiving trigger conditions and information about execution actions sent from a cloud or a mobile terminal;

FIG. 8 is a schematic diagram of an energy storage power supply, a projector, a sound device and a light string forming a computing system according to an embodiment of the present application;

FIG. 9 is a schematic diagram of an energy storage power supply and a computing system composed of a sensor, a camping light and a music player according to an embodiment of the present application;

FIG. 10 is a flowchart illustrating a computing method of a computing system according to an embodiment of the present application;

FIG. 11 is a flowchart illustrating a method for executing instructions in a computing system according to an embodiment of the present application;

FIG. 12 is a schematic diagram of a functional block diagram of another computing system according to an embodiment of the present application;

FIG. 13 is a schematic diagram of functional modules of an outdoor computing device according to an embodiment of the present application;

fig. 14 is a schematic diagram of an energy storage power supply and an outdoor computing system including a projector, a sound and a light string according to an embodiment of the present application.

Fig. 15 is a schematic structural diagram of an outdoor power equipment according to an embodiment of the present application directly electrically connected to an energy storage power source.

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 application. Rather, they are merely examples of apparatus and methods consistent with aspects of the application 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 application. 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 application. 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.

Referring to the schematic of the functional modules of the computing system shown in fig. 1, the computing system enables a user to create a scene required by the user and control scene linkage, and the computing system comprises:

the intelligent terminals 200 are used for generating triggering conditions and/or executing instructions; and

the energy storage power supply 100 is in wireless communication with the intelligent terminal 200, and is used for generating an execution instruction according to the received trigger condition and the execution action and controlling the execution of the instruction;

the energy storage power supply 100 may provide electric energy to the intelligent terminal.

The intelligent terminal 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 outdoor security sensing device, such as a body sensor, a wind-light rain sensor, an emergency button, an acoustic alarm, or an outdoor lamp, such as a camping lamp, an atmosphere lamp, a light string, or other types of intelligent terminals, such as an outdoor fan, an electric baking tray, an electric blanket, a vehicle-mounted refrigerator, or the like, and in general, the intelligent terminal 200 may generally refer to a device with a wireless communication module, and may be in wireless communication with the energy storage power supply.

The intelligent terminal 200 at least includes:

a powered device 21 for performing an action; and

battery pack 22 is used to provide power to the powered device.

The electric device 21 includes a housing, the battery pack 22 may be disposed in the housing of the electric device 21, and the battery pack 22 may be detachably mounted on the intelligent terminal 21, that is, the battery pack is detachably mounted on the electric device, for example, the battery pack 22 is detachably mounted in the electric fan 21, as shown in fig. 2.

When the battery pack is connected with the electric equipment physically, the electric equipment is connected with the battery pack in a communication mode in a protocol mode, namely when the battery pack is installed in the electric equipment, the battery pack sends an identification code to the electric equipment, the electric equipment receives the identification code and gives a feedback signal to the battery pack, the battery pack confirms, if true, the battery pack sends a working code to the electric equipment, the electric equipment is started, and if false, the battery pack does not discharge the electric equipment.

The battery pack and/or the electric equipment are provided with wireless communication modules for wireless communication with the energy storage power supply.

Preferably, the wireless communication module is disposed in the battery pack and is used for wirelessly communicating with the energy storage power supply to interact information, such as state information or control instruction information of the power supply and/or the electric equipment.

And a relay unit is further arranged in the wireless communication module of the intelligent terminal and used for restoring and forwarding communication information, namely when the distance between the energy storage power supply and the intelligent terminal 1 exceeds the wireless communication distance of the energy storage power supply, and when the intelligent terminal 2 is arranged between the energy storage power supply and the intelligent terminal 1, the information which needs to be transmitted by the energy storage power supply and the intelligent terminal 1 is relayed through the intelligent terminal 2. For example, a sound box is arranged between the energy storage power supply and the light string, and when the position of the light string exceeds the communication distance of the energy storage power supply, the energy storage power supply forwards a control instruction for controlling the light string to be turned on to the light string through the sound box, as shown in fig. 3.

Referring to the functional block diagram of the energy storage power supply shown in fig. 4, the energy storage power supply 100 includes:

a battery module for charging the intelligent terminal 200;

the input module is used for setting triggering conditions and executing actions by a user;

the power calculation module is used for generating an execution instruction according to the received trigger condition and the execution action and controlling the instruction to execute; and

the wireless communication module is configured to wirelessly communicate with a plurality of intelligent terminals 200.

The above battery module has at least one group of battery cells, which may be formed by connecting a plurality of batteries 10 in series or in parallel with each other, and the batteries may be 21700 batteries, and other types of batteries, such as 18650 batteries, may be used as shown in fig. 5.

The above wireless communication module at least includes a communication unit for wireless communication with the intelligent terminal, where the communication unit may be a non-cellular type, such as: preferably, the communication unit is bluetooth, that is, bluetooth wireless communication is adopted between the energy storage power supply and the intelligent terminal.

The energy storage power supply further includes:

and the inversion module is used for converting the direct current output by the battery module into alternating current so as to supply power to the intelligent terminal driven by the alternating current.

The shell of the energy storage power supply is provided with a direct current discharge interface and an alternating current discharge interface, the direct current discharge interface is directly and electrically connected with the battery module to supply power to the intelligent terminal driven by direct current, and the alternating current discharge interface is electrically connected with the battery module through the inversion module to supply power to the intelligent terminal driven by alternating current.

The computing power module comprises:

the processing unit is used for generating an execution instruction associated with the trigger condition and the execution action; and

the storage unit is used for storing the trigger conditions, the execution actions and the execution instructions.

The power calculation module can be arranged in the shell of the energy storage power supply, can be arranged outside the shell of the energy storage power supply, can be detachably arranged on the energy storage power supply, and is electrically connected with the energy storage power supply when being arranged on the energy storage power supply, and is in communication connection with the energy storage unit to exchange data.

The trigger conditions can be 1 or more, when a plurality of trigger conditions are set, the trigger conditions can be all triggers and sequentially triggered, and can also be any trigger, and each trigger condition comprises an intelligent terminal for generating the trigger condition and trigger content; after the trigger conditions 1 and 2 are triggered, the processing unit starts to get corresponding execution instructions from the storage unit, for example, a preset picture appears in the pictures put in the projector, and the clock time is 18 points later; the sequential triggering is that after the triggering condition 1 and the triggering condition 2 occur in a certain sequence, the processing unit starts to go to the storage unit to acquire corresponding execution instructions, for example, after the time is identified as 23 points, the outdoor temperature is identified to be lower than 26 ℃; any trigger, that is, any trigger condition of trigger condition 1 and trigger condition 2 occurs, the processing unit will start to acquire a corresponding execution instruction from the storage unit, for example, the picture projected by the projector appears in picture 1 or picture 2.

The number of the execution actions can be 1 or more, when a plurality of execution actions are set, the execution actions can be executed simultaneously or sequentially, and each execution action comprises an intelligent terminal for executing the instruction and execution content; wherein, the simultaneous execution is that the execution of the action 1 and the execution of the action 2 are simultaneously executed, for example, the flashing of the lamp string is carried out when the sound volume is increased; the sequential execution, i.e. executing the action 1 and executing the action 2, is to execute the actions in a certain sequence, for example, firstly turning on the camping lights in the tent and then turning on the music player.

The power calculation module marks the intelligent terminal generating the triggering condition as a triggering terminal, marks the intelligent terminal executing the instruction as an executing terminal, and forms an ad hoc network system 300 by the triggering terminal, the executing terminal and the energy storage power supply which are related in the same executing instruction, wherein each ad hoc network system comprises at least one triggering terminal, at least one executing terminal and the energy storage power supply 100, and the executing terminal in one ad hoc network system may be the triggering terminal in the other ad hoc network system; for example, the sensor, the camping light and the energy storage power supply form a power system 1, the camping light, the music player and the energy storage power supply form a power system 2, when the sensor detects that a person enters the tent, the camping light is turned on, and then the music player is turned on after the camping light is turned on, as shown in fig. 6.

After receiving the data information sent by the trigger terminal, the processing unit identifies whether a trigger condition exists in the data information; if the trigger condition exists, acquiring an execution instruction associated with the trigger condition from a storage unit, acquiring information of a corresponding execution terminal, and transmitting the corresponding control instruction to the execution terminal through a wireless communication module so as to enable the execution terminal to execute actions; if not, directly uploading or storing the data information.

The processing unit is further used for identifying whether a trigger terminal and an execution terminal corresponding to the same execution instruction exist in the power computing system in wireless communication with the energy storage power supply, classifying the information of the trigger terminal and the information of the execution terminal together with the trigger condition, the execution action and the execution instruction if the trigger terminal and the execution terminal exist, storing the information into the storage unit, and sending the information without the corresponding intelligent terminal to a user if the information is not exist, so that the user can add the corresponding intelligent terminal in the power computing system.

The input module can be arranged on the energy storage power supply for user input, the input mode can be defined by the user, and the input module can also be a preset option for the user to select; of course, the input module may not be set on the energy storage power supply, but the trigger condition and the information of the execution action sent from the cloud or the mobile communication device may be received, as shown in fig. 7.

For example, when a user camps with an energy storage power supply, a projector, a sound and a light string, and the user adopts the projector to play a movie, the projector, the sound and the light string are firstly in wireless communication with the energy storage power supply in a Bluetooth mode to form computing power, the user inputs a trigger condition and an execution action through an input module arranged on the energy storage power supply, for example, when the input trigger condition is that the Harybolt appears in a picture played by the projector, the execution action is to raise the volume of the sound, the light string is made to flash, after the computing power module receives the trigger condition and the execution action, an execution instruction associated with the trigger condition and the execution action is generated, the trigger condition, the execution action and the execution instruction are stored in a storage unit, meanwhile, whether the projector, the sound and the light string exist in an intelligent terminal in communication connection with the energy storage power supply or not is identified, then the projector is played, when the Harybolt appears in the picture played by the projector, the energy storage power supply processes state information sent by the projector, if the trigger condition appears, the corresponding execution instruction is obtained in the storage unit, the relevant execution instruction is sent to the sound and the light string after the trigger condition is received, and the sound string is connected to the sound string, and the sound string is made to flash, and the flash is shown in a serial connection figure after the instruction is started.

For example, the user carries an energy storage power supply, a sensor, a camping lamp and a music player, the user installs the energy storage power supply, the camping lamp and the music player in a tent, the sensor is installed at a door of the tent, the energy storage power supply, the sensor, the camping lamp and the music player form an ad hoc network, the user inputs a triggering condition and an executing action through an input module, for example, the input triggering condition 1 is that the sensor monitors that a person enters the tent, the executing action 1 is that the camping lamp is started, the triggering condition 2 is that the camping lamp is started, the executing action 2 is that the music player is started so as to play music, after the two sets of triggering conditions and the executing action are received by the energy storage power supply, an executing instruction is generated and stored in a storage unit, meanwhile, whether an intelligent terminal in wireless communication with the energy storage power supply exists or not is checked, if the sensor, the camping lamp and the music player exist, the executing instruction can be executed, and if the sensor does not exist, the user is informed to check wireless communication connection between the intelligent terminal and the energy storage power supply; the power calculation module identifies the state information transmitted by the sensor, identifies whether the state information exists in the triggering condition, acquires an execution instruction in the storage unit, and sends the corresponding instruction to the camping lamp, the camping lamp is started after receiving the instruction and sends the state information for starting the camping lamp to the energy storage power supply, the energy storage power supply receives the state information for identification, acquires the execution instruction in the storage unit after identifying the triggering condition for starting the camping lamp, and sends the instruction to the music player, and the music player starts to play music after receiving the instruction, as shown in fig. 9.

Referring to fig. 10, a method for calculating scene linkage of an energy storage power supply includes:

step S10, a user inputs trigger conditions and execution actions through an input module of the energy storage power supply;

s20, generating corresponding execution instructions after the power calculation module of the energy storage power supply receives the trigger conditions and the execution actions, and storing the corresponding execution instructions in a storage unit;

and a defining step S30, wherein the energy storage power supply defines the intelligent terminal generating the triggering condition as a triggering terminal, defines the intelligent terminal executing the instruction as an executing terminal and stores the executing terminal into a storage unit.

Referring to a method for executing instructions in linkage of a scenario of an energy storage power supply shown in fig. 11, the method for executing instructions includes:

a communication connection step S100, wherein the energy storage power supply is simultaneously in wireless communication with a plurality of intelligent terminals;

a terminal identification step S200, wherein the energy storage power supply identifies whether the triggering terminal and/or the executing terminal exist in the intelligent terminal in wireless communication with the energy storage power supply;

step S300 of condition identification, wherein an energy storage power supply receives state information sent by a trigger terminal, and a calculation module identifies whether a trigger condition exists in the state information;

an instruction reading step S400, if yes, acquiring an execution instruction and information of an execution terminal associated with the trigger condition from a storage unit;

an instruction transmission step S500, wherein the control instruction is sent to a corresponding execution terminal;

and the instruction execution step S600 is that the execution terminal executes the control instruction after receiving the control instruction.

Of course, the step S200 includes the steps of:

step S201, if there is a trigger terminal and/or an execution terminal, executing the step S300;

step S202, if there is no trigger terminal and/or execution terminal, notifying the user, adding missing trigger terminal and/or execution terminal, and re-executing step S200.

When the step S300 is executed, if a trigger condition is not present, the state information is stored.

Of course, the power calculation module may be disposed outside the energy storage power supply, and in wireless communication with the energy storage power supply, that is, a housing is disposed outside the power calculation module, so as to form an independent outdoor power calculation device 400, and a wireless communication module is disposed in the housing of the power calculation device 400, so as to wirelessly communicate with the energy storage power supply.

Referring to the functional block diagram of another computing system shown in fig. 12, the computing system comprises:

the intelligent terminals 200 are used for generating triggering conditions and/or executing instructions;

the energy storage power supply 100 is in wireless communication with the intelligent terminal 200 and the outdoor power computing equipment; and

the outdoor computing device 400 is configured to generate an execution instruction according to the received trigger condition and the execution action, and control the execution of the instruction.

The energy storage power supply can provide electric energy for the intelligent terminal and the outdoor power computing equipment.

As shown in fig. 13, the outdoor computing device 400 includes:

the power calculation module is used for generating an execution instruction; and

and the wireless communication module is used for wirelessly communicating with the energy storage power supply.

The power calculation module comprises:

the processing unit is used for generating an execution instruction associated with the trigger condition and the execution action; and

the storage unit is used for storing the trigger conditions, the execution actions and the execution instructions.

The outdoor computing device 400 further includes:

and the input module is used for inputting trigger conditions and executing actions to the user.

The outdoor computing equipment generates an execution instruction according to the triggering condition and the execution action and directly stores the execution instruction into the storage unit, namely, a user directly inputs the triggering condition and the execution action on the outdoor computing equipment.

Of course, an input module may also be provided on the energy storage power supply for the user to input the trigger condition and perform the action. The outdoor power computing equipment generates an execution instruction according to the transmitted triggering condition and the information of the execution action and stores the execution instruction in the storage unit.

When the instruction is executed, after the energy storage power supply receives the state information of the trigger terminal, the energy storage power supply sends the state information to the outdoor power computing equipment, the outdoor power computing equipment identifies the state information, whether the triggering condition exists in the state information or not is identified, if so, the processing unit acquires a corresponding execution instruction from the storage unit, and sends the execution instruction to the energy storage power supply.

The storage unit is of large capacity, and can be used for storing the state information of the intelligent terminal and the energy storage power supply, and the outdoor computing equipment can be in wireless communication with the mobile terminal, so that a user can access and inquire the information in the storage unit in real time, and the outdoor computing equipment can be used as a network memory at the same time.

The outdoor computing device 400 may further include:

and the battery module is used for providing electric energy for the power calculation module and the wireless communication module, namely, the outdoor power calculation equipment can provide electric energy for the power calculation module without connecting a power supply, and cordless work is realized.

Of course, the outdoor power computing device 400 may not be provided with a battery module, but is directly and electrically connected to an energy storage power supply, that is, the energy storage power supply is used to supply power to the outdoor power computing device, specifically, the energy storage power supply 100 may be provided with a discharging interface 11, a charging connector capable of being connected to the discharging interface is provided on the outdoor power computing device, when the charging connector of the outdoor power computing device is plugged into the discharging interface of the energy storage power supply, the outdoor power computing device and the energy storage power supply realize communication through a communication protocol, as shown in fig. 15, the charging connector on the outdoor power computing device can be hinged, so that the charging connector can be hidden on the housing, and damage to the charging connector is avoided.

The foregoing description of the preferred embodiments of the application 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 application.

Claims (19)

1. A computing system, the computing system comprising:

the intelligent terminals are used for generating triggering conditions and/or executing instructions; and

the energy storage power supply is in wireless communication with the intelligent terminal and is used for generating an execution instruction and controlling the intelligent terminal to execute the instruction;

the energy storage power supply includes:

the battery module is used for supplying power to the intelligent terminal;

the inversion module is used for converting direct current output by the battery module into alternating current;

the wireless communication module is used for wirelessly communicating with the intelligent terminal and exchanging communication information; and

the power calculation module is used for generating corresponding execution instructions according to the trigger conditions and the execution actions input by the user and controlling the execution of the instructions.

2. The computing power system of claim 1, wherein the computing power module comprises:

the processing unit is used for generating the execution instruction, processing information and controlling the execution of the instruction; and

and the storage unit is used for storing the trigger condition, the execution action and the execution instruction.

3. The computing power system of claim 1, wherein the stored energy power source further comprises:

and the input module is used for inputting the trigger condition and executing the action by a user.

4. The computing power system of claim 1, wherein the trigger condition and information to perform an action are collected from a cloud or a user terminal.

5. The power computing system of claim 1, wherein the power computing module is disposed within a housing of the energy storage power source.

6. The computing power system of claim 1, wherein the computing power module is disposed outside of a housing of the energy storage power source.

7. The computing power system of claim 6, wherein the computing power module is removably mounted to the stored energy power source.

8. The computing power system of claim 1, wherein the intelligent terminal is an outdoor camping device.

9. The computing power system of claim 1 or 8, wherein the intelligent terminal comprises at least:

the electric equipment is used for working; and

the battery pack is used for supplying power to the electric equipment;

the electric equipment and/or the battery pack are/is provided with a wireless communication module, and the wireless communication module is used for wirelessly communicating with the energy storage power supply.

10. The computing power system of claim 9, wherein the battery pack is removably mounted to the powered device.

11. A computing system, characterized by: the computing system includes:

the intelligent terminals are used for generating triggering conditions and/or executing instructions;

the energy storage power supply is used for wirelessly communicating with the intelligent terminal and exchanging information; and

the outdoor computing equipment is used for generating an execution instruction and controlling the instruction to execute;

the energy storage power supply includes:

the battery module is used for supplying power to the intelligent power supply;

the inversion module is used for converting direct current output by the battery module into alternating current; and

the wireless communication module is used for wirelessly communicating with the intelligent terminal and the outdoor computing power equipment;

the outdoor computing device includes:

the power calculation module is used for generating corresponding execution instructions according to the trigger conditions and the execution actions input by the user and controlling the execution of the instructions; and

and the wireless communication module is used for wirelessly communicating with the energy storage power supply.

12. The computing power system of claim 11, wherein the computing power module comprises:

the processing unit is used for generating the execution instruction; and

and the storage unit is used for storing the trigger condition, the execution action and the execution instruction.

13. The computing power system of claim 11 or 12, wherein the stored energy power source further comprises:

and the input module is used for inputting the trigger condition and the execution action by a user.

14. The computing power system of claim 11, wherein the outdoor computing power equipment further comprises:

and the input module is used for inputting the trigger condition and the execution action by a user.

15. The computing power system of claim 11, wherein the outdoor computing power equipment further comprises:

and the battery module is used for providing electric energy for the power calculation module and the wireless communication module.

16. A calculation method of a calculation force system is characterized in that: the computing method is applied to the computing power system of any one of claims 1 to 15, comprising:

a setting step, wherein a user inputs a trigger condition and executes an action;

and a calculation step, wherein the calculation module generates corresponding execution instructions according to the trigger conditions and the execution actions and stores the trigger conditions, the execution actions and the execution instructions.

17. The computing method of the computing power system of claim 16, wherein: the computing method further comprises the following steps:

and defining, namely defining the intelligent terminal generating the triggering condition as a triggering terminal by the power calculation module, and defining the intelligent terminal executing the instruction as an executing terminal.

18. An instruction execution method of a computing power system is characterized in that: the instruction execution method comprises the following steps:

a communication connection step, wherein the energy storage power supply is in wireless communication with the intelligent terminal;

a condition identification step, wherein a calculation module identifies whether a trigger condition exists in the state information sent from the trigger terminal;

an instruction reading step, wherein if the instruction exists, the computing power module acquires an execution instruction corresponding to the triggering condition;

an instruction transmission step of transmitting the execution instruction to an execution terminal;

and the instruction execution step, wherein the execution terminal executes the action after receiving the execution instruction.

19. The method of instruction execution for a computing power system of claim 18, wherein: the instruction execution method further comprises the following steps:

and a terminal identification step, wherein before the condition identification step is executed, the power calculation module identifies whether a triggering terminal and an executing terminal exist in the intelligent terminals which are in wireless communication with the energy storage power supply.