CN113362197A - New energy network access full-flow through identification and alarm method and device thereof - Google Patents

Abstract

The application provides a new energy network connection full-flow through recognition and alarm method and a device thereof, which are used for acquiring a service flow data packet and a service identification code of a new energy project to be connected to the grid, and determining a network connection ring node and service behavior information of the new energy project to be connected to the grid; calling a preset flow data packet; comparing the preset process data packet with the service process data packet one by one; and if the node of the network connection link and/or the service behavior information is abnormal, positioning and alarming. According to the scheme, the pre-constructed grid-connected access flow template database is utilized, when a new energy project to be grid-connected and accessed is subjected to grid-connected access, the preset flow data packet is called, so that the preset flow data packet is compared with the service flow data packet, manual operation is not needed in the process, the service handling efficiency is improved, the service handling time is saved, abnormal conditions occurring in the process can be compared, positioning and alarming are carried out, and the reliability and the smoothness of the new energy project grid-connected access process are improved.

Description

New energy network access full-flow through identification and alarm method and device thereof

Technical Field

The invention relates to the technical field of data processing, in particular to a new energy networking full-flow through identification and alarm method and a device thereof.

Background

When a new energy project is constructed, the grid-connected access work of the new energy project is particularly critical.

Nowadays, new energy projects are integrated in a large scale and have influence on the safety, economy and stable operation of a power grid; with the increasing heavy grid-connected access work of new energy projects, higher requirements are put forward on the processing efficiency of the grid-connected access work of the new energy projects.

The process of the grid-connected access work of the new energy project generally relates to departments of development, planning, marketing, scheduling, transaction and the like of a power grid company, and each department is provided with a system or a platform for handling the services of different links in the grid-connected access work process of the new energy project. However, since there are many involved departments and many processing links, the business handling in each link needs to be performed manually, the business handling efficiency is low, and a long business handling time is consumed for the user.

Disclosure of Invention

In view of this, the embodiment of the invention provides a new energy networking full-flow through recognition and alarm method and a device thereof, so as to solve the problems that in the prior art, the service handling efficiency is low and the longer service handling time of a user is consumed in a new energy project grid-connected access working flow.

In order to achieve the above purpose, the embodiments of the present invention provide the following technical solutions:

on one hand, the embodiment of the invention provides a new energy networking full-process through identification and alarm method, which comprises the following steps:

acquiring a service flow data packet and a service identification code of a new energy project to be grid-connected and accessed, and determining access network link nodes and service behavior information corresponding to each access network link node when the new energy project to be grid-connected and accessed is grid-connected and accessed based on the service flow data packet;

calling a preset flow data packet corresponding to the service identification code from a pre-constructed grid-connected access flow template database, wherein the preset flow data packet comprises preset network connection link nodes and preset service behavior information corresponding to each preset network connection link node;

comparing the preset process data packet with the service process data packet one by one;

if the comparison result indicates that the network connection link node and/or the business behavior information is abnormal, the network connection link node and/or the business behavior information with the abnormality is positioned, and an alarm is given.

Optionally, the determining, based on the service flow data packet, a network access link node when the new energy project to be grid-connected and accessed is grid-connected and service behavior information corresponding to each network access link node includes:

analyzing the service flow data packet by using a preset data analysis template to obtain network connection ring section codes corresponding to the new energy project to be connected to the grid in the grid connection access process and service behavior information corresponding to each network connection ring section code;

and determining network connection link nodes based on the network connection link codes, and determining service behavior information corresponding to each network connection link node, wherein each network connection link code corresponds to a unique network connection link node.

Optionally, the determining, based on the service flow data packet, a network access link node when the new energy project to be grid-connected and accessed is grid-connected and service behavior information corresponding to each network access link node includes:

if the new energy project comprises a plurality of service process data packets, sequencing the service process data packets according to a preset sequencing grade, wherein the sequencing grade comprises a cascading sequence of network connection link nodes, a processing time limit and data acquisition time;

according to the sequence, analyzing each service process data packet by using a preset data analysis template to obtain a network connection link code corresponding to each service process data packet in the new energy project to be connected to the grid in the grid-connected access process and service behavior information corresponding to each network connection link code;

and determining network connection link nodes based on the network connection link codes, and determining service behavior information corresponding to each network connection link node, wherein each network connection link code corresponds to a unique network connection link node.

Optionally, the comparing the preset process data packet with the service process data packet one by one includes:

based on the sequence of the network connection ring section codes of the preset network connection ring section nodes, starting from the first preset network connection ring section node of the preset process data packet, comparing the network connection ring section codes and preset service behavior information in the preset process data packet with the network connection ring section codes and the service behavior information in the service process data packet;

if the network connection ring node codes corresponding to the preset network connection ring node in the same network connection link are not consistent with the network connection ring node codes corresponding to the network connection ring node, determining that the currently compared network connection ring node is abnormal;

if the preset service behavior information corresponding to the preset network connection node in the same network connection link is inconsistent with the service behavior information corresponding to the network connection node, determining that the service behavior information corresponding to the network connection node is abnormal;

and if the preset network connection link node in the same network connection link is consistent with the network connection link code corresponding to the network connection link node, and the preset business behavior information is consistent with the business behavior information, executing comparison of the next preset network connection link node until the last preset network connection link node.

Optionally, before performing the comparison of the next preset network connection link node, the method further includes:

if the current preset network connection ring node is connected with the next preset network connection ring node in series, pushing processing information to the next preset network connection ring node, wherein the processing information comprises a result that the current preset network connection ring node and the network connection ring node in the same network connection link are compared without abnormity, and a network connection ring node code and a service identification code of the current preset network connection ring node;

or,

if the current preset network connection ring node is connected in parallel with a plurality of next preset network connection ring nodes, pushing processing information to the next connected preset network connection ring node, wherein the processing information comprises a result that the current preset network connection link node and the network connection ring node in the same network connection link are compared without abnormity, and a network connection ring node code and a service identification code of the current preset network connection link node;

and executing comparison of the nodes of the next preset network connection link in parallel.

Optionally, the method further includes:

and performing compliance verification on the service behavior information corresponding to the currently compared network access link node, if the service behavior information passes the verification, continuing to perform the comparison, and if the service behavior information does not pass the verification, giving an alarm.

Optionally, the process of constructing the grid-connected access flow template database includes:

acquiring a historical service flow data packet and a historical service identification code of each new energy project;

analyzing business behavior information corresponding to each network connection link node obtained based on each historical business process data packet of the new energy project aiming at each new energy project to obtain a business process alarm rule of each network connection link node of each historical business process data packet corresponding to the new energy project, wherein the business process alarm rule comprises a network connection link code, transacting personnel information, transacting authority information and transacting time limit;

and the service flow alarm rule and the historical service identification code of each network connection link node of each historical service flow data packet corresponding to the new energy project are jointly used as a grid-connected access flow template database.

Optionally, the alarming includes:

analyzing and positioning network access link nodes with abnormality and/or business behavior information, and determining alarm information and an alarm pushing department, wherein the alarm information at least comprises abnormality evaluation information and alarm risk level;

the abnormality evaluation information at least comprises an abnormality type and an abnormality occurrence reason;

the alarm risk level is determined by a risk coefficient RPN, an alarm coefficient PWN or a link alarm coefficient LWN;

the risk factor RPN_ij＝S_ij×O_ijS indicates the abnormal severity, O indicates the abnormal occurrence frequency, i indicates a service identification code, j indicates a network connection link code, and ij indicates the jth link of the ith service process data packet;

the alarm coefficient

m,n∈{1，2,3，...，k k∈N}

The link alarm coefficient

Optionally, after the warning is performed, the method further includes:

and based on positioning and alarming, correcting the abnormal network access link node and/or service behavior information, and recording the correction time length and the correction result after the correction is finished.

On the other hand, the embodiment of the invention provides a new energy networking full-process through identification and alarm device, which comprises:

the acquisition unit is used for acquiring a service flow data packet and a service identification code of a new energy project to be connected to the grid;

the determining unit is used for determining access network link nodes when the new energy project to be subjected to grid-connected access is subjected to grid-connected access and business behavior information corresponding to each access network link node based on the business process data packet;

the calling unit is used for calling a preset flow data packet corresponding to the service identification code from a pre-constructed grid-connected access flow template database, wherein the preset flow data packet comprises preset network connection link nodes and preset service behavior information corresponding to each preset network connection link node;

the comparison unit is used for comparing the preset process data packet with the service process data packet one by one;

and the alarm unit is used for positioning the abnormal network connection link node and/or the abnormal business behavior information and giving an alarm if the comparison result indicates that the abnormal network connection link node and/or the abnormal business behavior information exist.

Based on the new energy access network full-process through identification and alarm method and device provided by the embodiment of the invention, a service process data packet and a service identification code of a new energy project to be connected to the grid are obtained, and access network link nodes and service behavior information corresponding to each access network link node when the new energy project to be connected to the grid is connected to the grid are determined based on the service process data packet; calling a preset flow data packet corresponding to the service identification code from a pre-constructed grid-connected access flow template database, wherein the preset flow data packet comprises preset network connection link nodes and preset service behavior information corresponding to each preset network connection link node; comparing the preset process data packet with the service process data packet one by one; if the comparison result indicates that the network connection link node and/or the business behavior information is abnormal, the network connection link node and/or the business behavior information with the abnormality is positioned, and an alarm is given. According to the scheme provided by the embodiment of the invention, the pre-established grid-connected access flow template database is utilized, and when the new energy project to be grid-connected and accessed is grid-connected and accessed, the pre-established flow data packet is called, so that the pre-established flow data packet is compared with the service flow data packet, the process does not need manual operation, the service handling efficiency is improved, the service handling time of a user is saved, the abnormal condition occurring in the process can be compared, the abnormal condition can be positioned and alarmed, so that related personnel can timely know the abnormal condition, corresponding treatment measures can be taken for the abnormal condition, and the reliability and the fluency of the new energy project grid-connected and accessed process are improved.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to the provided drawings without creative efforts.

Fig. 1 is a schematic flow chart of a new energy networking full-flow through identification and alarm method according to an embodiment of the present invention;

fig. 2 is a schematic diagram illustrating connection of network connection ring nodes of grid-connected access of a new energy project according to an embodiment of the present invention;

fig. 3 is a block diagram of a new energy networking full-flow through identification and alarm device according to an embodiment of the present invention.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

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

The terms "first," "second," "third," "fourth," and the like in the description and in the claims of the present application and in the drawings described above, if any, are used for distinguishing between similar elements and not necessarily for describing a particular sequential or chronological order. It will be appreciated that the data so used may be interchanged under appropriate circumstances such that the embodiments described herein may be practiced otherwise than as specifically illustrated or described herein.

According to the background technology, when a new energy project is accessed in a grid-connected mode, as the number of departments involved in the process processing of the grid-connected access work is large, the number of processing links is large, and the business handling of each link needs to be manually operated, the problems that the business handling efficiency is low, and the long business handling time of a user is consumed exist.

The embodiment of the invention provides a new energy network connection full-process through identification and alarm method and a device thereof, and aims to solve the problems that in the prior art, the service handling efficiency is low and the service handling time of a user is consumed in a new energy project grid-connected access working process. The following description is given by way of specific examples.

Referring to fig. 1, a flow diagram of a new energy networking full-flow through identification and alarm method according to an embodiment of the present invention is shown. The method comprises the following steps:

s101: and acquiring a service flow data packet and a service identification code of the new energy project to be connected to the grid.

In S101, the service flow data packet includes access network link nodes when a new energy project to be grid-connected is grid-connected and accessed and service behavior information corresponding to each access network link node.

In practical situations, different new energy projects are different in power generation departments or enterprises involved in grid-connected access, so that different new energy projects are different in grid-connected access flow, and different new energy projects are different in service flow data packets. If one power generation department or enterprise is involved when a new energy project is accessed in a grid-connected mode, the new energy project comprises a business process data packet; if a plurality of power generation departments or enterprises are involved when a new energy project is accessed in a grid-connected mode, the new energy project comprises a plurality of business process data packets. In a specific implementation, different service flow data packets are distinguished by service identification codes. That is, there is correspondence between the service flow data packet and the service identification code.

In the specific implementation process of S101, a service flow data packet and a service identification code of a new energy project to be grid-connected accessed are acquired, so that the service identification code is subsequently used to determine a preset flow data packet corresponding to the service flow data packet in a pre-constructed grid-connected access flow template database.

S102: and determining access network link nodes when the new energy project to be subjected to grid-connected access is subjected to grid-connected access and business behavior information corresponding to each access network link node based on the business process data packet.

In the process of specifically implementing S102, the service flow data packet of the new energy project to be grid-connected and accessed, which is obtained by executing S101, is analyzed, so that an access network link node when the new energy project to be grid-connected and accessed is grid-connected and service behavior information corresponding to each access network link node can be obtained.

Specifically, firstly, a preset data analysis template is used for analyzing a service flow data packet to obtain network connection link codes corresponding to new energy projects to be connected to the grid in the grid connection access process, and service behavior information corresponding to each network connection link code.

The data parsing template may be preset and used to specify a data type (for example, an integer type, a floating point type, a boolean type, a character type, and the like), a data length, a numerical range, a service identifier code, a network connection link code, and the like in the network connection access procedure.

The integrity, the standardability, the consistency, the accuracy, the uniqueness and the relevance of the service flow data packet can be checked through the data analysis template, and the service flow data packet is analyzed, so that each network connection link code corresponding to a new energy project to be connected to the grid in the grid connection access process and service behavior information corresponding to each network connection link code are obtained.

And then, according to each network connection ring node code corresponding to the new energy project to be subjected to grid-connected access in the grid-connected access process, which is obtained through analysis, determining a network connection ring node corresponding to the network connection ring node code based on each network connection ring node code, and determining service behavior information corresponding to the network connection ring node.

Wherein, each network connection ring code corresponds to a unique network connection ring node.

It can be understood that there is a corresponding relationship between the network connection ring segment codes and the network connection ring segment nodes, and therefore, based on each network connection ring segment code of the new energy project obtained through analysis, the network connection ring segment nodes corresponding to each network connection ring segment code of the new energy project can be further determined.

In addition, if the new energy project acquired by executing S101 includes a plurality of business process data packets, before analyzing the business process data packets by using a preset data analysis template, the following steps may be further executed: and sequencing the plurality of service flow data packets according to a preset sequencing level.

The preset sequencing level can comprise the cascade order of the network connection link nodes, the transaction time limit and the data acquisition time. It should be noted that the priority order of the ranking levels is: transaction time limit > data acquisition time > cascading order of network access link nodes.

That is, when a plurality of service flow data packets are sorted, the service flow data packets are preferentially sorted according to the sorting level of the transaction time limit, then the service flow data packets are sorted according to the sorting level of the data acquisition time, and finally the service flow data packets are sorted according to the sorting level of the cascade order of the network connection link nodes.

Therefore, after the plurality of business process data packets are sequenced, each business process data packet is analyzed by using a preset data analysis template according to the sequencing.

S103: and calling a preset flow data packet corresponding to the service identification code from a pre-constructed grid-connected access flow template database.

In S103, the grid-connected access flow template database is created based on the historical service flow data packet and the historical service identification code for analyzing each new energy project.

The preset flow data packet comprises preset network connection link nodes of the new energy project and preset service behavior information corresponding to each preset network connection link node.

In the specific implementation process of S103, based on the service identification code of the new energy project to be grid-connected and accessed obtained by executing S101, a preset flow data packet corresponding to the service identification code is called from the grid-connected access flow template database, so that the preset flow data packet is subsequently used to compare with the service flow data packet of the new energy project to be grid-connected and accessed.

S104: and comparing the preset process data packet with the service process data packet one by one.

In the process of specifically implementing S104, based on the preset flow data packet obtained by executing S103, the preset flow data packet is compared with the service flow data packet one by one, that is, the network access node codes corresponding to the preset network access node nodes of the preset flow data packet and the preset service behavior information corresponding to the preset network access node nodes are compared one by one, and the network access node codes corresponding to the network access node nodes of the service flow data packet and the service behavior information corresponding to the network access node nodes are compared one by one. And then, executing subsequent operations according to the comparison result.

Wherein, there may be four comparison results, which specifically include: and the network connection link node and/or the service behavior information are abnormal, or the network connection link node and the service behavior information are not abnormal.

And executing S105 when the network connection link node and/or the service behavior information is abnormal.

And when the network connection link node and the service behavior information are not abnormal, continuously adopting the comparison mode of S104 to compare the next preset network connection link node until warning or finishing the comparison of all the preset network connection link nodes and then finishing the grid-connected access.

S105: and positioning the abnormal network access link node and/or the abnormal business behavior information, and alarming.

In the process of S105, based on the execution of S104, it is determined that any compared network access node in the service flow data packet is abnormal, and/or the service behavior information corresponding to any compared network access node is abnormal, the network access node with the abnormality and/or the service behavior information corresponding to the network access node are/is located, and an alarm is given.

Specifically, the alarm may be performed in the following manner: analyzing and positioning the abnormal network connection link node and/or business behavior information, and determining alarm information and an alarm pushing department so as to push the alarm information to the corresponding alarm pushing department, so that the corresponding alarm pushing department can know the abnormal network connection link node and/or business behavior information.

The alarm information at least comprises abnormality evaluation information and alarm risk level.

The abnormality evaluation information includes at least an abnormality type and an abnormality occurrence cause.

The alarm risk level is determined by a risk coefficient RPN, an alarm coefficient PWN or a link alarm coefficient LWN. The alert risk levels may be divided into a reminder alert level, a secondary alert level, an important alert level, and an emergency alert level.

Wherein, the calculation formula of the risk coefficient RPN is as follows:

RPN_ij＝S_ij×O_ij (1)

in the formula (1), S denotes the severity of the anomaly, O denotes the frequency of occurrence of the anomaly, i denotes a service identifier code, j denotes a network connection link code, and ij denotes the jth link of the ith service flow data packet.

It should be noted that the abnormal severity indicates the abnormal severity of the node of the network access link or the service behavior information in which there is an abnormality, and the abnormal severity may be divided into four levels: mild, moderate, severe and severe.

The abnormal occurrence frequency indicates the abnormal occurrence frequency of the abnormal network connection link node or the abnormal business behavior information, and the abnormal occurrence frequency can be divided into five levels: few stages, occasional stages, many stages, and frequent stages.

The calculation formula of the warning coefficient PWN is expressed as follows:

in formula (2), m, N belongs to {1, 2, 3.

It should be noted that the alarm coefficient indicates the smoothness of the new energy project grid-connected access process to be grid-connected accessed. The lower the numerical value of the alarm coefficient is, the higher the smoothness of handling in the new energy project grid-connected access process is. Optionally, if the numerical value of the alarm coefficient exceeds a preset alarm coefficient threshold, the new energy project is prompted to be a key new energy project, and an alarm is sent to a previous management department to which the new energy project belongs.

The calculation formula of the link alarm coefficient LWN is as follows:

it should be noted that the link alarm coefficient indicates the handling smoothness of a certain network connection link node in the new energy project grid-connected access process to be grid-connected and accessed. The lower the numerical value of the link alarm coefficient is, the higher the handling fluency degree of the network connection link node in the new energy project grid-connected access process is. Optionally, if the link alarm coefficient exceeds the preset link alarm coefficient threshold, the network connection link node is prompted to be a key network connection link node, and an alarm is sent to the upper-level business department to which the network connection link node belongs.

Optionally, after the alarm is performed, the following steps may be further performed: and based on positioning and alarming, correcting the abnormal network access link node and/or service behavior information, and recording the correction time length and the correction result after the correction is finished.

By correcting the abnormal network access link nodes and/or the abnormal business behavior information, the method is beneficial to promoting the effective implementation of the new energy project grid-connected access process, and improves the reliability and the fluency of the new energy project grid-connected access process. And after the correction is finished, recording the correction time length and the correction result, so that the time consumption spent in the correction process and the correction result can be conveniently known subsequently.

Based on the new energy access network full-flow through identification and alarm method provided by the embodiment of the invention, the pre-constructed grid-connected access flow template database is utilized, when a new energy project to be grid-connected and accessed is grid-connected and accessed, the preset flow data packet is called, so that the preset flow data packet is compared with the business flow data packet, the process does not need manual operation, the business handling efficiency is improved, the business handling time of a user is saved, abnormal conditions occurring in the process can be positioned and alarmed by comparison, so that related personnel can timely know the abnormal conditions, corresponding treatment measures are taken for the abnormal conditions, and the reliability and the smoothness of the new energy project grid-connected and accessed process are improved.

Based on the new energy networking full-process through identification and alarm method provided by the embodiment of the invention, in some embodiments provided by the invention, the process of the step S104 is specifically realized, and the process comprises the following steps:

based on the sequence of the network connection ring codes corresponding to the preset network connection ring nodes of the preset process data packet, comparing the network connection ring codes in the preset process data packet with the network connection ring codes in the service process data packet from the first preset network connection ring node, and simultaneously comparing the preset service behavior information in the preset process data packet with the service behavior information in the service process data packet.

And if the network connection ring node codes corresponding to the preset network connection ring node in the same network connection ring node are inconsistent with the network connection ring node codes corresponding to the corresponding network connection ring node in the service process data packet, determining that the currently compared network connection ring node in the service process data packet is abnormal.

And if the preset service behavior information corresponding to the preset network connection node in the same network connection node is inconsistent with the service behavior information corresponding to the corresponding network connection node in the service flow data packet, determining that the service behavior information corresponding to the currently compared network connection node in the service flow data packet is abnormal.

If the network connection ring node codes corresponding to the preset network connection ring node in the same network connection ring node are consistent with the network connection ring node codes corresponding to the corresponding network connection ring node in the service process data packet, and the preset service behavior information corresponding to the preset network connection ring node is consistent with the service behavior information corresponding to the network connection ring node, determining that the currently compared network connection ring node in the service process data packet and the service behavior information corresponding to the currently compared network connection ring node are not abnormal, and continuing to perform comparison of the next preset network connection ring node.

It should be noted that the access network link codes corresponding to the preset access network link nodes of the preset flow data packet and the access network link codes corresponding to the access network link nodes in the service flow data packet are different, so that the execution progress of the new energy project to be grid-connected and accessed can be obtained according to the access network link codes corresponding to the preset access network link nodes which are currently compared and/or according to the access network link codes corresponding to the access network link nodes which are currently compared.

It should be further noted that, comparing the preset service behavior information in the preset flow data packet with the service behavior information in the service flow data packet refers to: and comparing the first transacting personnel information, the first transacting authority information and the first transacting time limit corresponding to the current preset network connection ring node in the preset flow data packet with the second transacting personnel information, the second transacting authority information and the second transacting time limit corresponding to the corresponding network connection ring node in the business flow data packet respectively.

In the comparison process, if the first transacting staff information is consistent with the second transacting staff information, the first transacting authority information is consistent with the second transacting authority information, and the first transacting time limit is greater than the second transacting time limit, the comparison between the preset business behavior information in the preset flow data packet and the business behavior information in the business flow data packet is abnormal, that is, the business behavior information corresponding to the currently compared network access node in the business flow data packet is abnormal compared with the preset business behavior information corresponding to the currently preset network access node in the preset flow data packet.

If the first transacting personnel information is inconsistent with the second transacting personnel information, and/or the first transacting authority information is inconsistent with the second transacting authority information, and/or the first transacting time limit is smaller than the second transacting time limit, comparing preset business behavior information in the preset flow data packet with business behavior information in the business flow data packet is abnormal, namely comparing the business behavior information corresponding to the currently compared network access node in the business flow data packet with the preset business behavior information corresponding to the currently preset network access node in the preset flow data packet is abnormal.

Before the comparison of the next preset network connection link node is executed, because the network connection link nodes may be connected in series and/or in parallel, and according to the series-parallel connection condition of the network connection link node, before the comparison of the next preset network connection link node is specifically executed, the comparison is performed according to the series-parallel connection condition, so that the comparison result is more accurate.

Based on the above process, for the series:

a1: and when the current preset network connecting link node is confirmed to be compared with the next preset network connecting link node according to the flow sequence, determining that the current preset network connecting link node is connected with the next preset network connecting link node in series.

A2: and pushing the processing information to the next preset network connection ring node.

In a2, the processing information includes a result that there is no abnormality in comparison between a current preset network connection link node and the network connection link node in the same network connection link, and a network connection link code and a service identification code of the current preset network connection link node.

For the parallel connection:

b1: and when the current preset network connecting ring node is confirmed to be connected with a plurality of next preset network connecting ring nodes through comparison according to the flow sequence, determining that the current preset network connecting ring node is connected with the plurality of next preset network connecting ring nodes in parallel.

B2: and simultaneously pushing the processing information to the next preset network connection ring node connected in parallel.

In B2, the processing information includes the result that there is no abnormality in the comparison between the current preset network connection link node and the network connection link node in the same network connection link, and the network connection link code and the service identifier code of the current preset network connection link node.

B3: and executing comparison of the nodes of the next preset network connection link in parallel.

For convenience of understanding, the content that the current preset network connection ring node is connected in series with the next preset network connection ring node, and the current preset network connection ring node is connected in parallel with a plurality of next preset network connection ring nodes is described by way of example with reference to a schematic diagram of connection of each network connection ring node of the new energy project grid-connected access shown in fig. 2.

E.g. with A₀₁Representing the current default network access link node, A₀₂Represents the next preset network connection link node, A₀₁Only with A₀₂Is connected, i.e. A₀₁And A₀₂Are connected in series.

Therefore, the current preset network connection link node is A₀₁Comparing with the network connection ring node in the service flow data packet in the same network connection link, wherein the current preset network connection link node is A₀₁A next preset network connection link node, namely A₀₂Pushing processing information; execution A₀₂And comparing the nodes of the network connecting links in the same network connecting link.

E.g. with A_n-1Indicating the current default network access link node, B₀₁And K₀₁All represent the next preset network connection link node, and, A_n-1And B₀₁、K₀₁Are all connected, i.e. A_n-1To B₀₁Flow scheme of composition and A_n-1To K₀₁The formed flows are connected in parallel.

Therefore, the current preset network connection link node is A_n-1Comparing with the network connection ring node in the service flow data packet in the same network connection link, wherein the current preset network connection link node is A_n-1To the next preset network connection link node in parallel, namely B₀₁And K₀₁Meanwhile, pushing processing information; parallel execution of B₀₁Comparing with the nodes of the same network connection link, and K₀₁And comparing the nodes of the network connecting links in the same network connecting link.

It is understood that, in FIG. 2, B_pAnd K_qAll directions are A_nPush-inProcessing information, i.e., A_nReceive B_pAnd K_qWhen the pushed processing information is available, A can be executed_nAnd (4) comparing. The remaining network link nodes in FIG. 2, e.g. A_nTo A_n+mThe alignment was also performed based on the above.

In the embodiment of the invention, the current preset network connection ring node pushes the processing information to the next preset network connection ring node so as to execute the comparison of the next preset network connection ring node, and the business handling efficiency is improved and the business handling time of the user is saved through the realization of automatic comparison.

Based on the comparison, optionally, before comparing the preset service behavior information corresponding to the preset network access node in the same network access link with the service behavior information corresponding to the corresponding network access node in the service flow data packet, the following steps may also be performed:

and performing compliance verification on the service behavior information corresponding to the network access node in the currently compared service flow data packet to judge whether the service behavior information corresponding to the network access node conforms to the preset regulation.

Specifically, the compliance audit refers to performing audit on service behavior information corresponding to the network access node, wherein the audit is performed on at least the following contents: new energy project name, grid-connected voltage level, energy type (photovoltaic, wind power, biomass energy, etc.), business license, power station scale, power station location, and approval (docketing) number.

If the service behavior information corresponding to the network access node passes the compliance audit, continuing to perform comparison; and if the service behavior information corresponding to the network access ring node does not pass the compliance audit, giving an alarm. Optionally, if the service behavior information corresponding to the network access node does not pass compliance verification, the alarm may be given while reminding relevant responsible personnel through a short message, an email, or the like.

It should be noted that, if the service behavior information corresponding to the last compared network connection node in the service flow data packet passes the compliance audit of the new energy project name, the grid-connected voltage level, the energy type (photovoltaic, wind power, biomass energy, etc.), the business license, the power station scale, the power station location and the approval (docket) document, the compliance audit of the new energy project name, the grid-connected voltage level, the energy type (photovoltaic, wind power, biomass energy, etc.), the business license, the power station scale, the power station location and the approval (docket) document can be performed on the service behavior information corresponding to the current compared network connection node, and only the new energy project name, the grid-connected voltage level, the energy type (photovoltaic, wind power, biomass energy, etc.), the business license, the power station scale, the new energy project name, the grid-connected voltage level, the energy type (photovoltaic, wind power, biomass energy, etc.), the business license, the power station scale and the approval (docket) document need to be performed on the service behavior information corresponding to the current compared network connection node, And (4) performing compliance verification on other information except the power station location and approval (record) document number.

Optionally, after performing compliance audit on the new energy project name, the grid-connected voltage level, the energy type (photovoltaic, wind power, biomass energy, etc.), the business license, the power station scale, the power station location and the approval (docket) document number on the first network connection link node in the service flow data packet, the information of the new energy project name, the grid-connected voltage level, the energy type (photovoltaic, wind power, biomass energy, etc.), the business license, the power station scale, the power station location and the approval (docket) document number is modified into a deadlock mode to prevent modification, so that the information does not need to be considered to be subjected to compliance audit when performing comparison on subsequent network connection link nodes.

Based on the new energy network access full-process through identification and alarm method provided by the embodiment of the invention, the construction process of the network access process template database used in the embodiment of the invention is described below.

The construction process of the grid-connected access flow template database comprises the following steps:

c1: and acquiring a historical service flow data packet and a historical service identification code of each new energy project.

In the specific implementation, for each new energy project, all historical service flow data packets of the new energy project are acquired, so that each historical service flow data packet is analyzed to obtain a corresponding access network link node when the new energy project is accessed in a grid-connected mode, and service behavior information corresponding to each access network link node.

Each historical service flow data packet corresponds to a historical service identification code; and acquiring all historical service identification codes of the new energy project aiming at each new energy project, so that a historical service flow data packet corresponding to the new energy project can be determined through the historical service identification codes of the new energy project.

C2: and analyzing the service behavior information corresponding to each network connection link node obtained based on each historical service flow data packet of the new energy project aiming at each new energy project to obtain the service flow alarm rule of each network connection link node of each historical service flow data packet corresponding to the new energy project.

At C2, the business process alarm rules include the networking link code, the transactor information, the transacting authority information, and the transaction time limit.

In the specific implementation, for each new energy project, each historical service flow data packet of the new energy project is analyzed to obtain service behavior information corresponding to each network connection link node of the historical service flow data packet, and the service behavior information corresponding to each network connection link node is analyzed, so that a service flow alarm rule of each network connection link node of each historical service flow data packet of the new energy project can be obtained, and a grid-connected access flow template database is constructed by using the service flow alarm rule subsequently.

C3: and the service flow alarm rule and the historical service identification code of each network connection link node of each historical service flow data packet corresponding to the new energy project are jointly used as a grid-connected access flow template database.

In a specific implementation, based on the historical service identification code of each historical service flow data packet of each new energy project obtained by executing step C1 and the service flow alarm rule of each network connection link node of each historical service flow data packet of each new energy project obtained by executing step C2, the historical service identification code and the service flow alarm rule are jointly used as a grid-connected access flow template database.

In the embodiment of the invention, a grid-connected access flow template database is constructed and obtained based on the acquired historical service flow data packet and the historical service identification code of each new energy project, so that the pre-constructed grid-connected access flow template database is subsequently utilized, and when a new energy project to be grid-connected and accessed is subjected to grid-connected access, the preset flow data packet is called, so that the preset flow data packet and the service flow data packet are compared.

Correspondingly, the embodiment of the invention also discloses a new energy network connection full-process through identification and alarm device.

Referring to fig. 3, a block diagram of a new energy networking full-flow through identification and alarm device according to an embodiment of the present invention is shown.

This new forms of energy connects full flow through of network discernment and alarm device includes: the device comprises an acquisition unit 301, a determination unit 302, a calling unit 303, a comparison unit 304 and an alarm unit 305.

And the acquisition unit is used for acquiring the service flow data packet and the service identification code of the new energy project to be connected to the grid.

And the determining unit is used for determining the access network link nodes when the new energy project to be subjected to grid-connected access is subjected to grid-connected access and the service behavior information corresponding to each access network link node based on the service flow data packet.

And the calling unit is used for calling a preset flow data packet corresponding to the service identification code from a pre-constructed grid-connected access flow template database, wherein the preset flow data packet comprises preset network connection link nodes and preset service behavior information corresponding to each preset network connection link node.

And the comparison unit is used for comparing the preset process data packet with the service process data packet one by one.

And the alarm unit is used for positioning the abnormal network connection link node and/or the abnormal business behavior information and giving an alarm if the comparison result indicates that the abnormal network connection link node and/or the abnormal business behavior information exist.

Optionally, the determining unit includes:

the first analysis module is used for analyzing the service flow data packet by using a preset data analysis template to obtain network connection link codes corresponding to the new energy project to be connected to the grid in the grid connection access process and service behavior information corresponding to each network connection link code.

The first determining module is used for determining the network connection link nodes based on the network connection link codes and determining the service behavior information corresponding to each network connection link node, wherein each network connection link code corresponds to a unique network connection link node.

Optionally, the determining unit includes:

and the sequencing module is used for sequencing the plurality of service flow data packets according to a preset sequencing grade if the new energy project comprises the plurality of service flow data packets, wherein the sequencing grade comprises the cascade sequence, the handling time limit and the data acquisition time of the network connection link node.

And the second analysis module is used for analyzing each service flow data packet by using a preset data analysis template according to the sequence to obtain a network connection link code corresponding to each service flow data packet in the new energy project to be subjected to grid-connected access in the grid-connected access process and service behavior information corresponding to each network connection link code.

And the second determining module is used for determining the network connection link nodes based on the network connection link codes and determining the service behavior information corresponding to each network connection link node, wherein each network connection link code corresponds to a unique network connection link node.

Optionally, the alignment unit includes:

and the comparison module is used for comparing the network connection ring codes in the preset process data packet, the preset business behavior information with the network connection ring codes in the business process data packet and the business behavior information, starting from the first preset network connection link node of the preset process data packet based on the sequence of the network connection ring codes of the preset network connection link nodes.

And the third determining module is used for determining that the currently compared network connection node is abnormal if the network connection node code corresponding to the preset network connection node in the same network connection node is inconsistent with the network connection node code corresponding to the network connection node.

And the fourth determining module is used for determining that the service behavior information corresponding to the network access node is abnormal if the preset service behavior information corresponding to the preset network access node in the same network access node is inconsistent with the service behavior information corresponding to the network access node.

And the execution module is used for executing the comparison of the next preset network connection link node until the last preset network connection link node if the preset network connection link node in the same network connection link is consistent with the network connection link node corresponding to the network connection link node in the same network connection link and the preset service behavior information is consistent with the service behavior information.

Optionally, the comparing unit further includes:

the first pushing module is used for pushing processing information to a next preset network connection link node if the current preset network connection link node is connected with the next preset network connection link node in series before the execution module executes comparison of the next preset network connection link node, and the processing information comprises a result that the current preset network connection link node and the network connection link node in the same network connection link are compared without abnormity, and a network connection link node code and a service identification code of the current preset network connection link node.

And the second pushing module is used for pushing processing information to the next preset network connection node in parallel if the current preset network connection node is connected in parallel with a plurality of next preset network connection nodes before the execution module executes the comparison of the next preset network connection node, wherein the processing information comprises the result that the comparison of the current preset network connection node and the network connection node in the same network connection link is abnormal, and the network connection node code and the service identification code of the current preset network connection node.

And the execution module is also used for executing the comparison of the next preset network connection link node in parallel.

Optionally, the comparing unit further includes:

and the auditing module is used for performing compliance auditing on the service behavior information corresponding to the currently compared network access link node, if the service behavior information passes the auditing, the execution module is continuously executed, and if the service behavior information does not pass the auditing, the alarm is given.

Optionally, the apparatus further comprises: and constructing a unit. The construction unit comprises:

and the acquisition module is used for acquiring the historical service flow data packet and the historical service identification code of each new energy project.

And the analysis module is used for analyzing the service behavior information corresponding to each network connection link node obtained based on each historical service flow data packet of the new energy project aiming at each new energy project to obtain the service flow alarm rule of each network connection link node of each historical service flow data packet corresponding to the new energy project, wherein the service flow alarm rule comprises network connection link codes, transactor information, transacting authority information and transacting time limit.

And the construction module is used for taking the service flow alarm rule of each network connection link node of each historical service flow data packet corresponding to the new energy project and the historical service identification code as a grid-connected access flow template database.

Optionally, the alarm unit is specifically configured to: analyzing and positioning network access link nodes with abnormality and/or business behavior information, and determining alarm information and an alarm pushing department, wherein the alarm information at least comprises abnormality evaluation information and alarm risk level;

the abnormality evaluation information at least comprises an abnormality type and an abnormality occurrence reason;

the alarm risk level is determined by a risk coefficient RPN, an alarm coefficient PWN or a link alarm coefficient LWN;

the said risk coefficient RPN_ij＝S_ij×O_ijS indicates the abnormal severity, O indicates the abnormal occurrence frequency, i indicates a service identification code, j indicates a network connection link code, and ij indicates the jth link of the ith service process data packet;

the alarm coefficient

m,n∈{1，2,3，...，k k∈N}

Alarm coefficient of the said report link

Optionally, the apparatus further comprises: and a correction unit.

And the correcting unit is used for correcting the abnormal network access link node and/or the abnormal business behavior information based on positioning and alarming, and recording the correction time length and the correction result after the correction is finished.

For the specific implementation principle of each unit and each module in the new energy network connection full-process through identification and alarm device disclosed in the embodiment of the present invention, reference may be made to corresponding contents in the new energy network connection full-process through identification and alarm method disclosed in the embodiment of the present invention, and details are not described here.

Based on the new energy network access full-process through recognition and alarm device provided by the embodiment of the invention, the acquisition unit acquires a service process data packet and a service identification code of a new energy project to be connected to the grid, and the determination unit determines access network link nodes when the new energy project to be connected to the grid is connected to the grid and service behavior information corresponding to each access network link node based on the service process data packet; the calling unit calls a preset flow data packet corresponding to the service identification code from a pre-constructed grid-connected access flow template database, wherein the preset flow data packet comprises preset network connection link nodes and preset service behavior information corresponding to each preset network connection link node; the comparison unit compares the preset process data packet with the service process data packet one by one; and if the comparison result indicates that the network connection link node and/or the service behavior information is abnormal, the alarm unit positions the abnormal network connection link node and/or the abnormal service behavior information and gives an alarm. According to the scheme provided by the embodiment of the invention, the pre-established grid-connected access flow template database is utilized, and when the new energy project to be grid-connected and accessed is grid-connected and accessed, the pre-established flow data packet is called, so that the pre-established flow data packet is compared with the service flow data packet, the process does not need manual operation, the service handling efficiency is improved, the service handling time of a user is saved, the abnormal condition occurring in the process can be compared, the abnormal condition can be positioned and alarmed, so that related personnel can timely know the abnormal condition, corresponding treatment measures can be taken for the abnormal condition, and the reliability and the fluency of the new energy project grid-connected and accessed process are improved.

The embodiments in the present specification are described in a progressive manner, and the same and similar parts among the embodiments are referred to each other, and each embodiment focuses on the differences from the other embodiments. In particular, the system or system embodiments are substantially similar to the method embodiments and therefore are described in a relatively simple manner, and reference may be made to some of the descriptions of the method embodiments for related points. The above-described system and system embodiments are only illustrative, wherein the units described as separate parts may or may not be physically separate, and the parts displayed as units may or may not be physical units, may be located in one place, or may be distributed on a plurality of network units. Some or all of the modules may be selected according to actual needs to achieve the purpose of the solution of the present embodiment. One of ordinary skill in the art can understand and implement it without inventive effort.

Those of skill would further appreciate that the various illustrative elements and algorithm steps described in connection with the embodiments disclosed herein may be implemented as electronic hardware, computer software, or combinations of both, and that the various illustrative components and steps have been described above generally in terms of their functionality in order to clearly illustrate this interchangeability of hardware and software. Whether such functionality is implemented as hardware or software depends upon the particular application and design constraints imposed on the implementation. Skilled artisans may implement the described functionality in varying ways for each particular application, but such implementation decisions should not be interpreted as causing a departure from the scope of the present invention.

The previous description of the disclosed embodiments is provided to enable any person skilled in the art to make or use the present invention. Various modifications to these embodiments will be readily apparent to those skilled in the art, and the generic principles defined herein may be applied to other embodiments without departing from the spirit or scope of the invention. Thus, the present invention is not intended to be limited to the embodiments shown herein but is to be accorded the widest scope consistent with the principles and novel features disclosed herein.

Claims (10)

1. A new energy network access full-flow through identification and alarm method is characterized by comprising the following steps:

acquiring a service flow data packet and a service identification code of a new energy project to be grid-connected and accessed, and determining access network link nodes and service behavior information corresponding to each access network link node when the new energy project to be grid-connected and accessed is grid-connected and accessed based on the service flow data packet;

calling a preset flow data packet corresponding to the service identification code from a pre-constructed grid-connected access flow template database, wherein the preset flow data packet comprises preset network connection link nodes and preset service behavior information corresponding to each preset network connection link node;

comparing the preset process data packet with the service process data packet one by one;

if the comparison result indicates that the network connection link node and/or the business behavior information is abnormal, the network connection link node and/or the business behavior information with the abnormality is positioned, and an alarm is given.

2. The method according to claim 1, wherein the determining, based on the service flow data packet, the access network link node when the new energy project to be grid-connected and accessed is grid-connected and the service behavior information corresponding to each access network link node includes:

analyzing the service flow data packet by using a preset data analysis template to obtain network connection ring section codes corresponding to the new energy project to be connected to the grid in the grid connection access process and service behavior information corresponding to each network connection ring section code;

and determining network connection link nodes based on the network connection link codes, and determining service behavior information corresponding to each network connection link node, wherein each network connection link code corresponds to a unique network connection link node.

3. The method according to claim 1, wherein the determining, based on the service flow data packet, the access network link node when the new energy project to be grid-connected and accessed is grid-connected and the service behavior information corresponding to each access network link node includes:

if the new energy project comprises a plurality of service process data packets, sequencing the service process data packets according to a preset sequencing grade, wherein the sequencing grade comprises a cascading sequence of network connection link nodes, a processing time limit and data acquisition time;

according to the sequence, analyzing each service process data packet by using a preset data analysis template to obtain a network connection link code corresponding to each service process data packet in the new energy project to be connected to the grid in the grid-connected access process and service behavior information corresponding to each network connection link code;

and determining network connection link nodes based on the network connection link codes, and determining service behavior information corresponding to each network connection link node, wherein each network connection link code corresponds to a unique network connection link node.

4. The method of claim 1, wherein the comparing the preset process data packet with the service process data packet one by one comprises:

based on the sequence of the network connection ring section codes of the preset network connection ring section nodes, starting from the first preset network connection ring section node of the preset process data packet, comparing the network connection ring section codes and preset service behavior information in the preset process data packet with the network connection ring section codes and the service behavior information in the service process data packet;

if the network connection ring node codes corresponding to the preset network connection ring node in the same network connection link are not consistent with the network connection ring node codes corresponding to the network connection ring node, determining that the currently compared network connection ring node is abnormal;

if the preset service behavior information corresponding to the preset network connection node in the same network connection link is inconsistent with the service behavior information corresponding to the network connection node, determining that the service behavior information corresponding to the network connection node is abnormal;

and if the preset network connection link node in the same network connection link is consistent with the network connection link code corresponding to the network connection link node, and the preset business behavior information is consistent with the business behavior information, executing comparison of the next preset network connection link node until the last preset network connection link node.

5. The method of claim 4, wherein before performing the comparison of the next default networking link node, further comprising:

if the current preset network connection ring node is connected with the next preset network connection ring node in series, pushing processing information to the next preset network connection ring node, wherein the processing information comprises a result that the current preset network connection ring node and the network connection ring node in the same network connection link are compared without abnormity, and a network connection ring node code and a service identification code of the current preset network connection ring node;

or,

if the current preset network connection ring node is connected in parallel with a plurality of next preset network connection ring nodes, pushing processing information to the next connected preset network connection ring node, wherein the processing information comprises a result that the current preset network connection link node and the network connection ring node in the same network connection link are compared without abnormity, and a network connection ring node code and a service identification code of the current preset network connection link node;

and executing comparison of the nodes of the next preset network connection link in parallel.

6. The method of claim 4, further comprising:

and performing compliance verification on the service behavior information corresponding to the currently compared network access link node, if the service behavior information passes the verification, continuing to perform the comparison, and if the service behavior information does not pass the verification, giving an alarm.

7. The method of claim 1, wherein the process of constructing the grid-connected access flow template database comprises:

acquiring a historical service flow data packet and a historical service identification code of each new energy project;

analyzing business behavior information corresponding to each network connection link node obtained based on each historical business process data packet of the new energy project aiming at each new energy project to obtain a business process alarm rule of each network connection link node of each historical business process data packet corresponding to the new energy project, wherein the business process alarm rule comprises a network connection link code, transacting personnel information, transacting authority information and transacting time limit;

and the service flow alarm rule and the historical service identification code of each network connection link node of each historical service flow data packet corresponding to the new energy project are jointly used as a grid-connected access flow template database.

8. The method of claim 1, wherein said alerting comprises:

analyzing and positioning network access link nodes with abnormality and/or business behavior information, and determining alarm information and an alarm pushing department, wherein the alarm information at least comprises abnormality evaluation information and alarm risk level;

the abnormality evaluation information at least comprises an abnormality type and an abnormality occurrence reason;

the alarm risk level is determined by a risk coefficient RPN, an alarm coefficient PWN or a link alarm coefficient LWN;

the risk factor RPN_ij＝S_ij×O_ijS indicates the abnormal severity, O indicates the abnormal occurrence frequency, i indicates a service identification code, j indicates a network connection link code, and ij indicates the jth link of the ith service process data packet;

the alarm coefficient

m,n∈{1，2,3，...，k k∈N}

The link alarm coefficient

9. The method of claim 1, wherein after the alerting, further comprising:

and based on positioning and alarming, correcting the abnormal network access link node and/or service behavior information, and recording the correction time length and the correction result after the correction is finished.

10. The utility model provides a new forms of energy net access full flow link up discernment and alarm device which characterized in that, the device includes:

the acquisition unit is used for acquiring a service flow data packet and a service identification code of a new energy project to be connected to the grid;

the determining unit is used for determining access network link nodes when the new energy project to be subjected to grid-connected access is subjected to grid-connected access and business behavior information corresponding to each access network link node based on the business process data packet;

the calling unit is used for calling a preset flow data packet corresponding to the service identification code from a pre-constructed grid-connected access flow template database, wherein the preset flow data packet comprises preset network connection link nodes and preset service behavior information corresponding to each preset network connection link node;

the comparison unit is used for comparing the preset process data packet with the service process data packet one by one;

and the alarm unit is used for positioning the abnormal network connection link node and/or the abnormal business behavior information and giving an alarm if the comparison result indicates that the abnormal network connection link node and/or the abnormal business behavior information exist.

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