CN117271610B - Device state management method, device, terminal device and storage medium - Google Patents

Abstract

The application discloses a device state management method, a device, a terminal device and a storage medium, wherein the device state management method comprises the following steps: receiving data uploaded by the electrical equipment; determining a hot spot electrical device based on the data uploaded by the electrical device; and monitoring the equipment state of the hot spot electrical equipment. Based on the scheme, the equipment state monitoring can be performed on the hot spot electrical equipment in a targeted manner, the data interaction times between the platform and the electrical equipment in the equipment state updating process are reduced, and the equipment state updating efficiency is improved.

Description

Device state management method, device, terminal device and storage medium

Technical Field

The present disclosure relates to the field of electrical device control technologies, and in particular, to a device state management method, a device, a terminal device, and a storage medium.

Background

The intelligent electricity consumption management platform meets the electricity consumption safety requirements and the energy saving requirements of various application scenes by unique technical advantages. In general, an intelligent power consumption management platform manages a plurality of electrical devices, and real-time states of all the electrical devices are displayed on a visual man-machine interaction interface of the intelligent power consumption management platform, so that a technician can intuitively judge whether a certain electrical device is in an on-line state or an off-line state, and further control over the electrical device is achieved, or fault points are accurately processed. In order to acquire the state information of the managed electrical devices, the intelligent power consumption management platform generally needs to actively send a state request to each electrical device, and under the condition that the number of the electrical devices is large, the state information acquisition mode occupies a large amount of communication resources.

Disclosure of Invention

The main purpose of the application is to provide a device state management method, a device, a terminal device and a storage medium, and aims to solve the problem that the number of data interaction times between a platform and electrical equipment is too large in a device state updating process.

In order to achieve the above object, the present application provides a device state management method, where the device state management method is applied to an intelligent power consumption management platform, and the device state management method includes:

receiving data uploaded by the electrical equipment;

determining a hot spot electrical device based on the data uploaded by the electrical device;

and monitoring the equipment state of the hot spot electrical equipment.

Optionally, the step of determining a hotspot electrical device based on the data uploaded by the electrical device comprises:

obtaining a corresponding hot spot electrical equipment number based on the data uploaded by the electrical equipment;

and determining the hot spot electrical equipment according to the hot spot electrical equipment number.

Optionally, the step of obtaining the corresponding hotspot electrical device number based on the data uploaded by the electrical device includes:

extracting the data uploaded by the electrical equipment to obtain the hot spot electrical equipment number;

packaging the hot spot electrical equipment numbers into equipment number events, and pushing the equipment number events into a preset message queue;

Monitoring the message queue based on a preset monitoring task;

and if the equipment number event is monitored, analyzing the equipment number event to obtain the hot spot electrical equipment number.

Optionally, the intelligent electricity management platform is preset with a hot spot electrical device list, the hot spot electrical device list includes a plurality of first type data items, the first type data items are in one-to-one correspondence with preset marks, the marks are in one-to-one correspondence with device numbers of the electrical devices, and the step of determining the hot spot electrical device according to the hot spot electrical device numbers includes:

inquiring according to the number of the hot spot electrical equipment to obtain a corresponding mark;

and setting a first type data item corresponding to a mark corresponding to the hot spot electrical equipment number as a first state value, wherein the first state value is used for indicating that the corresponding electrical equipment is hot spot electrical equipment.

Optionally, the intelligent electricity management platform presets a history state list, where the history state list includes a plurality of second class data items, the second class data items are in one-to-one correspondence with the marks, the second class data items are used to store history state information of the electrical device, and the step of monitoring the device state of the hot spot electrical device includes:

Inquiring from a preset distributed cache to obtain current state information corresponding to the hot spot electrical equipment according to the hot spot electrical equipment number;

acquiring corresponding historical state information from the second class data items corresponding to the historical state list according to the marks corresponding to the hot spot electrical equipment;

comparing the current state information corresponding to the hot spot electrical equipment with the historical state information corresponding to the hot spot electrical equipment to obtain a comparison result;

obtaining equipment state change information of the hot spot electrical equipment based on the comparison result;

and if the equipment state change information is equipment on-line information or equipment off-line information, pushing equipment state change prompt based on the equipment state change information of the hot spot electric equipment.

Optionally, after the step of obtaining the device state variation information of the hot spot electrical device based on the comparison result, the method further includes:

and updating the historical state information corresponding to the hot spot electrical equipment according to the current state information corresponding to the hot spot electrical equipment.

Optionally, the step of monitoring the hot spot electrical device for a device status includes:

And monitoring the equipment state of the hot spot electrical equipment based on a preset timing monitoring task.

The embodiment of the application also provides a device state management device, which is applied to the intelligent power consumption management platform and comprises:

the receiving module is used for receiving the data uploaded by the electrical equipment;

the determining module is used for determining hot spot electrical equipment based on the data uploaded by the electrical equipment;

and the monitoring module is used for monitoring the equipment state of the hot spot electrical equipment.

The embodiment of the application also provides a terminal device, which comprises a memory, a processor and a device state management program stored on the memory and capable of running on the processor, wherein the device state management program realizes the steps of the device state management method when being executed by the processor.

The embodiments of the present application also propose a computer-readable storage medium, on which a device state management program is stored, which when executed by a processor implements the steps of the device state management method as described above.

The device state management method, the device, the terminal device and the storage medium provided by the embodiment of the application are used for receiving the data uploaded by the electrical device; determining a hot spot electrical device based on the data uploaded by the electrical device; and monitoring the equipment state of the hot spot electrical equipment. Based on the scheme, the hot spot electrical equipment is determined based on the received data uploaded by the electrical equipment, the equipment state of the hot spot electrical equipment is continuously monitored, targeted equipment state management is achieved, the data interaction times between the platform and the electrical equipment in the equipment state updating process are reduced, and the equipment state updating efficiency is improved.

Drawings

FIG. 1 is a schematic diagram of functional modules of a terminal device to which a device state management apparatus of the present application belongs;

FIG. 2 is a flowchart illustrating a first exemplary embodiment of a device state management method according to the present application;

FIG. 3 is a flowchart illustrating a second exemplary embodiment of a device state management method according to the present application;

FIG. 4 is a flowchart illustrating a third exemplary embodiment of a device state management method according to the present application;

FIG. 5 is a flowchart illustrating a fourth exemplary embodiment of a device state management method according to the present application;

FIG. 6 is a schematic diagram of list management related to a device state management method of the present application;

FIG. 7 is a flowchart illustrating a fifth exemplary embodiment of a device state management method according to the present application;

FIG. 8 is a flowchart illustrating a sixth exemplary embodiment of a device state management method according to the present application;

FIG. 9 is a flowchart of a seventh exemplary embodiment of a device state management method according to the present application;

fig. 10 is a schematic diagram of a hotspot electrical device management flow related to the device state management method of the present application;

fig. 11 is a schematic diagram of a hotspot electrical device status management flow related to the device status management method of the present application.

The achievement of the objects, functional features and advantages of the present application will be further described with reference to the accompanying drawings, in conjunction with the embodiments.

Detailed Description

It should be understood that the specific embodiments described herein are for purposes of illustration only and are not intended to limit the present application.

The main solutions of the embodiments of the present application are: by receiving data uploaded by the electrical device; determining a hot spot electrical device based on the data uploaded by the electrical device; and monitoring the equipment state of the hot spot electrical equipment. Based on the scheme, the hot spot electrical equipment is determined based on the received data uploaded by the electrical equipment, the equipment state of the hot spot electrical equipment is continuously monitored, targeted equipment state management is achieved, the data interaction times between the platform and the electrical equipment in the equipment state updating process are reduced, and the equipment state updating efficiency is improved.

Specifically, referring to fig. 1, fig. 1 is a schematic functional block diagram of a terminal device to which the device state management apparatus of the present application belongs. The device state management apparatus may be an apparatus capable of device state management independent of the terminal device, which may be carried on the terminal device in the form of hardware or software. The terminal equipment can be an intelligent mobile terminal with a data processing function such as a mobile phone and a tablet personal computer, and can also be a fixed terminal equipment or a server with a data processing function.

In this embodiment, the terminal device to which the device status management apparatus belongs includes at least an output module 110, a processor 120, a memory 130, and a communication module 140.

The memory 130 stores an operating system and a device state management program, and the device state management apparatus can upload received data of the electrical device; determining device information of the hot spot electrical device based on the data uploaded by the electrical device; and monitoring the device status of the hot spot electrical device, and storing the obtained corresponding status information and other information in the memory 130; the output module 110 may be a display screen or the like. The communication module 140 may include a WIFI module, a mobile communication module, a bluetooth module, and the like, and communicates with an external device or a server through the communication module 140.

Wherein the device state management program in the memory 130, when executed by the processor, performs the steps of:

receiving data uploaded by the electrical equipment;

determining a hot spot electrical device based on the data uploaded by the electrical device;

and monitoring the equipment state of the hot spot electrical equipment.

Further, the device state management program in the memory 130, when executed by the processor, further performs the steps of:

obtaining a corresponding hot spot electrical equipment number based on the data uploaded by the electrical equipment;

And determining the hot spot electrical equipment according to the hot spot electrical equipment number.

Further, the device state management program in the memory 130, when executed by the processor, further performs the steps of:

extracting the data uploaded by the electrical equipment to obtain the hot spot electrical equipment number;

packaging the hot spot electrical equipment numbers into equipment number events, and pushing the equipment number events into a preset message queue;

monitoring the message queue based on a preset monitoring task;

and if the equipment number event is monitored, analyzing the equipment number event to obtain the hot spot electrical equipment number.

Further, the device state management program in the memory 130, when executed by the processor, further performs the steps of:

inquiring according to the number of the hot spot electrical equipment to obtain a corresponding mark;

and setting a first type data item corresponding to a mark corresponding to the hot spot electrical equipment number as a first state value, wherein the first state value is used for indicating that the corresponding electrical equipment is hot spot electrical equipment.

Further, the device state management program in the memory 130, when executed by the processor, further performs the steps of:

Inquiring from a preset distributed cache to obtain current state information corresponding to the hot spot electrical equipment according to the hot spot electrical equipment number;

acquiring corresponding historical state information from the second class data items corresponding to the historical state list according to the marks corresponding to the hot spot electrical equipment;

comparing the current state information corresponding to the hot spot electrical equipment with the historical state information corresponding to the hot spot electrical equipment to obtain a comparison result;

obtaining equipment state change information of the hot spot electrical equipment based on the comparison result;

and if the equipment state change information is equipment on-line information or equipment off-line information, pushing equipment state change prompt based on the equipment state change information of the hot spot electric equipment.

Further, the device state management program in the memory 130, when executed by the processor, further performs the steps of:

and updating the historical state information corresponding to the hot spot electrical equipment according to the current state information corresponding to the hot spot electrical equipment.

Further, the device state management program in the memory 130, when executed by the processor, further performs the steps of:

and monitoring the equipment state of the hot spot electrical equipment based on a preset timing monitoring task.

According to the scheme, the embodiment particularly receives the data uploaded by the electrical equipment; determining a hot spot electrical device based on the data uploaded by the electrical device; and monitoring the equipment state of the hot spot electrical equipment. In the embodiment, the hotspot electrical equipment is determined based on the received data uploaded by the electrical equipment, the equipment state of the hotspot electrical equipment is continuously monitored, targeted equipment state management is achieved, the data interaction times between the platform and the electrical equipment in the equipment state updating process are reduced, and the equipment state updating efficiency is improved.

Referring to fig. 2, a first embodiment of a device state management method of the present application provides a flowchart, where the device state management method is applied to an intelligent power consumption management platform, and the device state management method includes:

step S10, data uploaded by the electrical equipment are received.

Specifically, the execution main body of the embodiment may be an intelligent electricity consumption management platform, the intelligent electricity consumption management platform establishes communication connection with a plurality of electrical devices, and monitors the device state of the electrical devices establishing communication connection, and the electrical devices may be electric meters, power monitoring instruments, power distribution devices, energy storage, inversion devices, power generation devices, intelligent home devices, data acquisition devices, communication devices, energy management devices, circuit breaking devices and other devices. The state monitoring means that the on-line state or the off-line state of the electrical equipment can be monitored by the intelligent electricity management platform, so that unified management of the states of a plurality of electrical equipment is realized.

When the electrical equipment operates on line, data can be uploaded to the intelligent electricity utilization management platform, and accordingly, the intelligent electricity utilization management platform receives the data uploaded by the electrical equipment. It is noted that the intelligent electricity management platform can also adopt an active acquisition mode to acquire the data uploaded by the electrical equipment.

And step S20, determining hot spot electrical equipment based on the data uploaded by the electrical equipment.

Specifically, when the intelligent electricity management platform receives data uploaded by the electrical equipment, the electrical equipment can be known to be in an active state. And further determining the corresponding electrical equipment according to the received uploaded data, and then determining the electrical equipment as hot spot electrical equipment.

And step S30, monitoring the equipment state of the hot spot electrical equipment.

Specifically, the division of hot spot electrical devices/non-hot spot electrical devices is to screen out some electrical devices that do not have data interaction for a long time. It can be understood that the hot spot electrical device performs data interaction (i.e. uploads data) with the intelligent electricity management platform within a last preset period of time, while the non-hot spot electrical device does not perform data interaction (i.e. does not upload data) with the intelligent electricity management platform within a last preset period of time, and the time can be set according to actual requirements.

After the hot spot electrical equipment is determined, the intelligent electricity management platform continuously monitors the equipment state of the hot spot electrical equipment to obtain corresponding state information, wherein the state information comprises on-line state information and off-line state information. For non-hot spot electrical equipment, the intelligent power utilization management platform can not monitor the equipment state, or reduce the frequency of monitoring, so that the data interaction times between the platform and the electrical equipment in the equipment state updating process are reduced.

According to the scheme, the embodiment particularly receives the data uploaded by the electrical equipment; determining a hot spot electrical device based on the data uploaded by the electrical device; and monitoring the equipment state of the hot spot electrical equipment. In the embodiment, the hotspot electrical equipment is determined based on the received data uploaded by the electrical equipment, the equipment state of the hotspot electrical equipment is continuously monitored, targeted equipment state management is achieved, the data interaction times between the platform and the electrical equipment in the equipment state updating process are reduced, and the equipment state updating efficiency is improved.

Referring to fig. 3, a flowchart is provided in a second embodiment of the device status management method of the present application, based on the embodiment shown in fig. 2, step S20, determining, based on the data uploaded by the electrical device, that the hotspot electrical device is further refined, includes:

Step S201, obtaining a corresponding hot spot electrical device number based on the data uploaded by the electrical device.

Specifically, the data uploaded by the electrical equipment includes an equipment number corresponding to the electrical equipment, and the equipment number is equivalent to the identity of the electrical equipment. After receiving the data uploaded by the electrical equipment, the intelligent electricity consumption management platform further extracts the corresponding equipment number, namely the hot spot electrical equipment number.

Step S202, determining the hot spot electrical equipment according to the hot spot electrical equipment number.

Specifically, due to the identity of the hot spot electrical equipment number, the intelligent electricity management platform can determine that the corresponding electrical equipment is the hot spot electrical equipment according to the hot spot electrical equipment number, so that the state of the hot spot electrical equipment can be continuously monitored.

According to the technical scheme, the corresponding hot spot electrical equipment numbers are obtained specifically based on the data uploaded by the electrical equipment; and determining the hot spot electrical equipment according to the hot spot electrical equipment number. In this embodiment, by extracting the device number from the uploaded data, the hot spot electrical device can be quickly determined, so that the intelligent power consumption management platform is convenient for managing and monitoring the state of the hot spot electrical device.

Referring to fig. 4, a flow chart is provided in a third embodiment of the device status management method of the present application, based on the embodiment shown in fig. 3, step S201 further refines a corresponding hotspot electrical device number based on the data uploaded by the electrical device, including:

and step 2011, extracting the data uploaded by the electrical equipment to obtain the hot spot electrical equipment number.

Specifically, after receiving data uploaded by the electrical equipment, the intelligent electricity management platform extracts the data to obtain a hot spot electrical equipment number, wherein the hot spot electrical equipment number is used as an identity of the hot spot electrical equipment.

Step 2012, packaging the hot spot electrical equipment number into an equipment number event, and pushing the equipment number event to a preset message queue.

Specifically, the intelligent electricity management platform packages the hot spot electrical equipment numbers into equipment number events, and the equipment number events accord with the event specification of the message queue. Further, the equipment number event is pushed to a preset message queue, and a plurality of events including the equipment number event flow downwards in the message queue. Message queues are a communication model for asynchronous communication in a distributed system that allows interactions between different applications, services or components by sending and receiving messages without requiring direct coupling together. The message queues can help to decouple the functions of different parts, and improve the expandability, reliability and performance of the system.

And step 2013, monitoring the message queue based on a preset monitoring task.

Specifically, a plurality of events in the message queue flow downwards, and the monitoring task continuously monitors the events in the message queue, and it can be understood that the monitoring task is a consumer of the message queue, and the monitoring task can be implemented based on a timer.

And step 2014, if the equipment number event is monitored, analyzing the equipment number event to obtain the hot spot electrical equipment number.

And when the monitoring task monitors the equipment number event, further consuming the equipment number event, and analyzing the equipment number event to obtain the hot spot electrical equipment number.

According to the technical scheme, the number of the hot spot electrical equipment is obtained by extracting the data uploaded by the electrical equipment; packaging the hot spot electrical equipment numbers into equipment number events, and pushing the equipment number events into a preset message queue; monitoring the message queue based on a preset monitoring task; and if the equipment number event is monitored, analyzing the equipment number event to obtain the hot spot electrical equipment number. In the embodiment, the message queue is introduced to deconstruct the acquisition and the use of the hot spot electrical equipment numbers in the equipment state management process, so that the independence of each service (function) of the equipment state management is improved.

Referring to fig. 5, a flow chart is provided in a fourth embodiment of the device status management method of the present application, based on the embodiment shown in fig. 3, the intelligent power consumption management platform is pre-provided with a hot spot electrical device list, where the hot spot electrical device list includes a plurality of first type data items, the first type data items are in one-to-one correspondence with preset marks, the marks are in one-to-one correspondence with device numbers of the electrical devices, and step S202 determines that the hot spot electrical devices are further refined according to the hot spot electrical device numbers, including:

step S2021, inquiring and obtaining a corresponding mark according to the hot spot electrical equipment number.

Specifically, as shown in fig. 6, fig. 6 is a schematic list management diagram related to the device state management method of the present application, where the list management diagram includes a hotspot electrical device list, the hotspot electrical device list includes a plurality of first type data items, a value "0" in the first type data item represents a non-hotspot electrical device, and a value "1" represents a hotspot electrical device. The first type of data items are in one-to-one correspondence with the subscript values of fig. 6. For example, a first type of data item in the hotspot electrical device list corresponds to a subscript value of "1", and the subscript value of "1" corresponds to device a, i.e., the first type of data item in the hotspot electrical device list corresponds to device a; for another example, the second first-type data item in the hot-spot electrical device list corresponds to a subscript value "2", and the subscript value "2" corresponds to device B, i.e., the second first-type data item in the hot-spot electrical device list corresponds to device B.

The labels correspond one-to-one to the device number of the electrical device, i.e. each label actually refers to an electrical device. The marks play a role in distinguishing the electrical equipment, and the corresponding marks can be obtained according to the numbers of the hot spot electrical equipment.

In step S2022, a first type of data item corresponding to the label corresponding to the hot spot electrical device number is set to a first state value, where the first state value is used to indicate that the corresponding electrical device is a hot spot electrical device.

Specifically, after obtaining the tag corresponding to the hotspot electrical device, the intelligent power consumption management platform may set the first type of data item corresponding to the tag corresponding to the hotspot electrical device number to a first state value, for example, the first state value is represented by a value of "1", and the first type of data item is set to "1", which indicates that the electrical device corresponding to the first type of data item is the hotspot electrical device. It will be appreciated that the second status value is represented by a value of "0" indicating that the electrical device to which the first type of data item corresponds is a non-hot electrical device.

According to the scheme, the corresponding mark is obtained by inquiring according to the number of the hot spot electrical equipment; and setting a first type data item corresponding to a mark corresponding to the hot spot electrical equipment number as a first state value, wherein the first state value is used for indicating that the corresponding electrical equipment is hot spot electrical equipment. In this embodiment, a list management manner is adopted to manage the hotspot electrical devices, and a corresponding mark can be obtained by querying according to the number of the hotspot electrical devices, wherein the mark corresponds to one electrical device and corresponds to a first type of data item in the hotspot electrical device list. Therefore, only the first type of data item is required to be set to the first state value, so that the corresponding electrical equipment can be indicated to be the hot spot electrical equipment, and the hot spot electrical equipment is updated.

Further, referring to fig. 7, a flow chart is provided in a fifth embodiment of the device state management method of the present application, based on the embodiment shown in fig. 5, the intelligent electricity management platform presets a history state list, where the history state list includes a plurality of second class data items, the second class data items are in one-to-one correspondence with the marks, the second class data items are used for storing history state information of the electrical device, and step S30 further refines device state monitoring of the hot electrical device, including:

step S301, according to the number of the hotspot electrical device, inquiring from a preset distributed cache to obtain current state information corresponding to the hotspot electrical device.

In particular, the intelligent power management platform may employ distributed caching (e.g., redis, remote dictionary services) to improve performance, speed up data access, and optimize user experience. According to the number of the hot spot electrical equipment, the current state information corresponding to the hot spot electrical equipment can be inquired from the distributed cache. The current state information may represent that the hot spot electrical device is currently in an on-line state or an off-line state based on a number, character, english form. For example, the hotspot electrical device is currently on-line, which may be represented by a value of "1"; or the hot spot electrical device is currently off-line, which may be represented by a value of "0".

Step S302, according to the mark corresponding to the hot spot electrical device, corresponding historical state information is obtained from the second class data item corresponding to the historical state list.

Specifically, the history state list includes second class data items corresponding to a plurality of electrical devices, and the second class data items of the hot electrical devices are also located therein. The data in the second class data item can be regarded as history state information, and corresponding history state information is obtained from the second class data item corresponding to the history state list according to the mark (which can be a subscript value) corresponding to the hot spot electrical equipment. The historical state information can be based on numbers, characters and English to indicate that the hot spot electrical equipment is in an on-line state or an off-line state at the last monitoring moment.

Fig. 6 is a schematic diagram of list management related to the device state management method of the present application, where the history state list includes a plurality of second type data items, and values in the second type data items may be regarded as history state information, where "0" represents that the hot spot electrical device is in an offline state at a last monitoring time, and "1" represents that the hot spot electrical device is in an online state at the last monitoring time. The second type data items are in one-to-one correspondence with the subscript values (marks) of fig. 6, for example, the first second type data item in the history state list corresponds to the subscript value "1", and the subscript value "1" corresponds to the device a, i.e., the first second type data item in the history state list corresponds to the device a; for example, the second type data item in the history state list corresponds to the subscript value "2", and the subscript value "2" corresponds to the device B, i.e., the second type data item in the history state list corresponds to the device B

The labels correspond one-to-one to the device number of the electrical device, i.e. each label actually refers to an electrical device. Because the marks play a role in distinguishing the electrical equipment, corresponding second-class data items can be determined from the history state list according to the marks corresponding to the hot-spot electrical equipment, and corresponding history state information is acquired from the second-class data items corresponding to the hot-spot electrical equipment.

Step S303, comparing the current state information corresponding to the hot spot electrical device with the historical state information corresponding to the hot spot electrical device, to obtain a comparison result.

Specifically, the current state information indicates that the hot spot electrical device is currently in an on-line state or an off-line state, and the historical state information indicates that the hot spot electrical device is in the on-line state or the off-line state at the last monitoring time. Further, the current state information corresponding to the hot spot electrical equipment is compared with the historical state information corresponding to the hot spot electrical equipment, so that whether equipment state change occurs between the last monitoring time and the current time of the hot spot electrical equipment can be known, and further a comparison result is obtained. The comparison result may indicate that the hotspot electrical device is in an online state at the two times, may indicate that the hotspot electrical device is in an offline state at the two times, may indicate that the hotspot electrical device has undergone a process from an online state to an offline state at the two times, and may indicate that the hotspot electrical device has undergone a process from an offline state to an online state at the two times.

As shown in fig. 6, the comparison result may have the following three types:

comparison result one: the current state information is the same as the history state information, for example, the values corresponding to the current state information and the history state information are both "0" or both "1". The results indicate that the device status of the hot spot electrical device is unchanged.

And a comparison result II: the current state information is different from the historical state information, the value corresponding to the current state information is 1, and the value corresponding to the historical state information is 0. The results indicate that the hot spot electrical device experienced a device on-line.

And (3) comparing the result III: the current state information is different from the historical state information, the value corresponding to the current state information is 0, and the value corresponding to the historical state information is 1. The results indicate that the hot spot electrical device underwent device offline.

And step S304, obtaining equipment state change information of the hot spot electrical equipment based on the comparison result.

Specifically, the device state change information may be three types of state holding information, device on-line information, and device off-line information. If the comparison result shows that the state of the hot spot electrical equipment does not change between the last monitoring time and the current time, state maintaining information can be obtained; if the comparison result shows that the hot spot electrical equipment goes through the process from the online state to the offline state between the last monitoring time and the current time, the hot spot electrical equipment is taken off line, and equipment off-line information is obtained; if the comparison result shows that the hot spot electrical equipment is in the process from the off-line state to the on-line state between the last monitoring time and the current time, the hot spot electrical equipment can be known to be on-line, and the equipment on-line information is obtained.

In step S305, if the device state change information is device on-line information or device off-line information, a device state change prompt is pushed based on the device state change information of the hot-spot electrical device.

Specifically, if the device state change information is device on-line information or device off-line information, it indicates that the hotspot electrical device experiences device state change, and at this time, the device state change prompt may be further pushed by the intelligent power consumption management platform. For example, when the device state change information corresponding to the hot spot electrical device a is device on-line information, pushing a text-form device state change prompt "the hot spot electrical device a is on-line"; when the equipment state change information corresponding to the hot spot electric equipment B is equipment offline information, the equipment state change in the form of push text prompts that the hot spot electric equipment B is offline. Similarly, the device state change prompt can also adopt one or more forms of voice, image, video and the like besides text, and the pushing mode can be voice broadcasting, popup window, short message or other modes.

More specifically, the intelligent electricity management platform provides a man-machine interaction interface, and after obtaining the equipment state change information of the hot spot electrical equipment, the intelligent electricity management platform can push equipment state change prompt based on the equipment state change information through the man-machine interaction interface; or the intelligent electricity management platform establishes communication connection with the mobile terminal used by the related manager, and after obtaining the equipment state change information of the hot spot electric equipment, the intelligent electricity management platform can push the equipment state change prompt based on the equipment state change information to the mobile terminal.

According to the technical scheme, the current state information corresponding to the hot spot electrical equipment is obtained by inquiring from a preset distributed cache according to the number of the hot spot electrical equipment; acquiring corresponding historical state information from the second class data items corresponding to the historical state list according to the marks corresponding to the hot spot electrical equipment; comparing the current state information corresponding to the hot spot electrical equipment with the historical state information corresponding to the hot spot electrical equipment to obtain a comparison result; obtaining equipment state change information of the hot spot electrical equipment based on the comparison result; and if the equipment state change information is equipment on-line information or equipment off-line information, pushing equipment state change prompt based on the equipment state change information of the hot spot electric equipment. In this embodiment, the state change of the hotspot electrical device is managed by adopting a list management manner, and the device state change information of the hotspot electrical device can be obtained by comparing the current state information corresponding to the hotspot electrical device with the history state information, and the corresponding device state change prompt is pushed when the hotspot electrical device is on line or off line, so that the relevant manager can timely acquire the state change of the hotspot electrical device.

Further, referring to fig. 8, a flowchart is provided in a sixth embodiment of the device status management method according to the present application, based on the embodiment shown in fig. 7, step S304 further includes, after obtaining the device status change information of the hot spot electrical device based on the comparison result:

step S306, updating the historical state information corresponding to the hotspot electrical device according to the current state information corresponding to the hotspot electrical device.

Specifically, after the device state change information is obtained, when the current state information corresponding to the hot spot electrical device loses timeliness, the historical state information corresponding to the hot spot electrical device can be updated according to the current state information corresponding to the hot spot electrical device.

For example, the current state information corresponding to the hot spot electric device is denoted as "online", the historical state information corresponding to the hot spot electric device is denoted as "offline", and after the device state variation information is obtained, the historical state information may be updated according to the current state information, so that the historical state information corresponding to the hot spot electric device is changed to "online". Here "online" may be replaced with a value of "1" and "offline" may be replaced with a value of "0".

According to the scheme, the historical state information corresponding to the hot spot electrical equipment is updated according to the current state information corresponding to the hot spot electrical equipment. In the embodiment, considering that the current state information has timeliness, after the equipment state change information is obtained, the historical state information corresponding to the hot spot electrical equipment is updated according to the current state information corresponding to the hot spot electrical equipment. In this way, the historical state information can be ensured to adapt to the equipment state change of the hot spot electrical equipment, so that the equipment state of the hot spot electrical equipment can be judged at the next monitoring moment.

Further, referring to fig. 9, a flowchart is provided in a seventh embodiment of the device status management method, based on the embodiment shown in fig. 2, step S30 further refines the device status monitoring of the hotspot electrical device, including:

step S307, performing device status monitoring on the hot spot electrical device based on a preset timing monitoring task.

Specifically, a timing monitoring task can be set according to actual scene requirements, and the timing monitoring task can monitor the equipment state of the hot spot electrical equipment based on a preset time interval, so that corresponding state information is obtained. It can be appreciated that if the time interval of the timing monitoring task is small, the state information can be ensured to be updated more timely; if the time interval of the timing monitoring task is larger, the interaction times between the intelligent electricity utilization management platform and the hot spot electric equipment can be reduced, and further the communication resources or calculation power of the platform can be saved.

According to the scheme, the equipment state of the hot spot electrical equipment is monitored based on the preset timing monitoring task. According to the embodiment, the device state of the hot spot electrical device is monitored through the timing monitoring task, the requirements of different scenes can be met through adjusting the time interval of the timing monitoring task, and the controllability of the device state management process is improved.

Further, an eighth embodiment of the device state management method of the present application is provided in conjunction with fig. 2, fig. 6, fig. 10, and fig. 11, fig. 10 is a schematic diagram of a hotspot electrical device management flow related to the device state management method of the present application, and fig. 11 is a schematic diagram of a hotspot electrical device state management flow related to the device state management method of the present application.

Firstly, the intelligent electricity management platform establishes communication connection with a plurality of electrical devices, and the active electrical devices upload data to the intelligent electricity management platform. Correspondingly, the intelligent electricity management platform extracts the data uploaded by the electrical equipment to obtain the hot spot electrical equipment number. Further, the intelligent electricity management platform adds the hot spot electrical equipment number into the message queue for decoupling, then takes the hot spot electrical equipment number out of the message queue, determines a corresponding lower standard value according to the hot spot electrical equipment number, and sets the numerical value of a hot spot electrical equipment list corresponding to the lower standard value to be 1, wherein the 1 is used for indicating that the electrical equipment is hot spot electrical equipment.

In another aspect, a timing monitoring task is initiated to take a pair of values with the same subscript value from a list of hot spot electrical devices, a list of historical states, respectively, it being understood that the pair of values are from the same electrical device. Then, among a pair of values, it is determined whether the value from the hot spot electric device list is "1" (i.e., whether the electric device is a hot spot electric device or not). If the value of the hot spot electrical equipment list is not '1', the fact that the electrical equipment is not the hot spot electrical equipment is indicated, the electrical equipment does not need to be monitored in the state, a pair of values corresponding to another index value is returned to the previous step, and subsequent monitoring is conducted. If the value of the hot spot electrical device list is "1", it indicates that the electrical device is a hot spot electrical device, and the corresponding hot spot electrical device number needs to be further determined according to the subscript value.

After determining the number of the hot spot electrical equipment, the current state value corresponding to the corresponding hot spot electrical equipment can be obtained from the distributed cache according to the number of the hot spot electrical equipment, wherein the current state value is '1' and is offline, and the current state value is '0'.

Further, comparing the current state value corresponding to the hot spot electrical equipment with the value corresponding to the historical state list, and judging whether the current state value is different. If the judging result shows that the equipment states corresponding to the hot spot electrical equipment are not changed, the equipment states of other electrical equipment can be monitored in a returning mode. If the judging result shows that the equipment states corresponding to the hot spot electrical equipment are different, the equipment state change is indicated, and whether the type of the equipment state change is online or online can be further determined.

If the type of device state change corresponding to the hotspot electrical device is online, a relevant device online prompt may be pushed, and other actions related to device online may be performed. If the type of device state change corresponding to the hotspot electrical device is offline, a relevant device offline prompt may be pushed, and other actions related to device offline may be performed.

Finally, the values of the historical state list may be updated based on the current state values.

In the embodiment, the hotspot electrical equipment is determined based on the received data uploaded by the electrical equipment, the equipment state of the hotspot electrical equipment is continuously monitored, targeted equipment state management is achieved, the data interaction times between the platform and the electrical equipment in the equipment state updating process are reduced, and the equipment state updating efficiency is improved.

In addition, the embodiment of the application also provides a device state management device, which is applied to the intelligent power consumption management platform and comprises:

the receiving module is used for receiving the data uploaded by the electrical equipment;

the determining module is used for determining hot spot electrical equipment based on the data uploaded by the electrical equipment;

And the monitoring module is used for monitoring the equipment state of the hot spot electrical equipment.

The principle and implementation process of the device state management in this embodiment are referred to the above embodiments, and are not described herein.

In addition, the embodiment of the application also provides a terminal device, which comprises a memory, a processor and a device state management program stored on the memory and capable of running on the processor, wherein the device state management program realizes the steps of the device state management method when being executed by the processor.

Because the device state management program is executed by the processor, all the technical schemes of all the embodiments are adopted, and therefore, the device state management program at least has all the beneficial effects brought by all the technical schemes of all the embodiments, and is not described in detail herein.

In addition, the embodiment of the application also provides a computer readable storage medium, wherein the computer readable storage medium stores a device state management program, and the device state management program realizes the steps of the device state management method when being executed by a processor.

Because the device state management program is executed by the processor, all the technical schemes of all the embodiments are adopted, and therefore, the device state management program at least has all the beneficial effects brought by all the technical schemes of all the embodiments, and is not described in detail herein.

Compared with the prior art, the device state management method, the device, the terminal device and the storage medium provided by the embodiment of the application receive the data uploaded by the electrical device; determining a hot spot electrical device based on the data uploaded by the electrical device; and monitoring the equipment state of the hot spot electrical equipment. Based on the scheme, the hot spot electrical equipment is determined based on the received data uploaded by the electrical equipment, the equipment state of the hot spot electrical equipment is continuously monitored, targeted equipment state management is achieved, the data interaction times between the platform and the electrical equipment in the equipment state updating process are reduced, and the equipment state updating efficiency is improved.

It should be noted that, in this document, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or system that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or system. Without further limitation, an element defined by the phrase "comprising one … …" does not exclude the presence of other like elements in a process, method, article, or system that comprises the element.

The foregoing embodiment numbers of the present application are merely for describing, and do not represent advantages or disadvantages of the embodiments.

From the above description of the embodiments, it will be clear to those skilled in the art that the above-described embodiment method may be implemented by means of software plus a necessary general hardware platform, but of course may also be implemented by means of hardware, but in many cases the former is a preferred embodiment. Based on such understanding, the technical solution of the present application may be embodied essentially or in a part contributing to the prior art in the form of a software product stored in a storage medium (e.g. ROM/RAM, magnetic disk, optical disk) as above, including several instructions for causing a terminal device (which may be a mobile phone, a computer, a server, a controlled terminal, or a network device, etc.) to perform the method of each embodiment of the present application.

The foregoing description is only of the preferred embodiments of the present application, and is not intended to limit the scope of the claims, and all equivalent structures or equivalent processes using the descriptions and drawings of the present application, or direct or indirect application in other related technical fields are included in the scope of the claims of the present application.

Claims (7)

1. The device state management method is applied to an intelligent power consumption management platform, and comprises the following steps:

receiving data uploaded by the electrical equipment;

determining a hot spot electrical device based on the data uploaded by the electrical device;

monitoring the equipment state of the hot spot electrical equipment;

the step of determining a hot spot electrical device based on the data uploaded by the electrical device comprises:

obtaining a corresponding hot spot electrical equipment number based on the data uploaded by the electrical equipment;

determining the hot spot electrical equipment according to the hot spot electrical equipment number;

the intelligent electricity management platform is pre-provided with a hot spot electrical equipment list, the hot spot electrical equipment list comprises a plurality of first type data items, the first type data items are in one-to-one correspondence with preset marks, the marks are in one-to-one correspondence with equipment numbers of the electrical equipment, and the step of determining the hot spot electrical equipment according to the hot spot electrical equipment numbers comprises the following steps:

inquiring according to the number of the hot spot electrical equipment to obtain a corresponding mark;

setting a first type of data item corresponding to a mark corresponding to the hot spot electrical equipment number as a first state value, wherein the first state value is used for indicating that the corresponding electrical equipment is hot spot electrical equipment;

The intelligent electricity management platform is preset with a history state list, the history state list comprises a plurality of second class data items, the second class data items are in one-to-one correspondence with the marks, the second class data items are used for storing history state information of the electrical equipment, and the step of monitoring the equipment state of the hot spot electrical equipment comprises the following steps:

inquiring from a preset distributed cache to obtain current state information corresponding to the hot spot electrical equipment according to the hot spot electrical equipment number;

acquiring corresponding historical state information from the second class data items corresponding to the historical state list according to the marks corresponding to the hot spot electrical equipment;

comparing the current state information corresponding to the hot spot electrical equipment with the historical state information corresponding to the hot spot electrical equipment to obtain a comparison result;

obtaining equipment state change information of the hot spot electrical equipment based on the comparison result;

and if the equipment state change information is equipment on-line information or equipment off-line information, pushing equipment state change prompt based on the equipment state change information of the hot spot electric equipment.

2. The device state management method of claim 1, wherein the step of obtaining the corresponding hotspot electrical device number based on the data uploaded by the electrical device comprises:

Extracting the data uploaded by the electrical equipment to obtain the hot spot electrical equipment number;

packaging the hot spot electrical equipment numbers into equipment number events, and pushing the equipment number events into a preset message queue;

monitoring the message queue based on a preset monitoring task;

and if the equipment number event is monitored, analyzing the equipment number event to obtain the hot spot electrical equipment number.

3. The device state management method according to claim 1, wherein after the step of obtaining device state variation information of the hotspot electrical device based on the comparison result, further comprising:

and updating the historical state information corresponding to the hot spot electrical equipment according to the current state information corresponding to the hot spot electrical equipment.

4. The device state management method of claim 1, wherein the step of device state monitoring the hotspot electrical device comprises:

and monitoring the equipment state of the hot spot electrical equipment based on a preset timing monitoring task.

5. A device state management apparatus, wherein the device state management apparatus is applied to an intelligent power consumption management platform, the device state management apparatus comprising:

The receiving module is used for receiving the data uploaded by the electrical equipment;

the determining module is used for determining hot spot electrical equipment based on the data uploaded by the electrical equipment;

the monitoring module is used for monitoring the equipment state of the hot spot electrical equipment;

the determining module is further configured to obtain a corresponding hotspot electrical device number based on the data uploaded by the electrical device; determining the hot spot electrical equipment according to the hot spot electrical equipment number;

the intelligent electricity management platform is pre-provided with a hot spot electric equipment list, wherein the hot spot electric equipment list comprises a plurality of first type data items, the first type data items are in one-to-one correspondence with preset marks, and the marks are in one-to-one correspondence with equipment numbers of the electric equipment; the determining module is further used for inquiring and obtaining a corresponding mark according to the number of the hot spot electrical equipment; setting a first type of data item corresponding to a mark corresponding to the hot spot electrical equipment number as a first state value, wherein the first state value is used for indicating that the corresponding electrical equipment is hot spot electrical equipment;

the intelligent electricity management platform is preset with a history state list, the history state list comprises a plurality of second-class data items, the second-class data items are in one-to-one correspondence with the marks, and the second-class data items are used for storing history state information of the electrical equipment; the monitoring module is further used for inquiring from a preset distributed cache according to the number of the hot spot electrical equipment to obtain current state information corresponding to the hot spot electrical equipment; acquiring corresponding historical state information from the second class data items corresponding to the historical state list according to the marks corresponding to the hot spot electrical equipment; comparing the current state information corresponding to the hot spot electrical equipment with the historical state information corresponding to the hot spot electrical equipment to obtain a comparison result; obtaining equipment state change information of the hot spot electrical equipment based on the comparison result; and if the equipment state change information is equipment on-line information or equipment off-line information, pushing equipment state change prompt based on the equipment state change information of the hot spot electric equipment.

6. A terminal device, characterized in that it comprises a memory, a processor and a device state management program stored on the memory and executable on the processor, which device state management program, when executed by the processor, implements the steps of the device state management method according to any of claims 1-4.

7. A computer readable storage medium, wherein a device state management program is stored on the computer readable storage medium, which when executed by a processor, implements the steps of the device state management method according to any of claims 1-4.