CN111835086A - State monitoring method and energy-saving electric power cabinet with infinite remote control alarm function - Google Patents

Abstract

The invention discloses a state monitoring method and an energy-saving electric cabinet with an infinite remote control alarm function, which comprises the steps of firstly generating an energy-saving parameter distribution network and a control parameter distribution network corresponding to the energy-saving electric cabinet, secondly extracting node configuration information of any network node in the energy-saving parameter distribution network and determining a reference network node from the control parameter distribution network, then loading the node configuration information to the reference network node according to an alarm information output record of the energy-saving electric cabinet and determining a parameter matching network so as to determine a current network node, and finally sequentially acquiring state description information in the control parameter distribution network according to an information flow sequence and judging whether the energy-saving electric cabinet has a signal instruction receiving fault or not. Therefore, alarm information can be output when the energy-saving electric power cabinet is judged to be out of order, the overhaul center can overhaul the energy-saving electric power cabinet in time, and the problem that the energy-saving electric power cabinet is difficult to accurately execute the instruction for switching the state of the high-voltage electric appliance during operation is solved.

Description

State monitoring method and energy-saving electric power cabinet with infinite remote control alarm function

Technical Field

The disclosure relates to the technical field of electric power cabinet processing, in particular to a state monitoring method and an energy-saving electric power cabinet with an infinite remote control alarm function.

Background

The electric power cabinet is important equipment for controlling various high-voltage electric appliances, and the normal operation of the electric power cabinet can ensure the safe operation and cooperation of the high-voltage electric appliances, so that large-scale power utilization accidents are avoided. In practical application, because the power cabinet needs to switch the operating state of the high-voltage electrical apparatus, the power consumption of the power cabinet is relatively large, and in order to reduce the power consumption of the power cabinet, the energy-saving power cabinet is applied to practical working conditions at present. However, when the energy-saving power cabinet is operated, a problem that it is difficult to accurately execute a command for switching the state of the high-voltage electrical apparatus often occurs.

Disclosure of Invention

In order to solve the technical problems in the related art, the present disclosure provides a state monitoring method and an energy-saving power cabinet with an infinite remote control alarm function.

A condition monitoring method is applied to monitoring equipment installed in an energy-saving electric power cabinet, and comprises the following steps:

generating an energy-saving parameter distribution network corresponding to a first thread parameter corresponding to an energy-saving thread of an energy-saving power cabinet and a control parameter distribution network corresponding to a second thread parameter corresponding to a high-voltage electrical appliance control thread of the energy-saving power cabinet, wherein the energy-saving parameter distribution network and the control parameter distribution network respectively comprise a plurality of network nodes with different parameter stabilities;

extracting node configuration information of a first thread parameter corresponding to an energy-saving thread of the energy-saving power cabinet at any network node in the energy-saving parameter distribution network, and determining a network node with the maximum parameter stability in the control parameter distribution network as a reference network node;

loading the node configuration information to the reference network node according to the alarm information output record of the energy-saving power cabinet, and calculating in the reference network node to obtain node loading information; generating a parameter matching network between a first thread parameter corresponding to an energy-saving thread of the energy-saving power cabinet and a second thread parameter corresponding to a high-voltage electrical appliance control thread of the energy-saving power cabinet based on the node configuration information and the node loading information;

acquiring dynamic configuration information from the reference network node by taking the network node corresponding to the node loading information as a target node, loading the dynamic configuration information to the network node where the node configuration information is located according to the network topology pointing parameter corresponding to the parameter matching network, obtaining static configuration information corresponding to the dynamic configuration information from the network node where the node configuration information is located, and determining the target node of the static configuration information as the current network node;

acquiring an information flow sequence loaded into the reference network node by the node configuration information; according to information matching coefficients between the static configuration information and reference configuration information corresponding to a plurality of sequence identifications on the information flow sequence, sequentially acquiring state description information of the energy-saving power cabinet corresponding to the current network node in a network interval corresponding to the control parameter distribution network; when the condition description information contains the set condition identification, the energy-saving electric power cabinet is determined to have a signal instruction receiving fault, and alarm information is sent to an overhaul center so that the overhaul center overhauls the energy-saving electric power cabinet.

Preferably, whether the acquired state description information includes the set state identifier is determined by the following steps:

determining identification signatures extracted based on state description information, and for a current identification signature in the identification signatures, determining signature update weight of the current identification signature in a target time period based on a first signature utilization rate of the current identification signature in the target time period and a second signature utilization rate of each identification signature in the target time period;

determining the identification confidence of the current identification signature between two continuous target time periods according to the signature update weights of the current identification signature in the two continuous target time periods;

and when a target random number obtained by weighting the signature random number corresponding to the current identification signature based on the identification confidence and the signature updating weight is in a set numerical value interval, determining the state identification corresponding to the current identification signature as the set state identification.

Preferably, the extracting node configuration information of the first thread parameter corresponding to the energy-saving thread of the energy-saving power cabinet at any network node in the energy-saving parameter distribution network includes:

acquiring node encapsulation logic information of any network node in the energy-saving parameter distribution network;

carrying out logic topology splitting on the node encapsulation logic information, and outputting a splitting result comprising a configuration text and a text field corresponding to the configuration text;

determining editable text information in the configuration text according to the configuration text and a text field corresponding to the configuration text;

determining the editable text information as the node configuration information.

Preferably, the loading the dynamic configuration information to a network node where the node configuration information is located according to a network topology direction parameter corresponding to the parameter matching network, and obtaining static configuration information corresponding to the dynamic configuration information in the network node where the node configuration information is located includes:

determining a loading path of a network node where the node configuration information is located according to a network topology direction parameter corresponding to the parameter matching network, loading dynamic configuration information into a data set corresponding to the network node where the node configuration information is located according to the loading path, and determining each data message in the data set;

under the condition that a configuration pointing identifier exists in a data set corresponding to a network node where the node configuration information is located based on the path parameters of the loading path, determining the data intersection rate between each data message of the data set under the loading pointing identifier and each data message of the data set under the configuration pointing identifier according to the data message of the data set under the configuration pointing identifier and a message key thereof;

moving the data message of the data set corresponding to the data message of which the data cross rate between the data message under the loading pointing identifier and the data message under the configuration pointing identifier is in the target interval to the configuration pointing identifier; under the condition that a plurality of data messages are contained under the loading pointing identifier corresponding to the data set, determining the data cross rate of the data set among the data messages under the loading pointing identifier according to the data messages and the message keys of the data set under the configuration pointing identifier, and calibrating the data messages under the loading pointing identifier according to the data cross rate among the data messages; setting a migration evaluation coefficient for the target data message obtained by calibration according to the data message of the data set under the configuration pointing identifier and the message key thereof, and moving the target data message to the configuration pointing identifier based on the migration evaluation coefficient;

and determining at least two groups of data messages to be processed matched with the configuration priority of the dynamic configuration information based on the data messages under the configuration pointing identifier, and determining message fields in the at least two groups of data messages to be processed as the static configuration information.

An energy-conserving electric power cabinet with unlimited remote control alarming function, install monitoring facilities in the energy-conserving electric power cabinet, monitoring facilities is used for:

generating an energy-saving parameter distribution network corresponding to a first thread parameter corresponding to an energy-saving thread of an energy-saving power cabinet and a control parameter distribution network corresponding to a second thread parameter corresponding to a high-voltage electrical appliance control thread of the energy-saving power cabinet, wherein the energy-saving parameter distribution network and the control parameter distribution network respectively comprise a plurality of network nodes with different parameter stabilities;

extracting node configuration information of a first thread parameter corresponding to an energy-saving thread of the energy-saving power cabinet at any network node in the energy-saving parameter distribution network, and determining a network node with the maximum parameter stability in the control parameter distribution network as a reference network node;

loading the node configuration information to the reference network node according to the alarm information output record of the energy-saving power cabinet, and calculating in the reference network node to obtain node loading information; generating a parameter matching network between a first thread parameter corresponding to an energy-saving thread of the energy-saving power cabinet and a second thread parameter corresponding to a high-voltage electrical appliance control thread of the energy-saving power cabinet based on the node configuration information and the node loading information;

acquiring dynamic configuration information from the reference network node by taking the network node corresponding to the node loading information as a target node, loading the dynamic configuration information to the network node where the node configuration information is located according to the network topology pointing parameter corresponding to the parameter matching network, obtaining static configuration information corresponding to the dynamic configuration information from the network node where the node configuration information is located, and determining the target node of the static configuration information as the current network node;

acquiring an information flow sequence loaded into the reference network node by the node configuration information; according to information matching coefficients between the static configuration information and reference configuration information corresponding to a plurality of sequence identifications on the information flow sequence, sequentially acquiring state description information of the energy-saving power cabinet corresponding to the current network node in a network interval corresponding to the control parameter distribution network; when the condition description information contains the set condition identification, the energy-saving electric power cabinet is determined to have a signal instruction receiving fault, and alarm information is sent to an overhaul center so that the overhaul center overhauls the energy-saving electric power cabinet.

Preferably, the monitoring device is specifically configured to:

determining identification signatures extracted based on state description information, and for a current identification signature in the identification signatures, determining signature update weight of the current identification signature in a target time period based on a first signature utilization rate of the current identification signature in the target time period and a second signature utilization rate of each identification signature in the target time period;

determining the identification confidence of the current identification signature between two continuous target time periods according to the signature update weights of the current identification signature in the two continuous target time periods;

and when a target random number obtained by weighting the signature random number corresponding to the current identification signature based on the identification confidence and the signature updating weight is in a set numerical value interval, determining the state identification corresponding to the current identification signature as the set state identification.

Preferably, the monitoring device is specifically configured to:

acquiring node encapsulation logic information of any network node in the energy-saving parameter distribution network;

carrying out logic topology splitting on the node encapsulation logic information, and outputting a splitting result comprising a configuration text and a text field corresponding to the configuration text;

determining editable text information in the configuration text according to the configuration text and a text field corresponding to the configuration text;

determining the editable text information as the node configuration information.

Preferably, the monitoring device is specifically configured to:

determining a loading path of a network node where the node configuration information is located according to a network topology direction parameter corresponding to the parameter matching network, loading dynamic configuration information into a data set corresponding to the network node where the node configuration information is located according to the loading path, and determining each data message in the data set;

under the condition that a configuration pointing identifier exists in a data set corresponding to a network node where the node configuration information is located based on the path parameters of the loading path, determining the data intersection rate between each data message of the data set under the loading pointing identifier and each data message of the data set under the configuration pointing identifier according to the data message of the data set under the configuration pointing identifier and a message key thereof;

moving the data message of the data set corresponding to the data message of which the data cross rate between the data message under the loading pointing identifier and the data message under the configuration pointing identifier is in the target interval to the configuration pointing identifier; under the condition that a plurality of data messages are contained under the loading pointing identifier corresponding to the data set, determining the data cross rate of the data set among the data messages under the loading pointing identifier according to the data messages and the message keys of the data set under the configuration pointing identifier, and calibrating the data messages under the loading pointing identifier according to the data cross rate among the data messages; setting a migration evaluation coefficient for the target data message obtained by calibration according to the data message of the data set under the configuration pointing identifier and the message key thereof, and moving the target data message to the configuration pointing identifier based on the migration evaluation coefficient;

and determining at least two groups of data messages to be processed matched with the configuration priority of the dynamic configuration information based on the data messages under the configuration pointing identifier, and determining message fields in the at least two groups of data messages to be processed as the static configuration information.

An energy-saving electric cabinet with an infinite remote control alarm function, wherein a monitoring device is installed in the energy-saving electric cabinet, the monitoring device comprises a processor and a memory which are communicated with each other, and the processor executes a computer program called from the memory to realize the method.

A computer-readable storage medium, on which a computer program is stored which, when executed, implements the above-described method.

The technical scheme provided by the embodiment of the disclosure can have the following beneficial effects.

Firstly, an energy-saving parameter distribution network and a control parameter distribution network corresponding to an energy-saving power cabinet are generated, secondly, node configuration information of any network node in the energy-saving parameter distribution network is extracted, a network node with the maximum parameter stability in the control parameter distribution network is determined as a reference network node, then, according to the alarm information output record of the energy-saving power cabinet, the node configuration information is loaded to the reference network node, a parameter matching network between a first thread parameter and a second thread parameter is determined, then, a current network node is determined according to the parameter matching network, and finally, according to the obtained information flow sequence, state description information is sequentially obtained in the control parameter distribution network, and whether the energy-saving power cabinet has a signal instruction receiving fault or not is judged based on the state description information. Therefore, alarm information can be output when the energy-saving electric power cabinet is judged to be out of order, the overhaul center can overhaul the energy-saving electric power cabinet in time, and the problem that the energy-saving electric power cabinet is difficult to accurately execute the instruction for switching the state of the high-voltage electric appliance during operation is solved.

Drawings

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

Fig. 1 is a schematic flow diagram of a condition monitoring method according to the present disclosure.

FIG. 2 is a block diagram illustrating a condition monitoring device according to an exemplary embodiment.

FIG. 3 is a flow diagram illustrating a method for monitoring a hardware configuration diagram of a device to implement application loading service components in accordance with an exemplary embodiment.

Detailed Description

Reference will now be made in detail to the exemplary embodiments, examples of which are illustrated in the accompanying drawings.

The inventor researches and analyzes the existing energy-saving electric power cabinet, and finds that although the energy-saving electric power cabinet is improved in energy consumption, the operation of an energy-saving thread in the energy-saving electric power cabinet can cause the signal instruction of the energy-saving electric power cabinet to be received to a certain extent, and the existing energy-saving electric power cabinet can not monitor the self state, so that the energy-saving electric power cabinet can not accurately execute the instruction for switching the state of the high-voltage electric appliance.

In order to solve the above problem, embodiments of the present invention provide a state monitoring method and an energy-saving power cabinet with an infinite remote control alarm function, which can monitor a self state of the energy-saving power cabinet, so as to output alarm information when it is determined that the energy-saving power cabinet has a fault, so that an overhaul center can overhaul the energy-saving power cabinet in time, and the problem that it is difficult to accurately execute a command for switching states of a high-voltage electrical appliance when the energy-saving power cabinet is in operation is solved.

Referring to fig. 1, a condition monitoring method is provided, which is applied to a monitoring device installed in an energy-saving power cabinet, and at least includes the following steps.

Step S11, generating an energy-saving parameter distribution network corresponding to a first thread parameter corresponding to an energy-saving thread of an energy-saving power cabinet and a control parameter distribution network corresponding to a second thread parameter corresponding to a high-voltage apparatus control thread of the energy-saving power cabinet, wherein the energy-saving parameter distribution network and the control parameter distribution network respectively comprise a plurality of network nodes with different parameter stability.

Step S12, extracting node configuration information of any network node of the first thread parameter corresponding to the energy-saving thread of the energy-saving power cabinet in the energy-saving parameter distribution network, and determining the network node with the maximum parameter stability in the control parameter distribution network as a reference network node.

Step S13, loading the node configuration information to the reference network node according to the alarm information output record of the energy-saving power cabinet, and calculating to obtain node loading information in the reference network node; and generating a parameter matching network between a first thread parameter corresponding to an energy-saving thread of the energy-saving power cabinet and a second thread parameter corresponding to a high-voltage electrical appliance control thread of the energy-saving power cabinet based on the node configuration information and the node loading information.

Step S14, taking the network node corresponding to the node loading information as a target node to obtain dynamic configuration information in the reference network node, loading the dynamic configuration information to the network node where the node configuration information is located according to the network topology direction parameter corresponding to the parameter matching network, obtaining static configuration information corresponding to the dynamic configuration information in the network node where the node configuration information is located, and determining that the target node of the static configuration information is the current network node.

Step S15, acquiring an information flow sequence in which the node configuration information is loaded into the reference network node; according to information matching coefficients between the static configuration information and reference configuration information corresponding to a plurality of sequence identifications on the information flow sequence, sequentially acquiring state description information of the energy-saving power cabinet corresponding to the current network node in a network interval corresponding to the control parameter distribution network; when the condition description information contains the set condition identification, the energy-saving electric power cabinet is determined to have a signal instruction receiving fault, and alarm information is sent to an overhaul center so that the overhaul center overhauls the energy-saving electric power cabinet.

It can be understood that, through the steps S11 to S15, firstly, an energy-saving parameter distribution network and a control parameter distribution network corresponding to the energy-saving power cabinet are generated, secondly, node configuration information of any network node in the energy-saving parameter distribution network is extracted, and a network node having the maximum parameter stability in the control parameter distribution network is determined as a reference network node, then, according to an alarm information output record of the energy-saving power cabinet, the node configuration information is loaded to the reference network node, and a parameter matching network between a first thread parameter and a second thread parameter is determined, further, a current network node is determined according to the parameter matching network, and finally, according to the obtained information flow sequence, state description information is sequentially obtained in the control parameter distribution network, and whether a signal instruction receiving fault occurs in the energy-saving power cabinet is determined based on the state description information. Therefore, alarm information can be output when the energy-saving electric power cabinet is judged to be out of order, the overhaul center can overhaul the energy-saving electric power cabinet in time, and the problem that the energy-saving electric power cabinet is difficult to accurately execute the instruction for switching the state of the high-voltage electric appliance during operation is solved.

In a specific implementation process, in order to accurately determine whether the acquired state description information includes the set state identifier, so as to ensure the accuracy of the signal command reception fault determination for the energy-saving power cabinet, in step S15, it may be determined whether the acquired state description information includes the set state identifier in the manner described in the following steps S151 to S154.

Step S151, determining the identification signatures extracted based on the state description information, and for a current identification signature in the identification signatures, determining a signature update weight of the current identification signature in a target time period based on a first signature utilization rate of the current identification signature in the target time period and a second signature utilization rate of each identification signature in the target time period.

Step S152, determining an identification confidence of the current identification signature between two consecutive target time periods according to the signature update weights of the current identification signature in the two consecutive target time periods.

Step S153, when the target random number obtained by weighting the signature random number corresponding to the current identification signature based on the identification confidence and the signature update weight is in a set value interval, determining that the state identifier corresponding to the current identification signature is the set state identifier.

It can be understood that through the descriptions in step S151 to step S153, whether the acquired state description information includes the set state identifier can be accurately determined, so as to ensure the accuracy of the signal instruction receiving fault judgment on the energy-saving power cabinet.

In a possible implementation manner, in order to accurately and completely extract the node configuration information, the extracting of the node configuration information of any network node in the energy saving parameter distribution network of the first thread parameter corresponding to the energy saving thread of the energy saving power cabinet, which is described in step S12, may specifically include the contents described in step S121 to step S124 below.

Step S121, obtaining node encapsulation logic information of any network node in the energy saving parameter distribution network.

Step S122, the node encapsulation logic information is subjected to logic topology splitting, and splitting results comprising configuration texts and text fields corresponding to the configuration texts are output.

Step S123, determining editable text information in the configuration text according to the configuration text and the text field corresponding to the configuration text.

Step S124, determining the editable text information as the node configuration information.

When the contents described in the above steps S121 to S124 are applied, the node configuration information can be accurately and completely extracted.

In practical applications, in order to ensure matching degree between dynamic configuration information and static configuration information, the step S14 is to load the dynamic configuration information to a network node where the node configuration information is located according to a network topology pointing parameter corresponding to the parameter matching network, and obtain the static configuration information corresponding to the dynamic configuration information in the network node where the node configuration information is located, which may specifically include the following steps S141 to S144.

Step S141, determining a loading path of a network node where the node configuration information is located according to the network topology direction parameter corresponding to the parameter matching network, loading dynamic configuration information into a data set corresponding to the network node where the node configuration information is located according to the loading path, and determining each data packet in the data set.

Step S142, determining, based on the path parameter of the loading path, that the dynamic configuration information has a configuration direction identifier in a data set corresponding to the network node where the node configuration information is located, and determining, according to the data packets of the data set under the configuration direction identifier and the packet key thereof, a data intersection rate between each data packet of the data set under the loading direction identifier and each data packet of the data set under the configuration direction identifier.

Step S143, moving the data message corresponding to the data packet of the data set in the target interval with the data cross rate between the data packet under the loading direction mark and the data packet under the configuration direction mark to the configuration direction mark; under the condition that a plurality of data messages are contained under the loading pointing identifier corresponding to the data set, determining the data cross rate of the data set among the data messages under the loading pointing identifier according to the data messages and the message keys of the data set under the configuration pointing identifier, and calibrating the data messages under the loading pointing identifier according to the data cross rate among the data messages; and setting a migration evaluation coefficient for the target data message obtained by calibration according to the data message of the data set under the configuration pointing identifier and the message key thereof, and moving the target data message to the configuration pointing identifier based on the migration evaluation coefficient.

Step S144, determining at least two groups of data packets to be processed matching with the configuration priority of the dynamic configuration information based on the data packets under the configuration pointing identifier, and determining packet fields in the at least two groups of data packets to be processed as the static configuration information.

It is understood that, through the contents described in the above steps S141 to S144, the matching degree between the dynamic configuration information and the static configuration information can be ensured.

Based on the same inventive concept, an energy-saving electric power cabinet with an infinite remote control alarm function is provided, wherein a monitoring device is installed in the energy-saving electric power cabinet, and the monitoring device is used for:

generating an energy-saving parameter distribution network corresponding to a first thread parameter corresponding to an energy-saving thread of an energy-saving power cabinet and a control parameter distribution network corresponding to a second thread parameter corresponding to a high-voltage electrical appliance control thread of the energy-saving power cabinet, wherein the energy-saving parameter distribution network and the control parameter distribution network respectively comprise a plurality of network nodes with different parameter stabilities;

extracting node configuration information of a first thread parameter corresponding to an energy-saving thread of the energy-saving power cabinet at any network node in the energy-saving parameter distribution network, and determining a network node with the maximum parameter stability in the control parameter distribution network as a reference network node;

loading the node configuration information to the reference network node according to the alarm information output record of the energy-saving power cabinet, and calculating in the reference network node to obtain node loading information; generating a parameter matching network between a first thread parameter corresponding to an energy-saving thread of the energy-saving power cabinet and a second thread parameter corresponding to a high-voltage electrical appliance control thread of the energy-saving power cabinet based on the node configuration information and the node loading information;

acquiring dynamic configuration information from the reference network node by taking the network node corresponding to the node loading information as a target node, loading the dynamic configuration information to the network node where the node configuration information is located according to the network topology pointing parameter corresponding to the parameter matching network, obtaining static configuration information corresponding to the dynamic configuration information from the network node where the node configuration information is located, and determining the target node of the static configuration information as the current network node;

acquiring an information flow sequence loaded into the reference network node by the node configuration information; according to information matching coefficients between the static configuration information and reference configuration information corresponding to a plurality of sequence identifications on the information flow sequence, sequentially acquiring state description information of the energy-saving power cabinet corresponding to the current network node in a network interval corresponding to the control parameter distribution network; when the condition description information contains the set condition identification, the energy-saving electric power cabinet is determined to have a signal instruction receiving fault, and alarm information is sent to an overhaul center so that the overhaul center overhauls the energy-saving electric power cabinet.

Preferably, the monitoring device is specifically configured to:

determining identification signatures extracted based on state description information, and for a current identification signature in the identification signatures, determining signature update weight of the current identification signature in a target time period based on a first signature utilization rate of the current identification signature in the target time period and a second signature utilization rate of each identification signature in the target time period; determining the identification confidence of the current identification signature between two continuous target time periods according to the signature update weights of the current identification signature in the two continuous target time periods; and when a target random number obtained by weighting the signature random number corresponding to the current identification signature based on the identification confidence and the signature updating weight is in a set numerical value interval, determining the state identification corresponding to the current identification signature as the set state identification.

Preferably, the monitoring device is specifically configured to:

acquiring node encapsulation logic information of any network node in the energy-saving parameter distribution network; carrying out logic topology splitting on the node encapsulation logic information, and outputting a splitting result comprising a configuration text and a text field corresponding to the configuration text; determining editable text information in the configuration text according to the configuration text and a text field corresponding to the configuration text; determining the editable text information as the node configuration information.

Preferably, the monitoring device is specifically configured to: determining a loading path of a network node where the node configuration information is located according to a network topology direction parameter corresponding to the parameter matching network, loading dynamic configuration information into a data set corresponding to the network node where the node configuration information is located according to the loading path, and determining each data message in the data set; under the condition that a configuration pointing identifier exists in a data set corresponding to a network node where the node configuration information is located based on the path parameters of the loading path, determining the data intersection rate between each data message of the data set under the loading pointing identifier and each data message of the data set under the configuration pointing identifier according to the data message of the data set under the configuration pointing identifier and a message key thereof; moving the data message of the data set corresponding to the data message of which the data cross rate between the data message under the loading pointing identifier and the data message under the configuration pointing identifier is in the target interval to the configuration pointing identifier; under the condition that a plurality of data messages are contained under the loading pointing identifier corresponding to the data set, determining the data cross rate of the data set among the data messages under the loading pointing identifier according to the data messages and the message keys of the data set under the configuration pointing identifier, and calibrating the data messages under the loading pointing identifier according to the data cross rate among the data messages; setting a migration evaluation coefficient for the target data message obtained by calibration according to the data message of the data set under the configuration pointing identifier and the message key thereof, and moving the target data message to the configuration pointing identifier based on the migration evaluation coefficient; and determining at least two groups of data messages to be processed matched with the configuration priority of the dynamic configuration information based on the data messages under the configuration pointing identifier, and determining message fields in the at least two groups of data messages to be processed as the static configuration information.

On the basis, please refer to fig. 2 in combination, a state monitoring apparatus 200 is further provided, which is applied to a monitoring device installed in an energy-saving power cabinet, and the apparatus includes:

the network generation module 210 is configured to generate an energy-saving parameter distribution network corresponding to a first thread parameter corresponding to an energy-saving thread of an energy-saving power cabinet and a control parameter distribution network corresponding to a second thread parameter corresponding to a high-voltage appliance control thread of the energy-saving power cabinet, where the energy-saving parameter distribution network and the control parameter distribution network respectively include a plurality of network nodes with different parameter stabilities;

an information extraction module 220, configured to extract node configuration information of any network node of a first thread parameter corresponding to an energy-saving thread of the energy-saving power cabinet in the energy-saving parameter distribution network, and determine a network node with the maximum parameter stability in the control parameter distribution network as a reference network node;

the information loading module 230 is configured to load the node configuration information to the reference network node according to an alarm information output record of the energy-saving power cabinet, and calculate node loading information in the reference network node; generating a parameter matching network between a first thread parameter corresponding to an energy-saving thread of the energy-saving power cabinet and a second thread parameter corresponding to a high-voltage electrical appliance control thread of the energy-saving power cabinet based on the node configuration information and the node loading information;

a node determining module 240, configured to obtain dynamic configuration information from the reference network node by using the network node corresponding to the node loading information as a target node, load the dynamic configuration information to the network node where the node configuration information is located according to the network topology direction parameter corresponding to the parameter matching network, obtain static configuration information corresponding to the dynamic configuration information from the network node where the node configuration information is located, and determine that the target node of the static configuration information is a current network node;

a troubleshooting module 250, configured to obtain an information flow sequence in which the node configuration information is loaded into the reference network node; according to information matching coefficients between the static configuration information and reference configuration information corresponding to a plurality of sequence identifications on the information flow sequence, sequentially acquiring state description information of the energy-saving power cabinet corresponding to the current network node in a network interval corresponding to the control parameter distribution network; when the condition description information contains the set condition identification, the energy-saving electric power cabinet is determined to have a signal instruction receiving fault, and alarm information is sent to an overhaul center so that the overhaul center overhauls the energy-saving electric power cabinet.

On the basis of the above, please refer to fig. 3 in combination, an energy-saving electric cabinet 300 with an infinite remote control alarm function is provided, a monitoring device 310 is installed in the energy-saving electric cabinet 300, the monitoring device 310 includes a processor 311 and a memory 312 which are communicated with each other, and the processor 311 executes a computer program called from the memory 312 to implement the above method.

Further, a computer-readable storage medium has stored thereon a computer program which, when executed, implements the method described above.

In summary, when the above technical solution is applied, firstly, an energy-saving parameter distribution network and a control parameter distribution network corresponding to the energy-saving power cabinet are generated, secondly, node configuration information of any network node in the energy-saving parameter distribution network is extracted, and a network node having the maximum parameter stability in the control parameter distribution network is determined as a reference network node, secondly, according to an alarm information output record of the energy-saving power cabinet, the node configuration information is loaded to the reference network node and a parameter matching network between a first thread parameter and a second thread parameter is determined, and then, according to the parameter matching network, a current network node is determined, and finally, according to the obtained information flow sequence, state description information is sequentially obtained in the control parameter distribution network, and whether a signal instruction receiving fault occurs in the energy-saving power cabinet is determined based on the state description information. Therefore, alarm information can be output when the energy-saving electric power cabinet is judged to be out of order, the overhaul center can overhaul the energy-saving electric power cabinet in time, and the problem that the energy-saving electric power cabinet is difficult to accurately execute the instruction for switching the state of the high-voltage electric appliance during operation is solved.

Claims (10)

1. A condition monitoring method is applied to monitoring equipment installed in an energy-saving electric power cabinet, and comprises the following steps:

generating an energy-saving parameter distribution network corresponding to a first thread parameter corresponding to an energy-saving thread of an energy-saving power cabinet and a control parameter distribution network corresponding to a second thread parameter corresponding to a high-voltage electrical appliance control thread of the energy-saving power cabinet, wherein the energy-saving parameter distribution network and the control parameter distribution network respectively comprise a plurality of network nodes with different parameter stabilities;

extracting node configuration information of a first thread parameter corresponding to an energy-saving thread of the energy-saving power cabinet at any network node in the energy-saving parameter distribution network, and determining a network node with the maximum parameter stability in the control parameter distribution network as a reference network node;

loading the node configuration information to the reference network node according to the alarm information output record of the energy-saving power cabinet, and calculating in the reference network node to obtain node loading information; generating a parameter matching network between a first thread parameter corresponding to an energy-saving thread of the energy-saving power cabinet and a second thread parameter corresponding to a high-voltage electrical appliance control thread of the energy-saving power cabinet based on the node configuration information and the node loading information;

acquiring dynamic configuration information from the reference network node by taking the network node corresponding to the node loading information as a target node, loading the dynamic configuration information to the network node where the node configuration information is located according to the network topology pointing parameter corresponding to the parameter matching network, obtaining static configuration information corresponding to the dynamic configuration information from the network node where the node configuration information is located, and determining the target node of the static configuration information as the current network node;

acquiring an information flow sequence loaded into the reference network node by the node configuration information; according to information matching coefficients between the static configuration information and reference configuration information corresponding to a plurality of sequence identifications on the information flow sequence, sequentially acquiring state description information of the energy-saving power cabinet corresponding to the current network node in a network interval corresponding to the control parameter distribution network; when the condition description information contains the set condition identification, the energy-saving electric power cabinet is determined to have a signal instruction receiving fault, and alarm information is sent to an overhaul center so that the overhaul center overhauls the energy-saving electric power cabinet.

2. The method of claim 1, wherein whether the acquired state description information includes the set state flag is determined by:

determining identification signatures extracted based on state description information, and for a current identification signature in the identification signatures, determining signature update weight of the current identification signature in a target time period based on a first signature utilization rate of the current identification signature in the target time period and a second signature utilization rate of each identification signature in the target time period;

determining the identification confidence of the current identification signature between two continuous target time periods according to the signature update weights of the current identification signature in the two continuous target time periods;

and when a target random number obtained by weighting the signature random number corresponding to the current identification signature based on the identification confidence and the signature updating weight is in a set numerical value interval, determining the state identification corresponding to the current identification signature as the set state identification.

3. The method according to claim 1, wherein extracting node configuration information of a first thread parameter corresponding to an energy-saving thread of the energy-saving power cabinet at any network node in the energy-saving parameter distribution network comprises:

acquiring node encapsulation logic information of any network node in the energy-saving parameter distribution network;

carrying out logic topology splitting on the node encapsulation logic information, and outputting a splitting result comprising a configuration text and a text field corresponding to the configuration text;

determining editable text information in the configuration text according to the configuration text and a text field corresponding to the configuration text;

determining the editable text information as the node configuration information.

4. The method according to claim 1, wherein loading the dynamic configuration information to a network node where the node configuration information is located according to a network topology direction parameter corresponding to the parameter matching network, and obtaining static configuration information corresponding to the dynamic configuration information in the network node where the node configuration information is located comprises:

determining a loading path of a network node where the node configuration information is located according to a network topology direction parameter corresponding to the parameter matching network, loading dynamic configuration information into a data set corresponding to the network node where the node configuration information is located according to the loading path, and determining each data message in the data set;

under the condition that a configuration pointing identifier exists in a data set corresponding to a network node where the node configuration information is located based on the path parameters of the loading path, determining the data intersection rate between each data message of the data set under the loading pointing identifier and each data message of the data set under the configuration pointing identifier according to the data message of the data set under the configuration pointing identifier and a message key thereof;

moving the data message of the data set corresponding to the data message of which the data cross rate between the data message under the loading pointing identifier and the data message under the configuration pointing identifier is in the target interval to the configuration pointing identifier; under the condition that a plurality of data messages are contained under the loading pointing identifier corresponding to the data set, determining the data cross rate of the data set among the data messages under the loading pointing identifier according to the data messages and the message keys of the data set under the configuration pointing identifier, and calibrating the data messages under the loading pointing identifier according to the data cross rate among the data messages; setting a migration evaluation coefficient for the target data message obtained by calibration according to the data message of the data set under the configuration pointing identifier and the message key thereof, and moving the target data message to the configuration pointing identifier based on the migration evaluation coefficient;

and determining at least two groups of data messages to be processed matched with the configuration priority of the dynamic configuration information based on the data messages under the configuration pointing identifier, and determining message fields in the at least two groups of data messages to be processed as the static configuration information.

5. The utility model provides an energy-conserving electric power cabinet with unlimited remote control alarming function which characterized in that, install monitoring facilities in the energy-conserving electric power cabinet, monitoring facilities is used for:

generating an energy-saving parameter distribution network corresponding to a first thread parameter corresponding to an energy-saving thread of an energy-saving power cabinet and a control parameter distribution network corresponding to a second thread parameter corresponding to a high-voltage electrical appliance control thread of the energy-saving power cabinet, wherein the energy-saving parameter distribution network and the control parameter distribution network respectively comprise a plurality of network nodes with different parameter stabilities;

extracting node configuration information of a first thread parameter corresponding to an energy-saving thread of the energy-saving power cabinet at any network node in the energy-saving parameter distribution network, and determining a network node with the maximum parameter stability in the control parameter distribution network as a reference network node;

loading the node configuration information to the reference network node according to the alarm information output record of the energy-saving power cabinet, and calculating in the reference network node to obtain node loading information; generating a parameter matching network between a first thread parameter corresponding to an energy-saving thread of the energy-saving power cabinet and a second thread parameter corresponding to a high-voltage electrical appliance control thread of the energy-saving power cabinet based on the node configuration information and the node loading information;

acquiring dynamic configuration information from the reference network node by taking the network node corresponding to the node loading information as a target node, loading the dynamic configuration information to the network node where the node configuration information is located according to the network topology pointing parameter corresponding to the parameter matching network, obtaining static configuration information corresponding to the dynamic configuration information from the network node where the node configuration information is located, and determining the target node of the static configuration information as the current network node;

acquiring an information flow sequence loaded into the reference network node by the node configuration information; according to information matching coefficients between the static configuration information and reference configuration information corresponding to a plurality of sequence identifications on the information flow sequence, sequentially acquiring state description information of the energy-saving power cabinet corresponding to the current network node in a network interval corresponding to the control parameter distribution network; when the condition description information contains the set condition identification, the energy-saving electric power cabinet is determined to have a signal instruction receiving fault, and alarm information is sent to an overhaul center so that the overhaul center overhauls the energy-saving electric power cabinet.

6. The energy-saving electric power cabinet of claim 5, wherein the monitoring device is specifically configured to:

determining identification signatures extracted based on state description information, and for a current identification signature in the identification signatures, determining signature update weight of the current identification signature in a target time period based on a first signature utilization rate of the current identification signature in the target time period and a second signature utilization rate of each identification signature in the target time period;

determining the identification confidence of the current identification signature between two continuous target time periods according to the signature update weights of the current identification signature in the two continuous target time periods;

and when a target random number obtained by weighting the signature random number corresponding to the current identification signature based on the identification confidence and the signature updating weight is in a set numerical value interval, determining the state identification corresponding to the current identification signature as the set state identification.

7. The energy-saving electric power cabinet according to claim 5, wherein the monitoring device is specifically configured to:

acquiring node encapsulation logic information of any network node in the energy-saving parameter distribution network;

carrying out logic topology splitting on the node encapsulation logic information, and outputting a splitting result comprising a configuration text and a text field corresponding to the configuration text;

determining editable text information in the configuration text according to the configuration text and a text field corresponding to the configuration text;

determining the editable text information as the node configuration information.

8. The energy-saving electric power cabinet according to claim 5, wherein the monitoring device is specifically configured to:

determining a loading path of a network node where the node configuration information is located according to a network topology direction parameter corresponding to the parameter matching network, loading dynamic configuration information into a data set corresponding to the network node where the node configuration information is located according to the loading path, and determining each data message in the data set;

under the condition that a configuration pointing identifier exists in a data set corresponding to a network node where the node configuration information is located based on the path parameters of the loading path, determining the data intersection rate between each data message of the data set under the loading pointing identifier and each data message of the data set under the configuration pointing identifier according to the data message of the data set under the configuration pointing identifier and a message key thereof;

moving the data message of the data set corresponding to the data message of which the data cross rate between the data message under the loading pointing identifier and the data message under the configuration pointing identifier is in the target interval to the configuration pointing identifier; under the condition that a plurality of data messages are contained under the loading pointing identifier corresponding to the data set, determining the data cross rate of the data set among the data messages under the loading pointing identifier according to the data messages and the message keys of the data set under the configuration pointing identifier, and calibrating the data messages under the loading pointing identifier according to the data cross rate among the data messages; setting a migration evaluation coefficient for the target data message obtained by calibration according to the data message of the data set under the configuration pointing identifier and the message key thereof, and moving the target data message to the configuration pointing identifier based on the migration evaluation coefficient;

and determining at least two groups of data messages to be processed matched with the configuration priority of the dynamic configuration information based on the data messages under the configuration pointing identifier, and determining message fields in the at least two groups of data messages to be processed as the static configuration information.

9. An energy-saving electric cabinet with an infinite remote control alarm function, wherein a monitoring device is installed in the energy-saving electric cabinet, the monitoring device comprises a processor and a memory which are communicated with each other, and the processor executes a computer program called from the memory to realize the method of any one of the claims 1-4.

10. A computer-readable storage medium, on which a computer program is stored which, when executed, implements the method of any of claims 1-4.

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