CN120109967A - Multifunctional charging device - Google Patents

Abstract

The present invention provides a multifunctional charging device. The charging device comprises: a first shell and at least one second shell rotatably connected to the first shell; the projection area of the outer contour of the first shell is greater than a set value, and a battery module and a data storage module are arranged in the first shell; a first interface is arranged on at least one second shell; one end of the battery module is connected to an external power supply through the first interface, and is used to receive power from the external power supply; the other end of the battery module is connected to the data storage module, and is used to output power to the data storage module; the data storage module is connected to an external electronic device through a connection bus, and is used to read and write data with the external electronic device; the battery module is also used to output power to the external electronic device through the connection bus. The present invention realizes the supporting function through the two parts of the rotatably connected shell, which can be used as a bracket for electronic equipment, and can integrate large-capacity data storage and portable charging functions, which is convenient for users to use.

Description

Multifunctional charging equipment

Technical Field

The invention relates to the technical field of chargers, in particular to a multifunctional charging device.

Background

Various charging devices exist in the market currently, and can be used for charging computers, mobile phones, tablets and the like. However, the conventional charging device can only realize the functions of storing electric quantity and charging the electronic device, and has relatively large volume. This results in the user having to carry about each exit, but the functions they implement are relatively limited and inconvenient to use. Therefore, designing a multifunctional charging device is a current problem to be solved.

Disclosure of Invention

In order to at least partially solve the problems of the prior art, the present invention provides a multifunctional charging device. The shell connected through the rotation of the two parts realizes the supporting function, can be used as a bracket of electronic equipment, can integrate the functions of large-capacity data storage and portable charging, and is convenient for users to use.

The invention provides multifunctional charging equipment which comprises a first shell and at least one second shell rotationally connected with the first shell, wherein the projection area of the outer contour of the first shell is larger than a set value, and a battery module and a data storage module are arranged in the first shell;

One end of the battery module is connected with an external power supply through the first interface and is used for accessing electric quantity from the external power supply, and the other end of the battery module is connected with the data storage module and is used for outputting the electric quantity to the data storage module;

The data storage module is connected with external electronic equipment through a connecting bus and is used for reading and writing data with the external electronic equipment; the battery module is also used for outputting electric quantity to the external electronic equipment through the connecting bus.

The first shell is in a flat plate shape, and the second shell is in a strip shape, wherein in the length direction of the second shell, the length of the first shell is larger than a first set value, and the length of the second shell is larger than a second set value;

One end of the second shell is connected to the first shell through a rotating shaft, the second shell is rotatable between a first position and a second position and is respectively clamped and fixed with the first shell in a plurality of angles between the first position and the second position, wherein if the second shell is positioned at the first position, an included angle between the first shell and the second shell is zero, so that the first shell and the second shell are positioned on the same plane board, and if the second shell is positioned at the second position, the included angle between the first shell and the second shell is the maximum clamping angle.

The rotating shaft comprises a bearing, wherein a through hole is formed in the bearing;

The charging equipment further comprises a power input line, one end of the power input line is connected with the first interface, and the other end of the power input line penetrates through a through hole of the bearing to be connected with the battery module so as to input electric quantity of an external power supply into the battery module.

The bearing comprises an inner ring and an outer ring which are matched with each other, wherein the outer ring is sleeved outside the inner ring;

And in the rotating process of the first shell or the second shell, the tooth structures of the inner ring and the outer ring are sequentially meshed, wherein the second shell is clamped and fixed with the first shell in the meshed state.

Illustratively, one side of the first housing is provided with an opening;

The charging equipment further comprises a connecting bus, wherein the connecting bus extends out of the shell through the opening to be connected with external electronic equipment, the connecting bus comprises a data line and a power output line, the data storage module is connected with the external electronic equipment through the data line, and the battery module is connected with the external electronic equipment through the power output line;

Correspondingly, a docking station is also arranged on the side surface where the opening is arranged.

Illustratively, the first panel of the first housing is provided with a magnetic structure;

A clamping mechanism is arranged on the second panel of the first shell and is used for clamping the film keyboard; the clamping mechanism is provided with a trigger button, and the trigger button is used for triggering the clamping mechanism to be in a clamping or non-clamping state when external force is applied;

the first panel and the second panel are two opposite surfaces on the first shell.

The charging equipment further comprises a first display screen and a second display screen which are arranged on the second shell, wherein a state monitoring module and a main control module are arranged in the first shell;

The state monitoring module comprises an electric signal monitoring unit connected with the battery module, wherein the electric signal monitoring unit is used for monitoring the voltage and/or the current of the battery module in real time, and the main control module is used for acquiring the voltage and/or the current from the state monitoring module and controlling the first display screen to display the acquired voltage and/or current;

The state monitoring module further comprises an energization timing unit connected with the data storage module, wherein the energization timing unit is used for timing the energization time of the data storage module, and the main control module is further used for obtaining the energization time of the data storage module from the state monitoring module and controlling the second display screen to display the energization time.

Illustratively, the charging apparatus further comprises a fingerprint input module;

The fingerprint input module is used for acquiring fingerprint information of a user;

The main control module is further configured to obtain user fingerprint information from the fingerprint input module, perform authority comparison analysis on the user fingerprint information to obtain a user authority determination result, open an access authority to the data storage module if the user authority determination result is authority, and close the access authority to the data storage module if the user authority determination result is non-authority.

Illustratively, the charging apparatus further comprises a power input module;

The main control module is further used for determining corresponding target power according to the power adjustment instruction when the power adjustment instruction is acquired based on the power input module, or determining the use power of the external electronic device as the target power when the fact that the external electronic device is connected in and the difference value of the use power of the external electronic device and the use power of the charging device exceeds a set threshold value is monitored, and adjusting working current to control the charging device to operate according to the target power.

Illustratively, the master control module is further configured to perform the steps of:

Generating at least one data calculation subtask and a data sequence subtask corresponding to the at least one data calculation subtask according to the current running state of the charging equipment, wherein the data calculation subtask comprises a data calculation subtask for calculating the use state data and/or storage data of the data storage module;

Processing each data computing subtask to obtain a computing result of each data computing subtask, and processing each data sequence subtask corresponding to each data computing subtask to obtain processing result data of each data sequence subtask;

And downloading the processing result data to a preset storage space, wherein the preset storage space is a storage space in the data storage module.

The multifunctional charging equipment comprises a first shell and a second shell which are connected in a rotating way, wherein the projection area of the outer outline of the first shell is larger than a set value, the multifunctional charging equipment can play a role of supporting electronic equipment and can be used as a bracket of the electronic equipment, and meanwhile, the charger not only comprises a battery module, but also comprises a data storage module, and can integrate the functions of large-capacity data storage and portable charging. Therefore, the charger provided by the application is a multifunctional charger and is convenient for users to use.

In the summary, a series of concepts in a simplified form are introduced, which will be further described in detail in the detailed description section. This summary is not intended to identify key features or essential features of the claimed subject matter, nor is it intended to be used as an aid in determining the scope of the claimed subject matter.

Advantages and features of the invention are described in detail below with reference to the accompanying drawings.

Drawings

The following drawings are included to provide an understanding of the invention and are incorporated in and constitute a part of this specification. Embodiments of the present invention and their description are shown in the drawings to explain the principles of the invention. In the drawings of which there are shown,

Fig. 1 is a schematic structural view of a multifunctional charging device according to an exemplary embodiment of the present invention;

Fig. 2 is a schematic structural view of a multifunctional charging device according to another exemplary embodiment of the present invention;

Fig. 3 is a schematic view illustrating an internal structure of a first housing according to another exemplary embodiment of the present invention;

fig. 4 is a schematic structural view of a multifunctional charging device according to still another exemplary embodiment of the present invention.

Wherein the above figures include the following reference numerals:

101. The fingerprint input device comprises a first shell, 102, a second shell, 103, a first interface, 104, an opening, 105, a connecting bus, 106, a docking station, 107, a magnetic structure, 108, a display screen, 109 and a fingerprint input module.

Detailed Description

In the following description, numerous details are provided to provide a thorough understanding of the invention. However, it will be understood by those skilled in the art that the following description illustrates preferred embodiments of the invention by way of example only and that the invention may be practiced without one or more of these details. Furthermore, some technical features that are known in the art have not been described in detail in order to avoid obscuring the invention.

Illustratively, the present application provides a multi-function charging apparatus. The charging equipment comprises a first shell 101 and at least one second shell 102 rotatably connected with the first shell 101, wherein the projection area of the outer outline of the first shell 101 is larger than a set value, a battery module and a data storage module are arranged in the first shell 101, a first interface is arranged on the at least one second shell 102, one end of the battery module is connected with an external power supply through the first interface and used for accessing electric quantity from the external power supply, the other end of the battery module is connected with the data storage module and used for outputting electric quantity to the data storage module, the data storage module is connected with the external electronic equipment through a connecting bus and used for reading and writing data with the external electronic equipment, and the battery module is further used for outputting electric quantity to the external electronic equipment through the connecting bus. The battery module may store power and output power.

The number of the second housings 102 may be more than one. Further, if the number of the second cases 102 is one, the second cases may be disposed on one side of the first case 101, and if the number of the second cases 102 is two, the second cases may be disposed on both sides of the first case 101. As shown in fig. 2, two second cases 102 are included and are provided on both sides of the first case 101, respectively.

Illustratively, the rotational connection between the first housing 101 and the second housing 102 may be accomplished using various connection means, either existing or developed in the future. Specifically, a rotary connector including a stator and a rotor is provided between the first housing 101 and the second housing 102. Further, the rotational connection may be a bearing.

The first housing 101 may be a panel, a rectangular frame, or a long bar intersecting with each other. The shape of the first housing 101 is not limited in the present application, as long as the projection area of the outer contour is larger than the set value, that is, the first housing 101 has a large enough area to play a supporting role. Further, the first housing 101 may be a collapsible structure and the outer profile may be an expanded profile. The projected area of the outer contour of the first housing 101 is larger than the set value. The set point may be close to the usual mobile electronic device size, for example 15cm x 20cm. The common mobile electronic equipment can be a mobile phone, a computer, a tablet and the like. The first housing 101 is of such a size that it can support the mobile electronic device and act as a stand.

The first housing and the second housing may be rotated to different states and thus fixed, for example. Further, the second housing 102 is rotatable between the first position and the second position, and is respectively clamped and fixed with the first housing 101 at a plurality of angles between the first position and the second position. In the snap-fit state, the relative position between the first housing 101 and the second housing 102 is fixed. As shown in fig. 1, a certain angle is formed between the first housing 101 and the second housing 102. When the second housing 102 is placed on the placement table, a certain angle is formed between the first housing 101 and the placement table, so that a user can conveniently place the mobile electronic device on the panel of the first housing 101.

As shown in fig. 2, the second housing 102 is provided with a first interface 103. It should be noted that fig. 2 shows that two second housings 102 are each provided with one first interface 103. In other embodiments, fewer first interfaces may be provided, for example, only one first interface 103 is provided on one second housing 102, and the number and arrangement of the first interfaces are not limited in the present application. Illustratively, the first interface 103 may be a Type-C interface or the like.

For example, the charging device may be plugged into a universal plug, which may be plugged into the first interface. The battery module in the charging equipment is connected with an external power supply through a universal plug, and the charging equipment can determine the voltage of the accessed external power supply and adjust the working voltage according to the voltage of the external power supply. In this embodiment, the charging device can be connected with different external power sources through the universal plug and adapt to the connected external power sources, so that users who need frequent international business trips are greatly facilitated. Wherein, adjust operating voltage can be through the main control module in the battery charging outfit. The main control module will be described in detail later.

Illustratively, the connection between the battery module and the data storage module may be an electrical connection or the like. The battery module can be a hybrid power supply formed by a lithium polymer battery pack and a super capacitor, and independent power supply of different modules can be realized. The capacity of the battery module is more than or equal to 10000mAh. The connection relationship between the battery module and the data storage module and the connection relationship between the external power source and the external electronic device may be as shown in fig. 3.

The external power source can be various power sources with power supply functions, and the working voltages of different external power sources can be different. The external power source may be mains power, for example.

The external electronic device can be various electronic devices which need to use electric quantity and/or need to read and write data, such as a computer, a mobile phone, a tablet, an unmanned aerial vehicle and the like. The external electronic equipment is connected with the module inside the charging equipment through the connecting bus, and can be particularly connected with the battery module and/or the data storage module, so that power supply is obtained from the battery module and/or data reading and writing with the data storage module are realized. The connection bus may be a line having functions of transmitting power and transmitting signals.

The data storage module is used for storing data input by the external electronic equipment and operation data of the charging equipment, and can also be used for storing computer programs. The computer program is loaded and executed by the main control module to implement the relevant processing steps. The data storage module may be a read-only memory, a random access memory, a magnetic disk, an optical disk, etc., and the storage mode may be transient storage or permanent storage. The data storage module may include one or more computer-readable storage media, which may be non-transitory. The data storage module may also include high speed random access memory, as well as non-volatile memory, such as one or more disk storage devices, flash memory storage devices. The charging device with the data storage module can expand the capacity of the external electronic device.

Further, an isolated DC-DC circuit can be arranged between the data storage module and the battery module so as to realize electromagnetic shielding of the storage circuit and the charging circuit and prevent the electric signal from interfering data reading and writing.

The multifunctional charging equipment provided by the embodiment comprises the first shell 101 and the second shell 102 which are connected in a rotating mode, the projection area of the outer outline of the first shell 101 is larger than a set value, the function of supporting the electronic equipment can be achieved, the multifunctional charging equipment can be used as a support of the electronic equipment, meanwhile, the charging equipment not only has a data reading-writing function, but also has a charging function, and the charging equipment can be charged through an external power supply, and can also be charged through the charging equipment. The functions of the traditional mobile hard disk, the charger and the bracket are integrated into one charging device. The user only needs to carry one charging device in the scenes of business trip and the like.

The first housing 101 is in a flat plate shape, the second housing 102 is in a strip shape, the length of the first housing 101 is larger than a first set value in the length direction of the second housing 102, the length of the second housing 102 is larger than a second set value, one end of the second housing 102 is connected to the first housing 101 through a rotating shaft, the second housing 102 is rotatable between a first position and a second position and is respectively clamped and fixed with the first housing 101 in a plurality of angles between the first position and the second position, wherein if the second housing 102 is in the first position, an included angle between the first housing 101 and the second housing 102 is zero, so that the first housing 101 and the second housing 102 are in the same flat plate, and if the second housing 102 is in the second position, the included angle between the first housing 101 and the second housing 102 is the maximum clamping angle.

Wherein the first set value and the second set value may be equal or unequal. The length of the first housing 101 is greater than the first set value so that the area of the first housing is large enough to house the electronic device. The length of the second housing 102 being greater than the second set value may make the length or the area of the second housing sufficiently long to support the first housing, as shown in fig. 1, the second housing 102 being sufficiently long to support the first housing 101 and maintain the smoothness of the first housing 101 when forming an angle with the first housing 101.

The first housing 101 and the second housing 102 may also have a certain thickness, and the thicknesses of the two may be equal or unequal. Further, the thicknesses of the first casing 101 and the second casing 102 are equal, so that when the included angle between the first casing 101 and the second casing 102 is zero, the first casing 101 and the second casing 102 are on the same plane plate, and the upper panel can form a plane so as to be convenient for placing or placing other objects.

The rotary shaft comprises a bearing, a through hole is formed in the bearing, the charging device further comprises a power input wire, the power input wire is arranged in the charging device, one end of the power input wire is connected with the first interface, and the other end of the power input wire penetrates through the through hole of the bearing to be connected with the battery module, so that electric quantity of an external power supply can be input into the battery module.

As shown in fig. 2, one end of the power input line is connected to the first interface 103, and the other end is connected to the battery module through the bearing through hole. The external power source can be plugged into the first interface 103, so that the electric quantity can be transmitted to the battery module to charge the charging device.

In the embodiment, the through hole arranged on the bearing can ensure that the power input wire is not stranded in the rotation process of the second shell, the service performance of the power input wire is ensured, and the bearing can rotate at a large angle (such as 270 degrees), so that the convenience of the charging process of the charging equipment is further ensured.

The bearing comprises an inner ring and an outer ring which are matched with each other, the outer ring is sleeved outside the inner ring, at least part of the outer side surface of the inner ring and at least part of the inner side surface of the outer ring are respectively provided with a tooth structure which is matched with each other, the tooth structures of the inner ring and the outer ring are sequentially meshed in the rotation process of the first shell 101 or the second shell 102, and the second shell 102 is clamped and fixed with the first shell 101 in the meshed state.

Wherein the tooth structure is constructed and arranged such that the torque thereof is greater than a set value. In the engaged condition, the tooth structure can support at least 3kg of articles. This design enables the charging device to be placed in a vast majority of mobile electronic devices.

In this embodiment, at least part of the side surface of the bearing is provided with a tooth structure, so that the second housing 102 and the first housing 101 can be clamped and fixed, and the angle between the first housing and the second housing can be adjusted step by step. Under the condition that the tooth structure is arranged on the outer side surface of the part, the first shell and the second shell can be clamped at a part of angles, other parts of the first shell and the second shell are not clamped, the first shell and the second shell can be rapidly and randomly rotated and then reset to readjust the angles without 360-degree rotation, and the rotation efficiency can be improved.

It should be noted that the through hole may be disposed in a central area of the inner ring, so that a certain distance is kept between the tooth structure and the power input line, so as to ensure that the power input line is not blocked by the tooth structure.

Illustratively, one side of the first housing 101 is provided with an opening, a connection bus extends out of the housing through the opening to be connected with an external electronic device, the connection bus includes a data line and a power output line, the data storage module is connected with the external electronic device through the data line, and the battery module is connected with the external electronic device through the power output line.

The opening may be provided at a side surface not in direct contact with the second housing 102. As shown in fig. 2 and 4, an opening 104 is provided in the housing of the charging device, and a connection bus 105 extends out of the housing through the opening 104, and the connection bus 105 can be pulled out of the placement groove to connect with an external electronic device.

The connecting bus comprises a data line for transmitting data and a power output line for transmitting current, so that synchronous bidirectional intercommunication of the data and the current can be realized. Illustratively, the connection bus may include 12 wires, 2 of which are data wires, and 10 of which are power output wires.

The embodiment realizes synchronous bidirectional intercommunication of data and current through the connecting bus. The charging equipment not only can charge the external electronic equipment, but also can charge the external electronic equipment by using the stored electric quantity, and can perform data interaction with the external electronic equipment, so that the charging equipment is convenient for users to use.

Illustratively, as shown in fig. 2 and 4, a docking station 106 is also provided on the side where the opening is provided. Wherein a plurality of second interfaces are arranged at the position of the docking station. The docking station can comprise Type C/HDMI/USB 3.0 interfaces, the interfaces can be connected with different external electronic devices, and expandability of the charging device is improved.

The first panel of the first housing 101 is provided with a magnetic structure, the second panel of the first housing 101 is provided with a clamping mechanism for clamping the thin film keyboard, the clamping mechanism is provided with a trigger button for triggering the clamping mechanism to be in a clamping or non-clamping state when external force is applied, and the first panel and the second panel are two opposite surfaces of the first housing 101.

As shown in fig. 1, a magnetic structure 107 is disposed on the first panel (which may be the front side). The adsorption device is used for adsorbing mobile electronic equipment and achieves a good fixing effect.

Illustratively, the second panel (which may be a back side) is provided with a clamping mechanism for clamping the membrane keypad. The film keyboard can be fixed when the clamping mechanism is in the clamping state, and can be taken down from the back of the charging equipment to be used independently when the clamping mechanism is in the non-clamping state.

In this embodiment, the charging device not only can adsorb electronic devices, but also can be connected with the thin film keyboard in a clamping manner, that is, the multifunctional charging device in the embodiment of the application integrates functions of a charger, a bracket, a mobile solid state disk and a keyboard. The user can carry the charging equipment of this embodiment when going out, need not carry charger, support, mobile solid state disk and keyboard, can greatly improve the use convenience.

In other embodiments, the magnetic structure may be disposed inside the first housing, in which case 107 in fig. 1 may be replaced by a soft material, which is used as a fixing component when the electronic device is placed, so as to prevent the electronic device from sliding down.

The charging device further comprises a first display screen and a second display screen which are arranged on the second shell 102, a state monitoring module and a main control module are further arranged in the first shell 101, the battery module is further connected with the state monitoring module and the main control module and used for outputting electric quantity to the state monitoring module and the main control module, the state monitoring module comprises an electric signal monitoring unit which is connected with the battery module, the electric signal monitoring unit is used for monitoring the voltage and/or the current of the battery module in real time, the main control module is used for acquiring the voltage and/or the current from the state monitoring module and controlling the first display screen to display the acquired voltage and/or the current, the state monitoring module further comprises an electrifying timing unit which is connected with the data storage module, the electrifying timing unit is used for timing the electrifying time of the data storage module, and the main control module is further used for acquiring the electrifying time of the data storage module from the state monitoring module and controlling the second display screen to display the electrifying time. The connection relationship between the state monitoring module and the main control module may be as shown in fig. 3.

The first display screen and the second display screen can be realized by two different display screens, for example, respectively arranged on the two second shells. The first display and the second display may also be realized by one display. As shown in fig. 2, the voltage/current and the energization time period information are synchronously displayed by one display screen 108 provided on the second housing 102, and the voltage/current and the energization time period information may be displayed in different areas of the display screen.

The state monitoring module is a module for monitoring the state of the charging device and various devices inside the charging device, and may be a module including various monitoring sensors or monitoring chips. Further, the state monitoring module can be used for monitoring the use state data such as the power-on duration of the data storage module, and the state monitoring module can also be used for monitoring the data such as the voltage, the current and the like of the battery module.

The main control module is used for managing and controlling all hardware devices and computer programs on the charging equipment so as to realize the operation and processing of the main control module on the data in the charging equipment and the data storage module. The master control module may be in the form of a processor, and may specifically include one or more processing cores, such as a 1-core processor, a 2-core processor, and the like. The processor may be implemented in at least one hardware form of DSP (DIGITAL SIGNAL Processing), FPGA (Field-Programmable gate array), PLA (Programmable Logic Array ). The processor may also include a main processor, which is a processor for processing data in a wake-up state, also called a CPU (Central Processing Unit ), and a coprocessor, which is a low-power processor for processing data in a standby state. In some embodiments, the processor may incorporate a GPU (Graphics Processing Unit, image processor) for rendering and rendering of content to be displayed by the display screen. In some embodiments, the processor may also include an AI (ARTIFICIAL INTELLIGENCE ) processor for processing computing operations related to machine learning, such as predicting a remaining useful life of the charging device.

In this embodiment, the monitored current/voltage or the power-on duration is displayed through the two display screen areas respectively, and the user can know the running state of the charging device in time by means of the display control of the main control module. Moreover, the interaction between the charging equipment and an external power supply and/or external electronic equipment can be monitored in real time through the state monitoring module, so that the charging equipment is convenient to manage and control.

The main control module is further used for judging that the data storage module is in data reading and writing with external electronic equipment if the state monitoring module monitors that the data wire is in data transmission, judging that the battery module is in a charging state if the state monitoring module monitors that the current input by an external power source exists in the power input wire or the current output to the external electronic equipment exists in the power output wire, and limiting the data transmission bandwidth of the data wire when the data storage module is in data reading and writing with the external electronic equipment and the battery module is in the charging state.

The charging state comprises inward charging of the charging device by the external power supply and outward charging of the external electronic device by the charging device.

Illustratively, the data transmission bandwidth may be automatically limited at 480Mbps or less in the charged state to reduce power consumption.

In this embodiment, when the charging device is in the charging state and the data read-write state at the same time, the data transmission bandwidth of the data line is limited. The power consumption can be reduced, and the operation load of the main control module is reduced.

The state monitoring module may be further configured to monitor usage state data such as a stored capacity of the data storage module, a data read/write speed, and the like, and the state monitoring module may be further configured to monitor data such as a temperature of the charging device. Furthermore, the state monitoring module can acquire the use state data of the data storage module and the temperature of the charging equipment in real time.

The state monitoring module comprises a storage capacity monitoring unit, a data transmission speed monitoring unit and an electrifying timing unit, wherein the storage capacity monitoring unit is used for monitoring the stored capacity of the data storage module, the data transmission speed monitoring unit is used for monitoring the data reading and writing speed of the data storage module in real time, the electrifying timing unit is used for timing the electrifying time of the data storage module, and correspondingly, the using state data of the data storage module comprise the stored capacity, the data reading and writing speed and the electrifying time, and the main control module is further used for acquiring the stored capacity, the data reading and writing speed and the electrifying time of the data storage module from the state monitoring module and controlling the display module to display the stored capacity, the data reading and writing speed and the electrifying time.

For example, the whole disc on the interface represents the total capacity, the part of the stored capacity marked as dark color and the part not stored is marked as light color, and a user can know the data storage state of the charging device by looking at the proportion of the dark area.

The data reading and writing speed is the real-time speed when the charging equipment and the external electronic equipment read and write data, and the data reading and writing speed can be identified through the pointer. Specifically, the main control module can convert the acquired data read-write speed into the rotation angle of the pointer, so as to control the display module to update the display state of the pointer.

The power-on duration is the accumulated use duration of the charging device. Further, the charging device has a total usage time length, for example, one thousand hours, whereby subtracting the energization time length from the total usage time length is the remaining service life of the charging device. Therefore, the display module displays the power-on duration and can remind the user of the residual service life. In some embodiments, the main control module may also predict the remaining service life of the charging device in combination with the running states (accumulated use duration, temperature, etc.) of the various indexes of the charging device, the security of the stored data, etc., so as to control the display module to display. Further, the main control module may activate the AI module to determine the remaining useful life.

The display module is a module for displaying data, graphics and the like, and can be realized through a display screen, a touch screen and the like. The display module may be implemented by a display screen on the charging device housing. Further, the display screen can be LCD/LED/OLED, clear display of information can be achieved, and fast refreshing of data is achieved without a click feeling. It should be noted that, the display module may be the first display screen or the second display screen, or may be implemented by other display screens.

In this embodiment, various use states of the data storage module are monitored by the state monitoring module, so that a user can instantly know whether the data storage function of the hard disk is normal, and the subsequent use is facilitated.

For example, since the battery module needs to charge numerous modules, the charging priority of these modules may be set. For example, the data storage module is set to the highest charging priority, and when the connection of the external electronic device is detected, the power supply of the data storage module is preferentially ensured, so that the reliable storage of the data can be realized to ensure the safety of the data. Further, the output end of the battery module is provided with a voltage distribution circuit ‌ for preferentially guaranteeing the power supply of the storage unit.

The battery module can also supply power to different modules through different power supply lines so as to ensure the power supply stability of each module, for example, the data storage module is independently powered, so that the data storage module does not change along with the change of the voltage of external electronic equipment, and the stable operation of the data storage module is ensured. Further, the battery module further comprises an isolated power conversion unit to ensure independent power supply of the corresponding module. Illustratively, the isolated power conversion unit includes an EMI filter circuit comprising a common mode choke and a Y capacitor, with a filter cutoff frequency set to 1MHz ± 10% ‌.

The state monitoring module further comprises a temperature sensor for monitoring a temperature value in the shell, and the main control module is correspondingly used for acquiring the temperature value from the state monitoring module. In this embodiment, the state monitoring module monitors not only the usage state data of the data storage module, but also the temperature state of the charging device, so that the user can obtain the running state of the charging device comprehensively.

The data storage module is a hard disk main body, the battery module is a battery core, a heat dissipation copper foil is attached to the hard disk main body and/or the battery core and used for conducting heat generated by the hard disk main body and/or the battery core into the shell, and the shell is made of a heat conducting material so as to conduct the heat in the shell to the outside of the shell.

Illustratively, a thermally conductive sheet may also be provided between the heat dissipating copper foil and the housing to better conduct heat from within the housing to the outside of the housing.

The charging device comprises a hard disk main body and a battery cell, and the hard disk main body and the battery cell can generate corresponding heat, and if the heat is concentrated at the positions of the hard disk main body and the battery cell, the heat can cause overheat of the hard disk main body and the battery cell to influence operation. In this embodiment, the heat dissipation copper foil conducts heat generated by the hard disk main body and/or the battery cell into the housing, and the heat conducting housing conducts heat inside the housing to outside the housing. The heat dissipation of the charging equipment can be realized through a physical heat dissipation mode, so that the effective cooling of the charging equipment is realized, and the normal operation of the charging equipment is ensured.

Illustratively, as shown in fig. 1, the charging device further includes a fingerprint input module 109, a fingerprint input module for acquiring user fingerprint information, and a main control module for acquiring user fingerprint information from the fingerprint input module, performing authority comparison analysis on the user fingerprint information to obtain a user authority determination result, opening the access authority to the data storage module if the user authority determination result is authority, and closing the access authority to the data storage module if the user authority determination result is non-authority.

Wherein, as shown in fig. 2, the fingerprint input module 109 is disposed on the second housing. The user may place a fingerprint on the fingerprint input module 109. The fingerprint input module 109 thus obtains user fingerprint information.

Further, the fingerprint input module can be specifically realized through a touch screen with a fingerprint identification function. The touch screen and the display screen in other embodiments can be realized by the same screen.

For example, when the main control module determines that the external electronic device is connected to the charging device, the main control module may output prompt information to remind the user to input fingerprint information. When the fingerprint information of the user is obtained through the fingerprint input module, the main control module determines a user permission judging result, and when the user permission exists, the access permission of the external electronic equipment to the data storage module is opened, meanwhile, an unlocking state schematic diagram can be displayed on an interface, otherwise, the permission is closed, and meanwhile, a locking state schematic diagram can be displayed.

In this embodiment, the master control module may implement authority management and control, and if the user does not have corresponding authority, the user cannot access the data storage module, so that reliability of the electronic device performing data interaction with the charging device can be ensured, and further security of the charging device is ensured. If the user permission determination result is no permission, the external electronic equipment cannot read and write data with the charging equipment, at this time, the charging device can charge through an external power supply and also can charge the electronic device, which is equivalent to a charger function.

The charging device further comprises a power input module, a main control module and a working current, wherein the main control module is further used for determining corresponding target power according to the power adjustment instruction when the power adjustment instruction is acquired based on the power input module, or determining the use power of the external electronic device as the target power when the fact that the external electronic device is connected and the difference value between the use power of the external electronic device and the use power of the charging device exceeds a set threshold value is monitored, and the working current is adjusted to control the charging device to operate according to the target power.

The power input module may be a module with an input function, such as a touch display screen and a key.

The power used by different electronic devices varies, and the charging device often needs to be connected with various electronic devices. Since there may be fluctuations in the power used by the electronic device during use, power differences within the fluctuation range are acceptable. But when the difference exceeds the set threshold, it indicates that the power usage of the charging device and the external electronic device is not adapted, for example, the normal power usage of the charging device is 140W, and when it is connected to the old device (96W), the power usage of the old device and the charging device is not adapted. Further, the set threshold corresponding to the difference of the power may be set as required, which is not limited in the embodiment of the present application.

In this embodiment, the adaptability adjustment is implemented according to the power set by the user or the power of the external electronic device, and further, the charging device may be adapted to use with various different electronic devices.

Illustratively, the foregoing embodiments implement power regulation. In other embodiments, the power may be replaced by a current or a voltage, and the specific implementation of the power adjustment may refer to the implementation of power adjustment, which is not described in detail in the embodiments of the present application. Illustratively, when the smartphone is connected, the charging device automatically switches to the 5V/3A output mode while maintaining 3.3V/1.8A independent power to the data storage module.

The main control module is further used for generating at least one data computing sub-task and a data sequence sub-task corresponding to the at least one data computing sub-task according to the current running state of the charging equipment, wherein the data computing sub-task comprises data computing sub-tasks for computing the using state data and/or storage data of the data storage module, processing each data computing sub-task to obtain a computing result of each data computing sub-task, processing the data sequence sub-tasks corresponding to each data computing sub-task to obtain processing result data of each data sequence sub-task, and downloading the processing result data to a preset storage space which is the storage space in the data storage module.

By way of example, the operating states of the charging device may include a data read state, a data write state, a standby state, and the like. The charging device may further include a normal operation mode and a low power consumption operation mode, where functions such as data reading and writing, data processing, and data displaying in the normal operation mode are normally operated, and in the low power consumption operation mode, some functions thereof may be turned off, for example, a temperature value may not be acquired, processed, and displayed, and an energization period may not be acquired, processed, and displayed. The closed functions may be performed by default or may be modified by the user. The operating states corresponding to the different operating modes may be different. Further, the data to be processed by the main control module in different running states are different. Therefore, it is necessary to generate the corresponding data calculation subtask and data sequence subtask according to the operation state of the charging device.

The data calculation subtasks may be tasks for calculating any data, which may be data stored in the data storage module or data monitored by the state monitoring module, for example, usage state data of the data storage module, a temperature value in the housing, and the like.

Further, the data calculation sub-task may be a corresponding task of performing targeted processing on each different data to facilitate display, storage, and the like. May include performing data analysis and feature extraction processing on the data to be stored, determining a current stored capacity based on the current stored data and a historical stored capacity, determining a data storage speed, determining a location where the data is stored, calculating a cumulative power-on duration, and the like. The data volume on the charging device is often huge due to the subsequent need of display, storage and the like, and in order to ensure the data order, the calculation results obtained by the data calculation subtasks need to be subjected to order processing according to the set rules, and the order processing can be normalization, format unified processing, form conversion processing and the like.

The main control module can also be connected with the data storage module. After the processing result data is obtained, the processing result data is downloaded to a preset storage space in the data storage module, so that the main control module can directly read corresponding data from the data storage module when needed, and further processes such as display and the like are performed.

For the case of data processing and subsequent display, the data-ordering subtask may also include a time-stamping process. The main control module performs time alignment processing based on the time stamp of each data, so that the data displayed by the display module at the same moment are aligned, and the judgment of a user is facilitated.

In this embodiment, in the face of the need of processing different data simultaneously, different computing tasks and corresponding ordering tasks are determined, so that ordered and reliable processing of each data can be realized, and ordered storage of charging equipment data and ordered management and control of running states are ensured.

The method comprises the steps of processing each data calculation subtask to obtain a calculation result of each data calculation subtask, processing each data calculation subtask to obtain processing result data of each data calculation subtask, and processing the current data calculation subtask to obtain a calculation result of the current data calculation subtask through a calculation thread, wherein the current data calculation subtask is any data calculation subtask, sending the calculation result of the current data calculation subtask to a sequencing thread to trigger the sequencing thread to process the data calculation subtask corresponding to the current data calculation subtask, and taking the next data calculation subtask in the current data calculation subtask as the current data calculation subtask and executing the step of processing the current data calculation subtask to obtain the calculation result of the current data calculation subtask if the current data calculation subtask is not the last data calculation subtask in at least one data calculation subtask.

For example, after the whole-order thread executes the corresponding data whole-order subtask, the main control module may send the processing result data of the current data whole-order subtask to the downloading thread, so as to trigger the downloading thread to download the processing result data to the preset storage space.

Because the charging equipment needs to process more data, in order to improve the data processing efficiency, in this embodiment, each data calculation subtask is performed in parallel, and similarly, the data sequence subtask is also performed in parallel, and after each data calculation subtask is completed, the corresponding data sequence subtask is started, so that the data processing efficiency can be greatly improved, the timeliness of data display can be ensured if the data display is required, and the efficiency of data reading and writing can be improved if the data reading and writing are required to be completed.

The data corresponding to the data calculation subtask is the use state data, the display module can be controlled to display based on the processing result data after the processing result data is obtained by the data calculation subtask, and the data knowledge graph can be constructed on the stored data after the processing result data is obtained by the data calculation subtask if the data corresponding to the data calculation subtask is the stored data, so that the data search can be conveniently carried out subsequently.

The data storage module comprises a plurality of storage blocks, at least one data calculation subtask and a data sequence subtask corresponding to the at least one data calculation subtask are generated according to the current running state of the charging equipment, the data storage module comprises that if the charging equipment is in a state of writing data into the data storage module and the current storage data is text data, text splitting is carried out on the current storage data to obtain at least one split text, the data calculation subtask corresponding to each split text and the data sequence subtask corresponding to the data calculation subtask are determined, corresponding data calculation subtask is processed to obtain a calculation result of each data calculation subtask, the data sequence subtask corresponding to each data calculation subtask is processed to obtain a processing result data of each data sequence subtask, the data sequence subtask comprises that the current split text is mapped into a digital sequence and a context relation sequence corresponding to the current split text is generated based on a preset context window, the context relation sequence is based on the adjacent split text in the current split text window, the corresponding data sequence is further obtained according to a corresponding knowledge graph of the current calculation result of the data calculation subtask, the corresponding data of the current calculation subtask is obtained according to the corresponding data of the calculation result of the data calculation sub-task, the current calculation result of the data sequence is further obtained according to a corresponding data of the calculation result of the current calculation sub-task is used as a corresponding data of the current knowledge graph, the data knowledge graph of the current storage block is obtained by integrating and constructing a data knowledge graph of the current storage block based on a digital sequence and a context relation sequence of each stored data, and also comprises a cross-correlation relation among each stored data.

The text data may be words, codes, etc. recorded in a file such as word, excel, notepad, etc. The main control module can have a data read-write analysis function and can read text data of the file. Note that the present embodiment is directed to text data, and in other embodiments, processing may be performed with respect to other data types and with reference to text data. For example, the text data may be replaced with image data, and when splitting the image data, the split image data may be the smallest unit having the meaning of an independent image, for example, may be a picture, a video segment, a picture area, or the like. The subsequent implementation manner may refer to a processing manner of text data, and the embodiments of the present application are not described in detail.

The split text may be a text segment obtained by splitting the text data, and each split text may be a minimum text segment with independent meaning, for example, may be a name, a verb, and the like.

For example, mapping the current split text to the digital sequence may be a process of encoding the current split text. The codes corresponding to the texts with different meanings or characteristics can be different, so that the result obtained by the codes can represent the meaning or the characteristic of the split text, and subsequent cross-correlation calculation is facilitated.

For example, the window size of the preset context window may be 5 characters by 5 characters, and each adjacent split text may correspond to a context sequence.

Illustratively, the cross-correlation relationship between text may be calculated by existing or future developed cross-correlation algorithms.

Further, the number sequence corresponding to the current split text and the determined context sequence can be taken together as a calculation result. In other embodiments, the number sequence and the context relation sequence may be integrated, for example, normalization processing is performed on the number sequence and each context relation sequence, a weight corresponding to each adjacent split text is determined, a weighted summation is performed on a normalization processing result of the context relation sequence based on the weight, a summation and other processing is performed on the weighted summation result and a normalization processing result of the number sequence corresponding to the current split text, and then the processing result is determined as a calculation result of the current split text.

For example, the construction process of obtaining the data knowledge graph of the current storage block corresponding to the current storage data may be integrated and constructed according to the calculation result. And for the case that the calculation result comprises the number sequence corresponding to the current split text and the context relation sequence, the calculation result can be obtained based on the integration construction of the number sequence corresponding to the current split text and the context relation sequence. Further, the number sequence can be used as a node, a data knowledge graph corresponding to a single split text is constructed based on the context relation, and the cross correlation relation among the split texts is determined, so that the data knowledge graph corresponding to the current stored data is constructed. And the result of integrating the digital sequence and the context relation sequence can be directly used as the node of each split text, and then the cross correlation relation among each split text is determined so as to construct and obtain the data knowledge graph corresponding to the current stored data.

The method comprises the steps of obtaining a data knowledge graph corresponding to current stored data, carrying out sequence arrangement processing on calculation results corresponding to split texts according to a preset sequence format to obtain processed calculation results with uniform formats, carrying out cross-correlation analysis on the processed calculation results of split texts, determining independent result data and associated result data based on the cross-correlation analysis results, wherein the association between the sequences corresponding to the independent result data and other sequences is lower than a set condition, the association between the sequences corresponding to the associated result data and other sequences is higher than or equal to the set condition, extracting feature identification information of corresponding data based on the associated result data, determining association factors between the corresponding split texts based on the extracted feature identification information, and constructing the data knowledge graph corresponding to the current stored data based on the association factors between the split texts.

Further, the feature recognition information comprises storage position feature information and semantic feature information, and the method comprises the steps of determining association factors between the corresponding two split texts based on the extracted feature recognition information, wherein the method comprises the steps of carrying out association analysis on the storage position feature information between the two split texts to obtain a position association relationship, carrying out association analysis on the semantic feature information between the storage position feature information to obtain an object semantic association relationship, and fusing the position association relationship and the semantic association relationship to obtain the association factors between the corresponding two split texts. The location feature information may be a storage block or sector where the corresponding split text is located, and the semantic feature information is feature information obtained by performing semantic recognition on the split text.

The method for updating the data knowledge graph of the current storage block based on the data knowledge graph corresponding to the current storage data can be implemented by acquiring the stored data in the current storage block, respectively determining a digital sequence and a context relation sequence of each stored data, determining a cross-correlation relation between the current storage data and different stored data, and further constructing a new knowledge graph of the current storage block based on the cross-correlation relation to realize updating of the knowledge graph.

For example, the constructed data knowledge graph may be stored in a pre-divided storage space of the charging device. The main control module can access the data knowledge graph in the storage space at any time so as to realize the searching and analyzing of the data.

In this embodiment, the data knowledge patterns are sequentially constructed in a small-to-large relationship, so that the total data knowledge patterns of the current storage block can be obtained, and the total data knowledge patterns have good retrieval convenience. When the user needs to search data in the charging equipment, the master control module can quickly search the data needed by the user based on the total data knowledge graph without traversing each file. Further, the main control module can integrate the stored data to obtain a result required by the user because the total data knowledge graph contains the cross-correlation relationship among different texts. For example, when a user inputs "help me encrypt order data of nearly three months" through a search window of an external electronic device, the main control module can search the order data of all dates through a total data knowledge graph and screen order files of nearly three months from the data, and then the main control module can encrypt all the order files without searching for encryption one by the user. For another example, the user inputs "help me find 2025 order data and analyze order status" through the search window of the external electronic device, then the main control module can find the order files under each date through the total data knowledge graph and screen out all files related to 2025, and then the main control module can analyze the order content in the order files, find rules and the like in the order files and generate a result text for output, so that the user does not need to find and manually analyze one by one.

In this embodiment, a data knowledge graph is constructed, and the data knowledge graph of the storage block is updated every time one data is newly stored, global searching can be performed on the data in the storage block through the data knowledge graph, and the fine granularity of searching can be refined to a single split text, so that accurate searching of the data can be realized, and convenience of searching and analyzing the data can be greatly improved.

In the description of the present invention, it should be understood that the azimuth or positional relationships indicated by the azimuth terms such as "front", "rear", "upper", "lower", "left", "right", "transverse", "vertical", "horizontal", "top", "bottom", etc., are generally based on the azimuth or positional relationships shown in the drawings, are merely for convenience of describing the present invention and simplifying the description, and these azimuth terms do not indicate and imply that the apparatus or elements referred to must have a specific azimuth or be constructed and operated in a specific azimuth, and thus should not be construed as limiting the scope of the present invention, and the azimuth terms "inside", "outside" refer to inside and outside with respect to the outline of each component itself.

For ease of description, regional relative terms, such as "above," "upper surface," "above," and the like, may be used herein to describe regional positional relationships of one or more components or features to other components or features shown in the figures. It will be understood that the relative terms of regions include not only the orientation of the components illustrated in the figures, but also different orientations in use or operation. For example, if the element in the figures is turned over entirely, elements "over" or "on" other elements or features would then be included in cases where the element is "under" or "beneath" the other elements or features. Thus, the process is carried out, the exemplary term "above" may be included. Upper and lower. Two orientations below. Moreover, these components or features may also be positioned at other different angles (e.g., rotated 90 degrees or other angles), and all such cases are intended to be encompassed herein.

It is noted that the terminology used herein is for the purpose of describing particular embodiments only and is not intended to be limiting of exemplary embodiments according to the present invention. As used herein, the singular is also intended to include the plural unless the context clearly indicates otherwise, and furthermore, it is to be understood that the terms "comprises" and/or "comprising" when used in this specification are taken to specify the presence of stated features, steps, operations, components, assemblies, and/or combinations thereof.

It should be noted that the terms "first," "second," and the like in the description and the claims of the present invention and the above figures are used for distinguishing between similar objects and not necessarily for describing a particular sequential or chronological order. It is to be understood that the data so used may be interchanged where appropriate such that embodiments of the invention described herein may be implemented in sequences other than those illustrated or otherwise described herein.

The present invention has been illustrated by the above-described embodiments, but it should be understood that the above-described embodiments are for purposes of illustration and description only and are not intended to limit the invention to the embodiments described. In addition, it will be understood by those skilled in the art that the present invention is not limited to the embodiments described above, and that many variations and modifications are possible in light of the teachings of the invention, which variations and modifications are within the scope of the invention as claimed. The scope of the invention is defined by the appended claims and equivalents thereof.

Claims (10)

1. A multifunctional charging device, characterized in that it comprises: a first shell and at least one second shell rotatably connected to the first shell; the projection area of the outer contour of the first shell is greater than a set value, a battery module and a data storage module are arranged in the first shell; at least one second shell is provided with a first interface; One end of the battery module is connected to the external power supply through the first interface, and is used to receive power from the external power supply; the other end of the battery module is connected to the data storage module, and is used to output power to the data storage module; The data storage module is connected to an external electronic device via a connection bus and is used to read and write data with the external electronic device; the battery module is also used to output power to the external electronic device via the connection bus. 2. The multifunctional charging device according to claim 1, characterized in that the first shell is in the shape of a flat plate, and the second shell is in the shape of a strip; in the length direction of the second shell, the length of the first shell is greater than a first set value, and the length of the second shell is greater than a second set value; One end of the second shell is connected to the first shell via a rotating shaft; the second shell is rotatable between a first position and a second position and is respectively clamped and fixed to the first shell at multiple angles between the first position and the second position; wherein, if the second shell is in the first position, the angle between the first shell and the second shell is zero, so that the first shell and the second shell are in the same plane plate; if the second shell is in the second position, the angle between the first shell and the second shell is the maximum clamping angle. 3. The multifunctional charging device according to claim 2, characterized in that the rotating shaft comprises a bearing; a through hole is provided in the bearing; The charging device also includes a power input line; one end of the power input line is connected to the first interface, and the other end passes through the through hole of the bearing to connect to the battery module, so as to input the power of the external power supply into the battery module. 4. The multifunctional charging device according to claim 3, characterized in that the bearing comprises an inner ring and an outer ring that cooperate with each other, the outer ring is sleeved outside the inner ring; at least part of the outer side surface of the inner ring and at least part of the inner side surface of the outer ring are respectively provided with mutually cooperating tooth structures; During the rotation of the first shell or the second shell, the tooth structures of the inner ring and the outer ring are meshed in sequence; wherein, in the meshed state, the second shell is clamped and fixed to the first shell. 5. The multifunctional charging device according to claim 3, characterized in that an opening is provided on one side of the first housing; The connection bus extends out of the housing through the opening to connect with an external electronic device; the connection bus includes a data line and a power output line; the data storage module is connected to the external electronic device through the data line; the battery module is connected to the external electronic device through the power output line; Correspondingly, an expansion dock is also provided on the side where the opening is provided. 6. The multifunctional charging device according to claim 2, characterized in that a magnetic attraction structure is provided on the first panel of the first shell; A clamping mechanism is provided on the second panel of the first housing, and the clamping mechanism is used to clamp the membrane keyboard; a trigger button is provided on the clamping mechanism, and the trigger button is used to trigger the clamping mechanism to be in a clamping or non-clamping state when subjected to an external force; The first panel and the second panel are two opposite surfaces of the first shell. 7. The multifunctional charging device according to claims 1 to 6, characterized in that the charging device further comprises a first display screen and a second display screen arranged on the second shell, and a state monitoring module and a main control module are also arranged in the first shell; the battery module is also connected to the state monitoring module and the main control module, and is used to output power to the state monitoring module and the main control module; The state monitoring module includes an electrical signal monitoring unit connected to the battery module; the electrical signal monitoring unit is used to monitor the voltage and/or current of the battery module in real time; the main control module is used to obtain the voltage and/or current from the state monitoring module, and control the first display screen to display the obtained voltage and/or current; The status monitoring module also includes a power-on timing unit connected to the data storage module; the power-on timing unit is used to time the power-on duration of the data storage module; the main control module is also used to obtain the power-on duration of the data storage module from the status monitoring module, and control the second display screen to display the power-on duration. 8. The multifunctional charging device according to claim 7, characterized in that the charging device further comprises a fingerprint input module; The fingerprint input module is used to obtain user fingerprint information; The main control module is further used to obtain user fingerprint information from the fingerprint input module, perform permission comparison analysis on the user fingerprint information to obtain a user permission determination result, and if the user permission determination result is that the user has permission, open the access permission to the data storage module; if the user permission determination result is that the user has no permission, close the access permission to the data storage module. 9. The multifunctional charging device according to claim 7, characterized in that the charging device further comprises a power input module; The main control module is also used to determine the corresponding target power according to the power adjustment instruction when a power adjustment instruction is obtained based on the power input module, or, when it is monitored that an external electronic device is connected and the difference between the power usage of the external electronic device and the power usage of the charging device exceeds a set threshold, determine the power usage of the external electronic device as the target power; and adjust the working current to control the charging device to operate according to the target power. 10. The multifunctional charging device according to claim 7, characterized in that the main control module is further used to perform the following steps: Generate at least one data calculation subtask and a data sorting subtask corresponding to the at least one data calculation subtask according to the current operating state of the charging device; the data calculation subtask includes a data calculation subtask for calculating the usage status data and/or storage data of the data storage module; Processing each of the data calculation subtasks to obtain a calculation result of each of the data calculation subtasks, and processing the data sorting subtasks corresponding to each of the data calculation subtasks to obtain processing result data of each of the data sorting subtasks; The processing result data is downloaded to a preset storage space; the preset storage space is a storage space in a data storage module.