CN112433776B - Power grid business processing system - Google Patents

Abstract

The application provides a power grid service processing system, which comprises a first service center and a second service center; the first service center is used for calling a first service component corresponding to the service requested by the first power grid service processing request to respond to the first power grid service processing request when the first power grid service processing request for accessing the existing corresponding service application is received; the second service center is used for calling a second service component corresponding to the service requested by the second power grid service processing request to respond to the second power grid service processing request when receiving the second power grid service processing request for accessing the non-corresponding service application, and the service center corresponding to the service is formed by the service component.

Description

Power grid business processing system

Technical Field

The application relates to the technical field of electric power data processing, in particular to a power grid service processing system.

Background

The power industry, one of the energy industries, generally relates to a large number of power businesses; when the type of the power service is updated in real time, the power grid service system also needs to be capable of adapting to the updating of the power service in time to perform corresponding processing as a device for processing the power service. However, the flexibility and the expansibility of the system architecture of the conventional power grid service system are poor, and the architecture based on the conventional power grid service system is difficult to adapt to processing the power service which is updated in real time, so that the processing efficiency is low.

Disclosure of Invention

In view of the above, it is necessary to provide a power grid service processing system for solving the above technical problems.

A grid services processing system, comprising: a first service center and a second service center;

the first service center comprises a plurality of first service components; the first service components are obtained by performing decoupling and subpackaging on the service application under the condition that the corresponding service application exists in the power grid service processing system; each first service component corresponds to one service in the service application, and the coupling degree between different services corresponding to different first service components is lower than the coupling degree between different services in the service application before the decoupling sub-packaging;

the second business center comprises a plurality of second service components; the plurality of second servitization components are obtained by performing service splitting abstraction on the power grid service under the condition that the power grid service does not have corresponding service application in the power grid service processing system; the coupling degree between different services corresponding to different second service components is lower than the coupling degree between different services of the power grid service before the service splitting abstraction;

The first service center is used for calling a first service component corresponding to the service requested by the first power grid service processing request to respond to the first power grid service processing request when receiving the first power grid service processing request for accessing the existing corresponding service application;

the second service center is used for calling a second service component corresponding to the service requested by the second power grid service processing request to respond to the second power grid service processing request when the second power grid service processing request for accessing the non-corresponding service application is received.

In one embodiment, a first service center and a second service center are deployed on the intranet side of the power grid service processing system; a first service agent corresponding to the first service center and a second service agent corresponding to the second service center are deployed on an external network side of the power grid service processing system opposite to the internal network side; an internal and external network safety exchange platform is arranged between the internal network side and the external network side of the power grid service processing system;

the first service agent is used for sending the first power grid service processing request to the internal and external network security exchange platform through a first external network access path preset by the internal and external network security exchange platform when receiving the first power grid service processing request;

The intranet and extranet security exchange platform is used for forwarding the first power grid service processing request to the first service center through a preset first intranet transmission path corresponding to the first service center after the security verification of the first power grid service processing request is passed;

the second service agent is used for sending the power grid service processing request to the internal and external network security exchange platform through a second external network access path preset by the internal and external network security exchange platform when receiving the second power grid service processing request;

and the internal and external network security exchange platform is used for forwarding the second power grid service processing request to the second service center through a preset second internal network transmission path corresponding to the second service center after the security verification of the second power grid service processing request is passed.

In one embodiment, the intranet and extranet security exchange platform comprises an extranet receiving agent, an intranet distribution service and a verification center;

the extranet receiving agent is used for receiving a first power grid service processing request sent by the first service agent through the first extranet access path and a second power grid service processing request sent by the second service agent through the second extranet access path, and sending the first power grid service processing request and the second power grid service processing request received within set time to the verification center in a unified manner;

After the security verification of the first power grid service processing request and the second power grid service processing request is passed, the verification center uniformly forwards the first power grid service processing request and the second power grid service processing request to the intranet distribution service;

the intranet distribution service is configured to forward the first power grid service processing request to the first service center via the first intranet transmission path, and forward the second power grid service processing request to the second service center via the second intranet transmission path.

In one of the embodiments, the first and second electrodes are,

the first service center is further used for storing a plurality of first service data formed by each first service component into a first database when responding to the first power grid service processing request;

the first service center is further configured to, when any one of the plurality of first service components accesses first service data of other first service components of the first service center, obtain corresponding first service data from the first database and send the corresponding first service data to the any one of the first service components;

the second service center is further configured to store, in a second database, a plurality of second service data formed by each second service component in response to the second power grid service processing request;

The second service center is further configured to, when any one of the second servitization components accesses second service data of other second servitization components of the second service center, obtain corresponding second service data from the second database and send the second service data to the any one of the second servitization components.

In one embodiment, the grid service processing system further comprises a data access component;

the first service center is further configured to, when any one of the first servitization components requests to access second service data of any one of the second servitization components, invoke a data access component to trigger the data access component to acquire the second service data of any one of the second servitization components from the second database and feed the second service data back to any one of the first servitization components after determining that a preset cross-center access right exists between the first service center and the second service center.

In one of the embodiments, the first and second parts of the device,

the first database is further configured to store the first service data into a first data table after receiving the first service data, split the first data table if the record data of the stored first data table exceeds a first preset record value, and store the split sub first data tables into the plurality of first sub databases respectively;

The second database is further configured to store the second service data into a second data table after receiving the second service data, split the second data table if the stored record data of the second data table exceeds a second preset record value, and store the split multiple sub-second data tables into multiple second sub-databases respectively.

In one embodiment, when the first database performs splitting processing on the first data table, the first database is further configured to determine a field of which the update frequency reaches a first preset update frequency in the first data table, and store first service data corresponding to the field of which the update frequency reaches the first preset update frequency in the same sub-first data table;

and/or the presence of a gas in the gas,

when the second database splits the second data table, the second database is further configured to determine a field of which the update frequency reaches a second preset update frequency in the second data table, and store second service data corresponding to the field of which the update frequency reaches the second preset update frequency in the same sub-second data table.

In one embodiment, when the power grid service processing system performs the decoupling package on the service application, the power grid service processing system is further configured to provide a user access interface for the service application, where the user access interface is used to integrate a plurality of access operations for accessing the service application in the decoupling package.

In one embodiment, the first plurality of servicing components and/or the second plurality of servicing components are formed after the power grid service system is subjected to a functional test and compiled.

In one embodiment, the compilation includes a mirror configuration and a runtime environment configuration.

According to the power grid business processing system, the service components are formed through decoupling, subpackaging and service splitting, the service/componentization of the power grid business is achieved, the coupling degree between the formed service components is lower than that between the original different services, the corresponding services can be flexibly expanded by the power grid business processing system conveniently, the corresponding business centers are formed through the service components, the response can be timely carried out when a power grid business processing request is received, and the processing efficiency of the power grid business processing system is improved.

Drawings

FIG. 1 is a schematic diagram of a grid services processing system in one embodiment;

FIG. 2 is a schematic diagram of a grid service processing system in another embodiment;

FIG. 3 is a schematic flow chart of a grid service processing method according to an embodiment;

FIG. 4 is a block diagram of a grid services processing apparatus according to an embodiment;

FIG. 5 is a diagram illustrating an internal structure of a computer device according to an embodiment.

Detailed Description

In order to make the objects, technical solutions and advantages of the present application more clearly understood, the present application is further described in detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are merely illustrative of and not restrictive on the broad application.

Reference in the specification to "an embodiment" means that a particular feature, structure, or characteristic described in connection with the embodiment can be included in at least one embodiment of the specification. The appearances of the phrase in various places in the specification are not necessarily all referring to the same embodiment, nor are separate or alternative embodiments mutually exclusive of other embodiments. It is explicitly and implicitly understood by a person skilled in the art that the embodiments described herein can be combined with other embodiments.

The application provides a power grid service processing system, which comprises a first service center and a second service center; wherein the first service center comprises a plurality of first service components; the first service components are obtained by decoupling and subpackaging service applications under the condition that the corresponding service applications exist in the power grid service processing system; each first service component corresponds to one service in the service application, and the coupling degree between different services corresponding to different first service components is lower than the coupling degree between different services in the service application before the decoupling sub-packaging; the second business center comprises a plurality of second service components; the plurality of second service components are obtained by splitting and abstracting the service of the power grid service under the condition that the power grid service does not have corresponding service application in the power grid service processing system; the coupling degree between different services corresponding to different second servitization components is lower than the coupling degree between different services of the power grid service before the service is split and abstracted.

Wherein, the business center composed of a plurality of service components can also be called micro application; specifically, as shown in fig. 1, micro applications are examples of micro applications that are targeted to perform a specific function or functions, each micro application includes one or more servitization components (i.e., componentization and servitization), the coupling of the servitization components in the application and the database is minimized, and each micro application is elastically extensible. A micro-application is an application deployment representation. It can be understood that the service component can be deployed on a service cloud management platform of the power grid business processing system to realize service support.

In the above embodiment, as shown in fig. 2, if a corresponding service application already exists in a power grid service processing system of a certain power grid service, when performing service/componentization, decoupling and packetizing may be directly performed on the service application to obtain a plurality of service components, so as to form a micro application (a first service center). If a certain power grid service does not have a corresponding service application in the power grid service processing system, the service of the power grid service can be split during the service/componentization, a plurality of service components are obtained in an abstract mode, and a micro application (a second service center) is formed.

Further, as shown in fig. 3, when processing a grid service, in step S301, if a first service center of the grid service processing system receives a first grid service processing request for accessing a service application that already exists, a first servitization component corresponding to a service requested by the first grid service processing request is invoked to respond to the first grid service processing request; step S302, if a second service center of the grid service processing system receives a second grid service processing request for accessing the service application that does not exist, a second servitization component corresponding to the service requested by the second grid service processing request is invoked to respond to the second grid service processing request.

That is, if the processed grid service is before servitization/componentization, and a service application capable of processing the grid service already exists, the first service center calls the corresponding servitization component to respond; and if the processed power grid service does not have the service application capable of processing the power grid service before the service/componentization, calling the corresponding service component by the second service center to respond.

Therefore, in the embodiment, the service components are formed by decoupling, subpackaging and service splitting, so that the service/componentization of the power grid service is realized, the coupling degree between the formed service components is lower than that between the original different services, the corresponding service is conveniently and flexibly expanded by the power grid service processing system, the corresponding service center is formed by the service components, the response can be timely carried out when the power grid service processing request is received, and the processing efficiency of the power grid service processing system is improved.

In one embodiment, a first service center and a second service center are deployed on the intranet side of a power grid service processing system; a first service agent corresponding to a first service center and a second service agent corresponding to a second service center are deployed on an outer network side of the power grid service processing system opposite to the inner network side; the power grid business processing system is provided with an internal and external network safety exchange platform between an internal network side and an external network side; the first service agent is used for sending a first power grid service processing request to the internal and external network security exchange platform through a first external network access path preset by the internal and external network security exchange platform when the first power grid service processing request is received; the internal and external network security exchange platform is used for forwarding the first power grid service processing request to the first service center through a preset first internal network transmission path corresponding to the first service center after the security verification of the first power grid service processing request is passed; the second service agent is used for sending the power grid service processing request to the internal and external network safety exchange platform through a second external network access path preset by the internal and external network safety exchange platform when receiving the second power grid service processing request; and the internal and external network security exchange platform is used for forwarding the second power grid service processing request to the second service center through a preset second internal network transmission path corresponding to the second service center after the security verification of the second power grid service processing request is passed.

That is to say, in order to ensure the safety of the grid service processing, the grid service processing system may be divided into an intranet side and an extranet side, where the intranet side is used to deploy a service center, and the extranet side is used to deploy a service agent corresponding to the service center. An internal and external network security exchange platform is arranged between the internal network side and the external network side, each service center and the corresponding service agent interact through the internal and external network security exchange platform, the internal and external network security exchange platform can be configured with appointed access paths (namely an external network access path and an internal network transmission path) of the external network side and the internal network side, and the power grid service processing request is transmitted through the appointed access path.

Further, the internal and external network security exchange platform comprises an external network receiving agent, an internal network distribution service and a verification center; the outer network receiving agent is used for receiving a first power grid service processing request sent by the first service agent through the first outer network access path and a second power grid service processing request sent by the second service agent through the second outer network access path, and uniformly sending the first power grid service processing request and the second power grid service processing request received within set time to the verification center; after the safety verification of the first power grid service processing request and the second power grid service processing request is passed, the verification center uniformly forwards the first power grid service processing request and the second power grid service processing request to an intranet distribution service; and the intranet distribution service is used for forwarding the first power grid business processing request to the first business center through a first intranet transmission path and forwarding the second power grid business processing request to the second business center through a second intranet transmission path.

That is to say, the service agent on the external network side can send a request to the external network receiving agent, the external network receiving agent uniformly forwards the request received within the set time to the verification center for verification, and forwards the request to the internal network distribution agent after the verification is passed, thereby reducing the interactive work between the internal and external network security exchange platform and each service center.

In an application example, i intranet and extranet services-intranet domain: the intranet and intranet security exchange platform needs to be configured with an access path of an appointed extranet side and an intranet side, so that in order to reduce the interaction work between the intranet and intranet security exchange platforms and each service center, the intranet side forwards the intranet and intranet security exchange platforms in a unified manner and then transfers the intranet and intranet security exchange platforms to specific micro services. And printing the log of the intranet and extranet service based on the tangent plane, analyzing the data packet in the request according to the specified format of a protocol XML (eXtensible Markup Language), and returning in the configured calling result format. Inner and outer network agents-outer network domain: in order to reduce the interaction work between the internal and external network security interaction platform and each service center, the service agent at the external network side can uniformly send the request to the external network receiving agent, and the request can be forwarded to the internal network distribution agent after the transfer of the internal and external network security interaction platform. Specifically, the address of the intranet and extranet security exchange platform can be specified according to the environment static file of the agent, the file is defined based on the protocol format, the requested data packet is assembled into a specific file, and the request is sent to the intranet and extranet security exchange platform through a calling tool.

The processing of access service data to a service center is described below:

in one embodiment, the first service center is further configured to store a plurality of first service data formed by each first service component in the first database when responding to the first grid service processing request; the first service center is further configured to, when any one of the plurality of first service components accesses first service data of other first service components of the first service center, obtain corresponding first service data from the first database and send the corresponding first service data to any one of the first service components. The second service center is also used for storing a plurality of second service data formed by each second service component into a second database when responding to the second power grid service processing request; the second service center is further configured to, when any one of the second servitization components accesses second service data of other second servitization components of the second service center, obtain corresponding second service data from the second database and send the corresponding second service data to any one of the second servitization components.

That is to say, in the above embodiment, the service components belonging to the same service center may directly access service data to each other, so as to improve the efficiency of the service center in processing the power grid service.

Further, the power grid service processing system also comprises a data access component; the first service center is further used for calling the data access component when any one of the first service components requests to access the second service data of any one of the second service components, so as to trigger the data access component to acquire the second service data of any one of the second service components from the second database and feed the second service data back to any one of the first service components after determining that a preset cross-center access right exists between the first service center and the second service center.

That is to say, if the service components between different service centers need to access the service data, the cross-center access can be performed after confirming that the cross-center access right exists through the data access component based on the preset data access component, thereby further ensuring the security and reliability of the access service data.

In one embodiment, when the service data is stored, data decoupling processing can be performed on the service data, and the data decoupling can be in three modes of a sub-library, a sub-table and a small table. Dividing a library: horizontally splitting, and storing the same table into different databases respectively according to the splitting key; dividing the table into two parts: the method comprises the following steps of vertically splitting, wherein one table in a library is divided by a splitting key and stored into a plurality of tables; ③ Small watch: broadcasting, storing the small table into a plurality of databases.

Specifically, the first database is further configured to store the first service data into the first data table after receiving the first service data, split the first data table if the record data of the stored first data table exceeds a first preset record value, and store the split sub first data tables into the plurality of first sub databases respectively; and the second database is further used for storing the second service data into a second data table after receiving the second service data, splitting the second data table if the stored record data of the second data table exceeds a second preset record value, and storing the plurality of sub second data tables obtained by splitting into the plurality of second sub databases respectively.

That is to say, when the recorded data stored in the data table exceeds the preset recorded value, the data in the data table is stored in a split manner, so that the normal storage of the power grid service data is ensured.

Further, when the first database splits the first data table, the first database is further configured to determine a field of which the update frequency reaches a first preset update frequency in the first data table, and store the first service data corresponding to the field of which the update frequency reaches the first preset update frequency in the same sub-first data table; and/or when the second database splits the second data table, the second database is further configured to determine a field of which the update frequency reaches a second preset update frequency in the second data table, and store second service data corresponding to the field of which the update frequency reaches the second preset update frequency in the same sub-second data table.

That is to say, when split storage is performed, the service data corresponding to the field with the higher update frequency is split and stored in the same data table, and when the service data is updated, the service data with the higher update frequency is stored in the same data table, so that reading of multiple data tables can be avoided, and the update efficiency of the service data can be improved.

In one embodiment, when the decoupling package is performed on the service application, the power grid service processing system is further configured to provide a user access interface for the service application, where the user access interface is used for integrating multiple access operations for accessing the service application in the decoupling package.

That is to say, in the process of decoupling and packetizing, if a user needs to access a service application, the user can access the service application based on a user access interface of the power grid service processing system, and the service application can be in an imperceptible transition in an interface integration manner.

Furthermore, in order to ensure that the servitization components operate normally, the first servitization components and/or the second servitization components are formed after the power grid service system completes the function test and is compiled. Further, the compilation may include a mirror configuration and a runtime environment configuration.

Illustratively, after the servitization component is formed, Docker (open source application container engine) packaging can be performed through automatic compilation and packaging tools; the process mainly executes mirror image management, running environment configuration, automatic packaging and the like.

It should be understood that although the steps in the flowcharts of fig. 1 to 3 are shown in order as indicated by the arrows, the steps are not necessarily performed in order as indicated by the arrows. The steps are not performed in the exact order shown and described, and may be performed in other orders, unless explicitly stated otherwise. Moreover, at least some of the steps in fig. 1 to 3 may include multiple steps or multiple stages, which are not necessarily performed at the same time, but may be performed at different times, and the order of performing the steps or stages is not necessarily sequential, but may be performed alternately or alternately with other steps or at least some of the other steps or stages.

In one embodiment, as shown in fig. 4, there is provided a grid service processing apparatus, including: a first service center 401 and a second service center 402;

the first business center 401 includes a plurality of first servitization components; the first service components are obtained by performing decoupling and subpackaging on the service application under the condition that the corresponding service application exists in the power grid service processing system; each first service component corresponds to one service in the service application, and the coupling degree between different services corresponding to different first service components is lower than the coupling degree between different services in the service application before the decoupling sub-packaging;

The second business center 402 includes a plurality of second servitization components; the second service components are obtained by splitting and abstracting the service of the power grid service under the condition that the power grid service does not have corresponding service application in the power grid service processing system; the coupling degree between different services corresponding to different second servitization components is lower than the coupling degree between different services of the power grid service before the services are split and abstracted;

the first service center 401 is configured to, when receiving a first power grid service processing request for accessing an existing corresponding service application, invoke a first servization component corresponding to a service requested by the first power grid service processing request to respond to the first power grid service processing request;

the second service center 402 is configured to, when a second grid service processing request for accessing the service application that does not exist correspondingly is received, invoke a second servization component corresponding to the service requested by the second grid service processing request to respond to the second grid service processing request.

In one implementation, a first service center and a second service center are deployed on an intranet side of a power grid service processing system; a first service agent corresponding to a first service center and a second service agent corresponding to a second service center are deployed on an outer network side of the power grid service processing system, wherein the outer network side is opposite to an inner network side; an internal and external network safety exchange platform is arranged between the internal network side and the external network side of the power grid service processing system;

The first service agent is used for sending a first power grid service processing request to the internal and external network security exchange platform through a first external network access path preset by the internal and external network security exchange platform when receiving the first power grid service processing request;

the internal and external network security exchange platform is used for forwarding the first power grid service processing request to the first service center through a preset first internal network transmission path corresponding to the first service center after the security verification of the first power grid service processing request is passed;

the second service agent is used for sending the power grid service processing request to the internal and external network safety exchange platform through a second external network access path preset by the internal and external network safety exchange platform when receiving the second power grid service processing request;

and the internal and external network security exchange platform is used for forwarding the second power grid service processing request to the second service center through a preset second internal network transmission path corresponding to the second service center after the security verification of the second power grid service processing request is passed.

In one implementation, the intranet and extranet security exchange platform comprises an extranet receiving agent, an intranet distribution service and a verification center;

the external network receiving agent is used for receiving a first power grid service processing request sent by the first service agent through the first external network access path and a second power grid service processing request sent by the second service agent through the second external network access path, and uniformly sending the first power grid service processing request and the second power grid service processing request received within set time to the verification center;

After the safety verification of the first power grid service processing request and the second power grid service processing request is passed, the verification center uniformly forwards the first power grid service processing request and the second power grid service processing request to an intranet distribution service;

and the intranet distribution service is used for forwarding the first power grid service processing request to the first service center through a first intranet transmission path and forwarding the second power grid service processing request to the second service center through a second intranet transmission path.

In one implementation, the first service center is further configured to store, in a first database, a plurality of first service data formed by each first service component in response to the first grid service processing request; the first service center is further configured to, when any one of the plurality of first service components accesses first service data of other first service components of the first service center, obtain corresponding first service data from the first database and send the corresponding first service data to any one of the first service components.

In one implementation, the second service center is further configured to store, in the second database, a plurality of second service data formed by each second servitization component in response to the second grid service processing request; the second service center is further configured to, when any one of the second servitization components accesses second service data of other second servitization components of the second service center, obtain corresponding second service data from the second database and send the corresponding second service data to any one of the second servitization components.

In one implementation, the grid services processing system further comprises a data access component;

the first service center is further used for calling the data access component when any one of the first service components requests to access the second service data of any one of the second service components, so as to trigger the data access component to acquire the second service data of any one of the second service components from the second database and feed the second service data back to any one of the first service components after determining that a preset cross-center access right exists between the first service center and the second service center.

In one implementation, the first database is further configured to store the first service data into the first data table after receiving the first service data, split the first data table if the record data of the stored first data table exceeds a first preset record value, and store the split multiple sub first data tables into the multiple first sub databases respectively.

In one implementation, the second database is further configured to store the second service data into the second data table after receiving the second service data, split the second data table if the record data of the stored second data table exceeds a second preset record value, and store the multiple sub-second data tables obtained by splitting into the multiple second sub-databases, respectively.

In one implementation, when the first database performs splitting processing on the first data table, the first database is further configured to determine a field whose update frequency reaches a first preset update frequency in the first data table, and store the first service data corresponding to the field whose update frequency reaches the first preset update frequency into the same sub-first data table.

In one implementation, when the second database performs splitting processing on the second data table, the second database is further configured to determine a field whose update frequency reaches a second preset update frequency in the second data table, and store the second service data corresponding to the field whose update frequency reaches the second preset update frequency in the same sub-second data table.

In one implementation, when the power grid service processing system performs the decoupling sub-package on the service application, the power grid service processing system is further configured to provide a user access interface for the service application, where the user access interface is used for integrating multiple access operations for accessing the service application in the decoupling sub-package.

In one implementation, the plurality of first servitization components and/or the plurality of second servitization components are formed after the power grid service system is subjected to functional testing and compiled.

In one implementation, the compilation includes a mirror configuration and a runtime environment configuration.

For specific definition of the grid service processing device, reference may be made to the definition of the other embodiments above, and details are not described here again. All or part of each module in the power grid service processing device can be realized by software, hardware and a combination thereof. The modules can be embedded in a hardware form or independent from a processor in the computer device, and can also be stored in a memory in the computer device in a software form, so that the processor can call and execute operations corresponding to the modules.

In one embodiment, a computer device is provided, which may be a server, and the internal structure thereof may be as shown in fig. 5. The computer device includes a processor, a memory, and a network interface connected by a system bus. Wherein the processor of the computer device is configured to provide computing and control capabilities. The memory of the computer device comprises a nonvolatile storage medium and an internal memory. The non-volatile storage medium stores an operating system, a computer program, and a database. The internal memory provides an environment for the operation of an operating system and computer programs in the non-volatile storage medium. The database of the computer device is used for storing the power grid service data. The network interface of the computer device is used for communicating with an external terminal through a network connection. The computer program is executed by a processor to implement a method performed by modules in a grid service processing system.

It will be appreciated by those skilled in the art that the configuration shown in fig. 5 is a block diagram of only a portion of the configuration associated with the present application, and is not intended to limit the computing device to which the present application may be applied, and that a particular computing device may include more or less components than those shown, or may combine certain components, or have a different arrangement of components.

In an embodiment, a computer device is provided, comprising a memory and a processor, the memory storing a computer program, the processor implementing the steps of the above method embodiments when executing the computer program.

In one embodiment, a computer-readable storage medium is provided, on which a computer program is stored, which computer program, when being executed by a processor, carries out the steps of the respective method embodiments described above.

It will be understood by those skilled in the art that all or part of the processes of the methods of the embodiments described above may be implemented by hardware instructions of a computer program, which may be stored in a non-volatile computer-readable storage medium, and when executed, may include the processes of the embodiments of the methods described above. Any reference to memory, storage, database or other medium used in the embodiments provided herein can include at least one of non-volatile and volatile memory. Non-volatile Memory may include Read-Only Memory (ROM), magnetic tape, floppy disk, flash Memory, optical Memory, or the like. Volatile Memory can include Random Access Memory (RAM) or external cache Memory. By way of illustration and not limitation, RAM can take many forms, such as Static Random Access Memory (SRAM) or Dynamic Random Access Memory (DRAM), among others.

All possible combinations of the technical features in the above embodiments may not be described for the sake of brevity, but should be considered as being within the scope of the present disclosure as long as there is no contradiction between the combinations of the technical features.

The above examples only express several embodiments of the present application, and the description thereof is more specific and detailed, but not construed as limiting the scope of the invention. It should be noted that, for a person skilled in the art, several variations and modifications can be made without departing from the concept of the present application, which falls within the scope of protection of the present application. Therefore, the protection scope of the present patent shall be subject to the appended claims.

Claims (10)

1. A grid service processing system, comprising: a first service center and a second service center; the first service center and the second service center are deployed on the intranet side of the power grid service processing system; an external network side of the power grid business processing system, which is opposite to the internal network side, is provided with a first service agent corresponding to the first business center and a second service agent corresponding to the second business center; an internal and external network safety exchange platform is arranged between the internal network side and the external network side of the power grid service processing system;

The first service center comprises a plurality of first service components; the first service components are obtained by decoupling and subpackaging the service applications under the condition that the corresponding service applications exist in the power grid service processing system; each first service component corresponds to one service in the service application, and the coupling degree between different services corresponding to different first service components is lower than the coupling degree between different services in the service application before the decoupling sub-packaging;

the second business center comprises a plurality of second servitization components; the plurality of second servitization components are obtained by splitting and abstracting the service of the power grid service under the condition that the power grid service does not have corresponding service application in the power grid service processing system; the coupling degree between different services corresponding to different second service components is lower than the coupling degree between different services of the power grid service before the service splitting abstraction;

the first service center is used for calling a first service component corresponding to the service requested by the first power grid service processing request to respond to the first power grid service processing request when receiving the first power grid service processing request for accessing the existing corresponding service application;

The second service center is used for calling a second service component corresponding to the service requested by the second power grid service processing request to respond to the second power grid service processing request when the second power grid service processing request for accessing the non-corresponding service application is received;

the first service agent is used for sending the first power grid service processing request to the internal and external network security exchange platform through a first external network access path preset by the internal and external network security exchange platform when receiving the first power grid service processing request;

the intranet and extranet security exchange platform is used for forwarding the first power grid service processing request to the first service center through a preset first intranet transmission path corresponding to the first service center after the security verification of the first power grid service processing request is passed;

the second service agent is used for sending the power grid service processing request to the internal and external network security exchange platform through a second external network access path preset by the internal and external network security exchange platform when receiving the second power grid service processing request;

And the intranet and extranet security exchange platform is used for forwarding the second power grid service processing request to the second service center through a preset second intranet transmission path corresponding to the second service center after the security verification on the second power grid service processing request is passed.

2. The system according to claim 1, wherein the intranet and extranet security exchange platform comprises an extranet receiving agent, an intranet distribution service and a verification center;

the extranet receiving agent is used for receiving a first power grid service processing request sent by the first service agent through the first extranet access path and a second power grid service processing request sent by the second service agent through the second extranet access path, and sending the first power grid service processing request and the second power grid service processing request received within set time to the verification center in a unified manner;

after the safety verification of the first power grid service processing request and the second power grid service processing request is passed, the verification center uniformly forwards the first power grid service processing request and the second power grid service processing request to the intranet distribution service;

The intranet distribution service is configured to forward the first grid service processing request to the first service center via the first intranet transmission path, and forward the second grid service processing request to the second service center via the second intranet transmission path.

3. The system of claim 1,

the first service center is further used for storing a plurality of first service data formed by each first service component into a first database when responding to the first power grid service processing request;

the first service center is further configured to, when any one of the plurality of first service components accesses first service data of other first service components of the first service center, obtain corresponding first service data from the first database and send the corresponding first service data to the any one of the first service components;

the second service center is further configured to store, in a second database, a plurality of second service data formed by each second service component in response to the second power grid service processing request;

the second service center is further configured to, when any one of the second servitization components accesses second service data of other second servitization components of the second service center, obtain corresponding second service data from the second database and send the second service data to the any one of the second servitization components.

4. The system of claim 3, wherein the grid services processing system further comprises a data access component;

the first service center is further configured to, when any one of the first service components requests to access second service data of any one of the second service components, invoke a data access component to trigger the data access component to acquire the second service data of any one of the second service components from the second database and feed the second service data back to any one of the first service components after determining that a preset cross-center access right exists between the first service center and the second service center.

5. The system of claim 3,

the first database is further configured to store the first service data into a first data table after receiving the first service data, split the first data table if the record data of the stored first data table exceeds a first preset record value, and store the split multiple sub-first data tables into multiple first sub-databases respectively;

the second database is further configured to store the second service data into a second data table after receiving the second service data, split the second data table if the record data of the stored second data table exceeds a second preset record value, and store the split multiple sub-second data tables into multiple second sub-databases respectively.

6. The system according to claim 3, wherein the first database is further configured to determine a field with an update frequency reaching a first preset update frequency in the first data table when the first data table is split, and store the first service data corresponding to the field with the update frequency reaching the first preset update frequency in the same sub-first data table.

7. The system according to claim 3, wherein the second database is further configured to determine a field whose update frequency reaches a second preset update frequency in the second data table when performing the splitting process on the second data table, and store the second service data corresponding to the field whose update frequency reaches the second preset update frequency in the same sub-second data table.

8. The system of claim 1, wherein the grid services processing system, when performing the decoupling package on the service application, is further configured to provide a user access interface for the service application, the user access interface being configured to integrate a plurality of access operations for accessing the service application in the decoupling package.

9. The system according to any one of claims 1 to 8, wherein the first plurality of servitization components and/or the second plurality of servitization components are formed after the grid service system is subjected to functional testing and compiled.

10. The system of claim 9, wherein the compilation comprises a mirror configuration and a runtime environment configuration.

Images