CN114336971B - Power information processing system and method and power distribution equipment - Google Patents

Abstract

The application provides an electric power information processing system, a method and power distribution equipment, wherein the system comprises: the monitoring equipment is used for receiving a data instruction sent by the terminal, carrying the data instruction to the power line through the first power carrier module, receiving first feedback information and/or second feedback information from the power line through the first power carrier module, and returning the first feedback information and/or the second feedback information to the terminal, wherein the data instruction carries the unique identifier of the target equipment; the power distribution equipment is connected with the monitoring equipment and used for receiving the data instruction from the power line through the second power carrier module and sending first feedback information to the power line according to the unique identifier of the target equipment in the data instruction; the power utilization equipment is connected with the power distribution equipment and used for receiving the data instruction from the power line through the third power carrier module and sending second feedback information to the power line based on the data instruction. The present electric power wiring of this scheme at utmost utilizes and realizes the energy management and control.

Description

Power information processing system and method and power distribution equipment

Technical Field

The present application relates to the field of power grid technologies, and in particular, to a power information processing system, a power information processing method, and a power distribution device.

Background

With the development of society, energy problems become more and more important, and smart homes and 'green' energy application become the main strategic points of various companies. In this case, energy application control is important. In the prior art, energy application control is mainly carried out in two modes of a secondary signal weak current control system and a wireless intelligent control system.

However, the secondary weak current signal control system needs to additionally increase a control box, which increases the difficulty of laying the line; the wireless intelligent control system has information potential safety hazards due to the fact that wireless electric waves are adopted to transmit data. Meanwhile, the anti-interference capability of the secondary weak current signal control system and the wireless intelligent control system is poor.

Disclosure of Invention

An object of the embodiments of the present application is to provide an electric power information processing system, an electric power information processing method, and a power distribution device, which utilize the existing electric power wiring to the maximum extent to realize energy management and control, and improve the anti-interference capability.

On one hand, the application provides an electric power information processing system which comprises monitoring equipment, power distribution equipment and electric equipment, wherein the power distribution equipment is connected with the monitoring equipment; the monitoring equipment is used for receiving a data instruction sent by the terminal and carrying the data instruction to a power line through the first power carrier module, and the data instruction carries a unique identifier of the target equipment; the power distribution equipment is used for receiving the data instruction from the power line through the second power carrier module and sending first feedback information to the power line according to the unique identification of the target equipment in the data instruction; the electric equipment is used for receiving a data instruction from the power line through the third power carrier module and sending second feedback information to the power line based on the data instruction; the monitoring equipment is further used for receiving the first feedback information and/or the second feedback information from the power line through the first power carrier module and returning the first feedback information and/or the second feedback information to the terminal.

In one embodiment, the data instructions include a state data collection instruction;

according to the unique identification of the target equipment in the data instruction, sending first feedback information to the power line, and the method comprises the following steps:

and the power distribution equipment compares the unique identifier of the target equipment in the data instruction with the identifier of the power distribution equipment, collects the current state information of the power distribution equipment when the unique identifier of the target equipment is consistent with the identifier of the power distribution equipment, and takes the current state information of the power distribution equipment as first feedback information to be carried on a power line.

In one embodiment, the power information processing system further comprises:

and when the unique identifier of the target equipment is inconsistent with the identifier of the power distribution equipment, the power distribution equipment transmits the data instruction on the power line continuously through the second power carrier module.

In one embodiment, the data instructions include a state data collection instruction;

sending second feedback information to the power line based on the data instruction, comprising:

and the electric equipment compares the unique identifier of the target equipment in the data instruction with the identifier of the electric equipment, collects the current state information of the electric equipment when the unique identifier of the target equipment is consistent with the identifier of the electric equipment, and loads the current state information of the electric equipment as second feedback information onto the power line.

In one embodiment, the sending the second feedback information to the power line based on the data command further comprises:

when the unique identifier of the target device is consistent with the identifier of the electric equipment, if the current state information of the electric equipment cannot be collected, the electric equipment is determined to be in a disconnected state, and the information that the electric equipment is in the disconnected state is carried on the power line as second feedback information through the third power carrier module.

In one embodiment, the data instructions include resource information configuration instructions;

the monitoring equipment is further used for distributing power resource information for the power distribution equipment and the electric equipment through respective power carrier modules based on the resource information configuration instructions.

In one embodiment, the power information processing system further comprises:

the power distribution equipment is also used for reporting the abnormal state information to the monitoring equipment through the second power carrier module;

the monitoring equipment is also used for controlling the power distribution equipment to be disconnected according to the abnormal state information.

On the other hand, the application also provides a power information processing method, which is applied to the power information processing system, and the power information processing method comprises the following steps:

receiving a data instruction sent by a terminal through monitoring equipment, and carrying the data instruction to a power line through a first power line carrier module, wherein the data instruction carries a unique identifier of target equipment;

receiving a data instruction from the power line through a second power carrier module, and sending first feedback information to the power line through the power distribution equipment according to the unique identifier of the target equipment carried in the data instruction;

receiving a data instruction from the power line through a third power carrier module, and sending second feedback information to the power line through the electric equipment based on the data instruction;

and receiving the first feedback information and/or the second feedback information from the power line through a first power carrier module of the monitoring equipment, and returning the first feedback information and/or the second feedback information to the terminal.

Further, the present application also provides an electronic device, which includes:

a processor;

a memory for storing processor-executable instructions;

wherein the processor is configured to execute the above power information processing method.

In addition, the application also provides a power distribution device, wherein the power distribution device comprises a power carrier module, a processing module and a power distribution module; the power carrier module, the processing module and the power distribution module are all arranged in the power distribution equipment; the processing module is connected with the power carrier module; one end of the power distribution module is connected with the processing module, and the other end of the power distribution module is connected with the power carrier module; the power line carrier module is used for receiving the state data collecting instruction and transmitting the state data collecting instruction to the processing module; the processing module is used for receiving the state data collection instruction transmitted by the power carrier module, comparing the unique identifier of the target equipment in the state data collection instruction with the identifier of the power distribution equipment, and collecting the current state information of the power distribution equipment when the unique identifier of the target equipment is consistent with the identifier of the power distribution equipment; the power distribution module is used for providing current state information of the power distribution equipment; the power carrier module is also used for receiving the resource information configuration instruction and transmitting the resource information configuration instruction to the power distribution module; the power distribution module is also used for receiving the resource information configuration instruction transmitted by the power carrier module.

The scheme of the application provides an electric power information processing system which comprises monitoring equipment, power distribution equipment and electric equipment, wherein the monitoring equipment, the power distribution equipment and the electric equipment are all provided with electric power carrier modules; the monitoring equipment can collect the state information of the electric equipment and the power distribution equipment through the corresponding power carrier modules, and transmit the state information through the existing power wiring. Therefore, the electric power information processing system can utilize the existing electric power wiring to the maximum extent to realize energy management and control, reduces the laying difficulty of lines, and improves the anti-interference capacity of the system.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present application, the drawings required to be used in the embodiments of the present application will be briefly described below.

Fig. 1 is a schematic diagram of an electrical information processing system according to an embodiment of the present application;

FIG. 2 is a schematic diagram of a monitoring device according to an embodiment of the present application;

FIG. 3 is a schematic diagram of a power distribution apparatus provided in an embodiment of the present application;

fig. 4 is a schematic diagram of an electrical device provided in an embodiment of the present application;

FIG. 5 is a schematic diagram of a power information processing system according to an embodiment of the present application;

FIG. 6 is a schematic diagram illustrating an operation of an electrical information processing system according to an embodiment of the present disclosure;

fig. 7 is a schematic flowchart of a power information processing method according to an embodiment of the present application;

fig. 8 is a schematic structural diagram of an electronic device according to an embodiment of the present application.

Detailed Description

The technical solutions in the embodiments of the present application will be described below with reference to the drawings in the embodiments of the present application.

Like reference numbers and letters refer to like items in the following figures, and thus, once an item is defined in one figure, it need not be further defined or explained in subsequent figures. Meanwhile, in the description of the present application, the terms "first", "second", and the like are used only for distinguishing the description, and are not construed as indicating or implying relative importance.

Fig. 1 is a schematic diagram of an electrical information processing system according to an embodiment of the present disclosure. Referring to fig. 1, the power information processing system 100 includes a monitoring device 110, a power distribution device 120, and a power consuming device 130. Wherein, the power distribution device 120 is connected with the monitoring device 110; the consumer 130 is connected to the distribution device 120.

Several power distribution devices 120 may be included in the power information processing system 100, with each of the several power distribution devices 120 being connected to the monitoring device 110. Several consumers of electricity 130 may be included in the power information processing system 100, and each of the several consumers of electricity 130 is connected to the power distribution device 120. For convenience of description, fig. 1 illustrates an example in which the power information processing system 100 includes 3 power distribution devices 120 and 3 power consuming devices 130. Wherein, the power distribution device 120 is connected with the monitoring device 110 through the power line 140; the consumer 130 and the distribution device 120 are connected via a power line 140.

Referring to fig. 1, the power information processing system 100 may be connected with a terminal 200. Specifically, the terminal 200 may be connected through the monitoring device 110. Specifically, the terminal 200 may be an intelligent device such as a desktop computer.

In an operation process, when power maintenance personnel performs power management and control, the data instruction can be sent to the power information processing system 100 through the terminal 200; the power information processing system 100 may send the corresponding power parameter to the terminal 200 according to the data command, so that the maintenance personnel can maintain the power distribution equipment 120 and the electric equipment 130 according to the content of the power parameter.

Fig. 2 is a schematic view of a monitoring device according to an embodiment of the present application. Referring to fig. 2, the monitoring device 110 is provided with a first power carrier module 111, a first processing module 112 and a communication module 113. The first processing module 112 is connected to the first power carrier module 111; one end of the communication module 113 is connected to the first power carrier module 111, and the other end of the communication module 113 is connected to the first processing module 112. The first power carrier module 111 is configured to transmit a data command; the first processing module 112 is configured to process the data instruction; the communication module 113 is configured to receive a data instruction sent by the terminal 200; the specific usage of the first power carrier module 111, the first processing module 112 and the communication module 113 is shown in fig. 6.

In one embodiment, the monitoring device 110 may add or subtract corresponding functional modules as needed. For example, the monitoring device 110 may add a key module according to the requirement.

Fig. 3 is a schematic diagram of a power distribution apparatus according to an embodiment of the present application. Referring to fig. 3, the power distribution device 120 is provided with a second power carrier module 121, a second processing module 122 and a power distribution module 123. The second processing module 122 is connected to the second power carrier module 121; one end of the power distribution module 123 is connected to the second power carrier module 121, and the other end of the power distribution module 123 is connected to the second processing module 122. The second power carrier module 121 is configured to transmit a corresponding data command; the second processing module 122 is configured to process the data instruction; the power distribution module 123 is used to perform the main functions of the power distribution device 120; the power distribution module 123 stores state information of the power distribution device 120, where the state information may be on/off state information, fault information, auxiliary contact information, energy consumption information, and the like of the power distribution device. The specific usage of the second power carrier module 121, the second processing module 122 and the power distribution module 123 is detailed in the embodiment of fig. 6.

In one embodiment, the power distribution device 120 may add or subtract corresponding functional modules as needed.

Fig. 4 is a schematic view of an electric device according to an embodiment of the present disclosure. Referring to fig. 4, the electric device 130 is provided with a third power carrier module 131, a third processing module 132 and an electric module 133. The third processing module 132 is connected to the third power carrier module 131; one end of the power consuming module 133 is connected to the third power carrier module 131, and the other end of the power consuming module 133 is connected to the third processing module 132. The third power carrier module 131 is configured to transmit a corresponding data command; the third processing module 122 is configured to process the data instruction; the power utilization module 133 is used to perform the main functions of the power utilization apparatus 130; the state information of the electric device 130 stored in the electric module 133 may be on-off state information, fault information, power loss, and the like. The specific usage of the third power carrier module 131, the third processing module 132 and the power utilization module 133 is shown in fig. 6.

In one embodiment, the electric device 130 may add or subtract corresponding functional modules according to the requirement.

For example, the first power carrier module 111, the second power carrier module 121, and the third power carrier module 131 may be composed of power carrier communication chips, and the model of the power carrier communication chip may be HT8550.

Fig. 5 is a schematic diagram of an electrical information processing system according to an embodiment of the present application. Referring to fig. 5, the power distribution device 120 may be an electrical device with a power carrier module, such as a circuit breaker, a leakage protector, a self-recovery overvoltage/undervoltage protector, and the like; the electric equipment 130 may be a central air conditioner, a dimming lamp, a television, a household socket, a lamp, an air conditioner, and other electric terminal equipment with a power line carrier module. Referring to fig. 2, a plurality of electrical devices 130 may be connected to the same distribution device 120 or may be connected to different distribution devices 120.

The power distribution device 120 may protect the electrical device 130 and monitor the operating status of the electrical device 130.

Fig. 6 is a schematic view of a work flow of the power information processing system according to an embodiment of the present application. In fig. 6, the operation flow of the power information processing system 100 is explained by taking an example in which the power information processing system includes only 1 power distribution device 120 and 1 power consumption device 130. Referring to fig. 6, the monitoring device 110 may be connected with the terminal 200 through the communication module 113.

When the power maintenance person performs power maintenance, a data command may be transmitted to the monitoring apparatus 110 through the terminal 200. The data instructions are used to collect relevant power parameters of the powered device 130 and/or the power distribution device 120. After receiving the data command, the monitoring device 110 may mount the data command on the power line 140 through the first power carrier module 111. The data instruction carries a unique identifier of a target device, and the target device is the power distribution device 120 and/or the electrical device 130, which the maintenance personnel need to collect data.

In an embodiment, the data instruction may carry unique identifiers of a plurality of target devices, and the target devices may be the power distribution device 120 or the electrical device 130.

The power distribution device 120 may receive the data command from the power line 140 through the second power carrier module 121, and send the first feedback information to the power line 140 according to the unique identifier of the target device in the data command.

The electric device 130 may receive the data command from the power line 140 through the third power carrier module 131, and send the second feedback information to the power line 140 based on the data command.

At this time, the monitoring device 110 may receive the first feedback information and/or the second feedback information from the power line 140 through the first power carrier module 111 and return the first feedback information and/or the second feedback information to the terminal 200.

In the application, the power information processing system 100 sets the power carrier modules in the monitoring device 110, the power distribution device 120 and the electric device 130, so that the existing power wiring is utilized to the maximum extent to realize energy management and control, and the anti-interference capability is improved.

In one embodiment, the data instructions include a state data collection instruction. The status data collection instructions may be used to collect current status information of the power distribution device 120 and/or the powered device 130, among other things.

In an operation process, after the power maintenance personnel sends the status data collection instruction to the monitoring device 110 through the terminal 200, the monitoring device 110 receives the status data collection instruction through the communication module 113, and the communication module 113 transmits the status data collection instruction to the first processing module 112. The first processing module 112 analyzes and processes the status data collection instruction, and sends the status data collection instruction to the first power carrier module 111 after the processing is completed. The state data collection command is converted from a digital signal to an analog signal by the first power carrier module 111, and the converted state data collection command is loaded on the power line 140.

The power distribution device 120 may receive the status data collection instruction from the power line 140 through the second power carrier module 121, convert the status data collection instruction from an analog signal to a digital signal through the second power carrier module 121, and transmit the status data collection instruction to the second processing module 122 after the conversion is successful. The second processing module 122 compares the unique identifier of the target device in the status data collection instruction with the identifier of the power distribution device 120, and when the unique identifier of the target device is consistent with the identifier of the power distribution device 120, the second processing module 122 collects current status information of the power distribution device 120 from the power distribution module 123, and the current status information is used as first feedback information after the collection is successful.

In an embodiment, when the unique identifier of the target device is consistent with the identifier of the power distribution device 120 but the current status information of the power distribution device 120 is not collected, it may be determined that the power distribution device 120 is in the disconnected state, and the second processing module 122 uses the information that the power distribution device 120 is in the disconnected state as the first feedback information.

For example, when the leakage protector and the self-recovery overvoltage/undervoltage protector are disconnected, the disconnection state information of the leakage protector and the self-recovery overvoltage/undervoltage protector can be used as the first feedback information. When the leakage protector is closed and the self-recovery type overvoltage and undervoltage protector is disconnected, the current state information of the leakage protector is collected to serve as first feedback information, and meanwhile the disconnection state information of the self-recovery type overvoltage and undervoltage protector is used as the first feedback information. The leakage protector and the self-recovery overvoltage/undervoltage protector are both power distribution equipment 120 with a power carrier module.

After the first feedback information is successfully collected, the second processing module 122 may send the feedback information to the second power carrier module 121, the second power carrier module 121 converts the first feedback information into an analog signal, and the first feedback information is piggybacked onto the power line 140 after the conversion is successful. The monitoring device 110 obtains the first feedback information from the power line 140 through the first power carrier module 111, converts the first feedback information into a digital signal, and returns the first feedback information to the terminal 200 through the first processing module 112 and the communication module 113 after the first feedback information is successfully converted.

The maintenance personnel can maintain the power distribution equipment 120 according to the first feedback information, and when the power distribution equipment 120 is found to be in fault, the fault can be timely eliminated, so that the power distribution equipment 120 can be recovered to operate.

In an embodiment, when the unique identification of the target device is not consistent with the identification of the power distribution device, the power distribution device 120 may continue transmitting the status data collection instruction on the power line 140 through the second power carrier module 121. At this time, the power distribution device 120 acts as a relay and directly transmits the status data collection command to the power line 140, so that the power consumption device 130 can receive the status data collection command.

The electric device 130 may receive the status data collection instruction from the power line 140 through the third power carrier module 131, convert the status data collection instruction from an analog signal to a digital signal through the third power carrier module 131, and transmit the status data collection instruction to the third processing module 132 after the conversion is successful. The third processing module 132 compares the unique identifier of the target device in the status data collection instruction with the identifier of the electric equipment 130, and when the unique identifier of the target device is consistent with the identifier of the electric equipment 130, the third processing module 132 collects current status information of the electric equipment 130 from the electric equipment module 133, and the current status information is used as second feedback information after the current status information is successfully collected.

In an embodiment, when the unique identifier of the target device is identical to the identifier of the powered device 130 but the current status information of the powered device 130 is not collected, it may be determined that the powered device 130 is in the disconnected state, and the third processing module 132 uses the information that the powered device 130 is in the disconnected state as the second feedback information.

For example, when both the lighting device and the air-conditioning device are in the off state, the off state information of the lighting device and the air-conditioning device may be used as the second feedback information; when the lighting equipment is closed and the air conditioning equipment is opened, collecting the current state information of the lighting equipment as second feedback information, and meanwhile, taking the opening state information of the air conditioning equipment as the second feedback information. The lighting equipment and the air conditioning equipment are electric equipment 130 with a power carrier module.

After the second feedback information is successfully collected, the third processing module 132 may send the feedback information to the third power carrier module 131, so that the second feedback signal may be converted into an analog signal by the third power carrier module 131, and the second feedback information is loaded onto the power line 140 after the conversion is successful. After receiving the second feedback information, the second power carrier module 12 directly mounts the second feedback information on the power line 140. The monitoring device obtains the second feedback information from the power line 140 through the first power carrier module 111, converts the second feedback information into a digital signal, and returns the second feedback information to the terminal 200 through the first processing module 112 and the communication module 113 after the second feedback information is successfully converted. In the above process, the power distribution device 120 acts as a relay and directly transmits the status data collection command to the power line 140, so that the monitoring device 110 can receive the status data collection command.

The maintenance personnel can maintain the electric equipment 130 according to the second feedback information, and when the electric equipment 130 is found to be in fault, the fault can be timely eliminated, and the electric equipment 130 can be used for recovering operation.

In an embodiment, the power distribution device 120 may monitor the device status of the electrical device 130, and when the electrical device 130 is found to be abnormal, the power distribution device 120 may be disconnected, so as to guarantee the electrical safety of the user. For example, when the power distribution device 120 monitors that the electrical leakage occurs in the electrical device 130, or the load voltage of the electrical device 130 is too large, the power distribution device 120 may be disconnected, so as to ensure the electrical safety of the user.

In an embodiment, the monitoring device 110 may control the power distribution device 120 to open and close, and when the power distribution device 120 monitors that the electrical device 130 is abnormal or the power distribution device 120 monitors that an abnormal state exists in itself, the power distribution device 120 may report the abnormal state information to the monitoring device 110 through the second power carrier module 121. The monitoring device 110 may receive the abnormal state information through the first power carrier module 111, and control the power distribution device 120 to be disconnected according to the abnormal state information. When the abnormal conditions of the power distribution equipment 120 and the electric equipment 130 are eliminated, the monitoring equipment 11 can control the power distribution equipment 120 to be closed, so that the power information processing system 100 can be recovered to operate.

By the above measures, the power consumption safety of the user can be fully ensured, and the line safety of the power information processing system 100 can be ensured.

In one embodiment, the monitoring device 110 is further configured to assign device identifiers to the power distribution device 120 and the power consumption device 130 when the power information processing system is first used, so as to ensure that the communications between the devices do not interfere with each other.

In one embodiment, the data instructions include resource information configuration instructions. The resource information configuration instruction carries power resource information. The monitoring device 110 may allocate power resource information to the power distribution device and the power-consuming device through respective power carrier modules based on the resource information configuration instruction.

During an operation, the power distribution personnel may send a resource information configuration command to the monitoring device 110 through the terminal 200. The monitoring device 110 receives the resource information configuration instruction through the communication module 113, and successfully transmits the power resource information carried in the resource information configuration instruction to the power distribution device 120 through the first power carrier module 111 and the second power carrier module 121; meanwhile, the power resource information carried in the resource information configuration instruction is transmitted to the electric equipment 130 through the first power carrier module 111, the second power carrier module 121 and the third power carrier module 131. The power distribution equipment 120 and the electric equipment 130 are supplied with electric energy in the above manner, so that the electric equipment 130 and the power distribution equipment 120 can execute corresponding work flows.

In an embodiment, the first power carrier module 111, the second power carrier module 121, and the third power carrier module 131 may only receive and transmit data commands within a certain frequency range. At this time, the status data collection instruction and the resource information configuration instruction can be distinguished according to different frequency bands of the data instruction.

Through the measures, the power information processing system can utilize the existing power supply system to the maximum degree to realize energy management and control, reduces the laying difficulty of lines, and improves the anti-interference capacity of the system.

In an embodiment, when the power information processing system 100 includes a plurality of power distribution devices, each power distribution device 120 determines whether its device identifier matches the unique identifier of the target device in the data command, and when the device identifier matches the unique identifier of the target device in the data command, collects current state information of the power distribution device 120 as first feedback information; when there is no match, the data command is transmitted to the plurality of electrical devices 130 connected to the electrical distribution device 120. The electric equipment 130 judges whether the identification of the electric equipment is matched with the unique identification of the target equipment in the data instruction, and when the identification of the electric equipment is matched with the unique identification of the target equipment, the current state information of the electric equipment 130 is collected to be used as second feedback information; when there is no match, no data collection is performed.

Fig. 7 is a schematic flowchart of a power information processing method according to an embodiment of the present application. The power information processing method is applied to the power information processing system 100. The power information processing method includes the following steps S210 to S240.

Step S210: the data instruction sent by the terminal is received through the monitoring equipment, and the data instruction is carried to the power line through the first power carrier module, wherein the data instruction carries the unique identification of the target equipment.

Step S220: and receiving a data instruction from the power line through the second power carrier module, and sending first feedback information to the power line through the power distribution equipment according to the unique identifier of the target equipment carried in the data instruction.

Step S230: and receiving a data instruction from the power line through the third power carrier module, and sending second feedback information to the power line through the electric equipment based on the data instruction.

Step S240: and receiving the first feedback information and/or the second feedback information from the power line through a first power carrier module of the monitoring equipment, and returning the first feedback information and/or the second feedback information to the terminal.

The specific implementation process in the above steps is described in detail in the workflow description part of the power information processing system, and is not described herein again.

As shown in fig. 8, the present embodiment provides an electronic device 9 including: at least one processor 91 and a memory 92, one processor 91 being exemplified in fig. 8. The processor 91 and the memory 92 are connected by a bus 90, and the memory 92 stores instructions executable by the processor 91, and the instructions are executed by the processor 91, so that the electronic device 9 can execute all or part of the flow of the above-mentioned power information processing method. The Memory 92 may be implemented by any type of volatile or non-volatile Memory device or combination thereof, such as Static Random Access Memory (SRAM), electrically Erasable Programmable Read-Only Memory (EEPROM), erasable Programmable Read-Only Memory (EPROM), programmable Read-Only Memory (PROM), read-Only Memory (ROM), magnetic Memory, flash Memory, magnetic disk or optical disk.

The present application also provides a computer-readable storage medium storing a computer program executable by the processor 91 to perform the power information processing method provided by the present application.

In the embodiments provided in the present application, the disclosed apparatus and method can be implemented in other ways. The apparatus embodiments described above are merely illustrative and, for example, the flowcharts and block diagrams in the figures illustrate the architecture, functionality, and operation of possible implementations of apparatus, methods and computer program products according to various embodiments of the present application. In this regard, each block in the flowchart or block diagrams may represent a module, segment, or portion of code, which comprises one or more executable instructions for implementing the specified logical function(s). In some alternative implementations, the functions noted in the block may occur out of the order noted in the figures. For example, two blocks shown in succession may, in fact, be executed substantially concurrently, or the blocks may sometimes be executed in the reverse order, depending upon the functionality involved. It will also be noted that each block of the block diagrams and/or flowchart illustration, and combinations of blocks in the block diagrams and/or flowchart illustration, can be implemented by special purpose hardware-based systems that perform the specified functions or acts, or combinations of special purpose hardware and computer instructions.

In addition, functional modules in the embodiments of the present application may be integrated together to form an independent part, or each module may exist alone, or two or more modules may be integrated to form an independent part.

The functions, if implemented in the form of software functional modules and sold or used as a stand-alone product, may be stored in a computer-readable storage medium. Based on such understanding, the technical solution of the present application or portions thereof that substantially contribute to the prior art may be embodied in the form of a software product stored in a storage medium and including instructions for causing a computer device (which may be a personal computer, a server, or a network device) to execute all or part of the steps of the method according to the embodiments of the present application. And the aforementioned storage medium includes: a U-disk, a removable hard disk, a Read-Only Memory (ROM), a Random Access Memory (RAM), a magnetic disk, or an optical disk, and various media capable of storing program codes.

Claims (8)

1. An electric power information processing system characterized by comprising:

the monitoring equipment is used for receiving a data instruction sent by the terminal and carrying the data instruction to a power line through a first power carrier module, wherein the data instruction carries a unique identifier of target equipment;

the power distribution equipment is connected with the monitoring equipment and used for receiving the data instruction from the power line through a second power carrier module and sending first feedback information to the power line according to the unique identifier of the target equipment in the data instruction;

the power utilization equipment is connected with the power distribution equipment and used for receiving the data instruction from the power line through a third power carrier module and sending second feedback information to the power line based on the data instruction;

the monitoring equipment is further configured to receive the first feedback information and/or the second feedback information from the power line through the first power carrier module, and return the first feedback information and/or the second feedback information to the terminal;

the data instructions include state data collection instructions;

the power distribution equipment is further used for comparing the unique identifier of the target equipment in the state data collection instruction with the identifier of the power distribution equipment, and when the unique identifier of the target equipment is inconsistent with the identifier of the power distribution equipment, the state data collection instruction is continuously transmitted on the power line through the second power carrier module;

the data instructions further comprise resource information configuration instructions;

the monitoring equipment is further used for distributing power resource information to the power distribution equipment and the electric equipment through respective power carrier modules based on the resource information configuration instructions;

the power distribution equipment is connected with the monitoring equipment through the power line, and the electric equipment is connected with the power distribution equipment through the power line;

the first feedback information is current state information of the power distribution equipment, and the current state information of the power distribution equipment is on-off state information, fault information, auxiliary contact information and energy consumption information of the power distribution equipment; the second feedback information is current state information of the electric equipment, and the current state information of the electric equipment is on-off state information, fault information and electric energy loss information of the electric equipment.

2. The system of claim 1, wherein the sending first feedback information onto the power line according to the unique identifier of the target device in the data command comprises:

and when the unique identifier of the target equipment is consistent with the identifier of the power distribution equipment, collecting the current state information of the power distribution equipment, and carrying the current state information of the power distribution equipment as the first feedback information onto the power line.

3. The system of claim 1, wherein said sending second feedback information onto the power line based on the data command comprises:

and the electric equipment compares the unique identifier of the target equipment with the identifier of the electric equipment in the state data collection instruction, collects the current state information of the electric equipment when the unique identifier of the target equipment is consistent with the identifier of the electric equipment, and carries the current state information of the electric equipment on the power line as the second feedback information.

4. The system of claim 1, wherein the sending second feedback information to the power line based on the data command further comprises:

when the unique identifier of the target device is consistent with the identifier of the electric equipment, if the current state information of the electric equipment cannot be collected, the electric equipment is determined to be in a disconnected state, and the information that the electric equipment is in the disconnected state is carried on the power line as second feedback information through the third power carrier module.

5. The system of claim 1, further comprising:

the power distribution equipment is also used for reporting abnormal state information to the monitoring equipment through the second power carrier module;

the monitoring equipment is also used for controlling the power distribution equipment to be disconnected according to the abnormal state information.

6. An electric power information processing method applied to the electric power information processing system according to any one of claims 1 to 5, the method comprising:

receiving a data instruction sent by a terminal through monitoring equipment, and carrying the data instruction to a power line through a first power line carrier module, wherein the data instruction carries a unique identifier of target equipment;

receiving the data instruction from the power line through a second power carrier module, and sending first feedback information to the power line through the power distribution equipment according to the unique identification of the target equipment carried in the data instruction;

receiving the data instruction from the power line through a third power carrier module, and sending second feedback information to the power line through the electric equipment based on the data instruction;

receiving the first feedback information and/or the second feedback information from the power line through the first power carrier module of the monitoring device, and returning the first feedback information and/or the second feedback information to a terminal;

the data instructions include state data collection instructions;

the power distribution equipment is further used for comparing the unique identifier of the target equipment in the state data collection instruction with the identifier of the power distribution equipment, and when the unique identifier of the target equipment is inconsistent with the identifier of the power distribution equipment, the state data collection instruction is continuously transmitted on the power line through the second power carrier module;

the data instructions further comprise resource information configuration instructions;

the monitoring equipment is further used for distributing power resource information to the power distribution equipment and the electric equipment through respective power carrier modules based on the resource information configuration instructions;

the power distribution equipment is connected with the monitoring equipment through the power line, and the electric equipment is connected with the power distribution equipment through the power line;

the first feedback information is the current state information of the power distribution equipment, and the current state information of the power distribution equipment is the on-off state information, the fault information, the auxiliary contact information and the energy consumption information of the power distribution equipment; the second feedback information is current state information of the electric equipment, and the current state information of the electric equipment is on-off state information, fault information and electric energy loss information of the electric equipment.

7. An electronic device, characterized in that the electronic device comprises:

a processor;

a memory for storing processor-executable instructions;

wherein the processor is configured to perform the power information processing method of claim 6.

8. An electrical distribution apparatus, comprising:

the power carrier module is arranged in the power distribution equipment and used for receiving a state data collection instruction and transmitting the state data collection instruction to the processing module;

the processing module is arranged in the power distribution equipment, is connected with the power carrier module and is used for receiving a state data collection instruction transmitted by the power carrier module, comparing the unique identifier of the target equipment in the state data collection instruction with the identifier of the power distribution equipment, and collecting the current state information of the power distribution equipment when the unique identifier of the target equipment is consistent with the identifier of the power distribution equipment;

the power distribution module is arranged in the power distribution equipment, one end of the power distribution module is connected with the processing module, and the other end of the power distribution module is connected with the power carrier module and used for providing current state information of the power distribution equipment;

the power carrier module is also used for receiving a resource information configuration instruction and transmitting the resource information configuration instruction to the power distribution module;

the power distribution module is also used for receiving a resource information configuration instruction transmitted by the power carrier module;

the processing module is further used for continuously transmitting the state data collection instruction on a power line through the power carrier module when the unique identifier of the target device is inconsistent with the identifier of the power distribution device;

the resource information configuration instruction carries power resource information; the power distribution equipment is connected with the monitoring equipment through the power line, and the power distribution equipment is connected with the electric equipment through the power line; the current state information is on-off state information, fault information, auxiliary contact information and energy consumption information of the power distribution equipment.

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