CN116382696A - Engineering attribute dynamic analysis and submission method based on factory object position number - Google Patents

Abstract

The invention discloses a dynamic analysis and submission method of engineering properties based on a factory object position number, which belongs to the field of data call in the metallurgical industry, and constructs a factory decomposition structure perspective view and flexibly configures an engineering position number property group by endowing key values to characteristic properties of each factory object position number in a factory decomposition structure, and more flexibly submits engineering data of a factory object to a required system, and can output a data structure suitable for scenes only by simple business requirement rule description, so that the data requirements of various scenes can be flexibly met; based on the attribute service requirement, the target attribute group is obtained through simple configuration, and only the target attribute group is transmitted, so that the safety of the data is effectively ensured.

Description

Engineering attribute dynamic analysis and submission method based on factory object position number

Technical Field

The invention belongs to the field of data calling in the metallurgical industry, and particularly relates to a dynamic analysis and submission method of engineering properties based on a factory object position number.

Background

When the traditional metallurgical industry application system processes data requirements of projects, process facilities, work decomposition packages and the like related to the engineering field, a bus or micro-service mode is adopted, but a certain technical bottleneck exists in the aspect of multi-scene data structure processing, and particularly, cross-service data and data attributes are processed, so that the safety and convenience of data distribution are not high. The attribute management is started to be established in the existing factory decomposition structure, through the realization of the factory object position numbers, and the factory object position numbers have a large number of attributes and can be applied to various work or system tasks. The conventional solution of current data distribution is to acquire the required data by adopting methods such as special discussion and special data butt-joint development, report transfer, analysis and arrangement of original data, and the like, and a new work task package or a process is additionally added for solving the problem of a single point, so that the work is complex and repeated, and the data calling efficiency is low.

According to the invention, based on flexible connection and opening of the factory object position numbers of the data barriers of each stage of engineering project execution, factory operation, factory transformation retirement and the like, the engineering data service mode is redefined by the industrial Internet technical architecture, and the engineering data is ensured to be efficiently, conveniently and safely invoked in each stage of the whole life cycle of the factory.

Disclosure of Invention

Aiming at the defects in the prior art, the engineering attribute dynamic analysis and submission method based on the factory object position number solves the problems in the prior art.

In order to achieve the aim of the invention, the invention adopts the following technical scheme: a dynamic analysis and submission method of engineering properties based on a factory object position number comprises the following steps:

acquiring a first factory object position number and a first characteristic attribute corresponding to the first factory object position number, and constructing a factory exploded structure perspective view according to the first factory object position number, the first characteristic attribute corresponding to the first factory object position number and a factory exploded structure, wherein each first characteristic attribute in the factory exploded structure perspective view is provided with a corresponding first key value;

acquiring a call request corresponding to a first characteristic attribute transmitted by a target system, wherein the call request comprises at least one first key value corresponding to the first characteristic attribute, and the target system is used for representing an external system requesting to call the first characteristic attribute in a factory exploded structure perspective;

analyzing the first characteristic attribute in the stored factory exploded structure perspective based on the first key value corresponding to the first characteristic attribute in the factory exploded structure perspective and the first key value corresponding to the first characteristic attribute in the call request to obtain a factory exploded structure perspective analysis result with the first characteristic attribute, and submitting the factory exploded structure perspective analysis result with the first characteristic attribute to a target system to complete factory exploded structure perspective analysis and submission of the factory object with the first characteristic attribute.

In one possible implementation manner, the method includes obtaining a first factory object position number and a first feature attribute corresponding to the first factory object position number, and constructing a factory exploded structure perspective according to the first factory object position number and the first feature attribute corresponding to the first factory object position number, including:

acquiring a first factory object position number and first characteristic attributes corresponding to the first factory object position number, and obtaining factory exploded structure perspective view data, wherein each first factory object position number corresponds to at least one first characteristic attribute;

acquiring a factory exploded structure perspective template, wherein the factory exploded structure perspective template comprises a multi-hierarchy structure, second factory object position numbers corresponding to each hierarchy, position numbers corresponding to each second factory object position number and a plurality of second characteristic attributes corresponding to each second factory object position number; the second characteristic attribute comprises a second attribute name and a second attribute parameter;

extracting corresponding data from the factory exploded structure perspective data according to the factory exploded structure perspective template to generate a plurality of factory exploded structure perspective elements, wherein each factory exploded structure perspective element corresponds to one factory object;

a factory exploded structural perspective is obtained from a plurality of factory exploded structural perspective elements as well as a factory exploded structural perspective template that serves as a display layer, the factory exploded structural perspective elements serving as a data layer through which data support is provided for the display layer.

In one possible embodiment, extracting corresponding data from the factory exploded perspective data according to the factory exploded perspective template to generate a plurality of factory exploded perspective elements includes:

according to the position number of the second factory object corresponding to each level in the factory exploded structure perspective template, extracting second factory exploded perspective elements from the factory exploded structure perspective data to obtain a target factory object;

obtaining a target factory exploded structure perspective according to a plurality of first characteristic attributes corresponding to each first factory object position number and a plurality of second characteristic attributes corresponding to each second factory object position number in the factory exploded structure perspective template;

and taking each target factory object and the target characteristic attribute corresponding to the target factory object as factory exploded structure perspective elements.

In one possible embodiment, obtaining a factory exploded perspective from a plurality of factory exploded perspective elements and a factory exploded perspective template, comprises:

randomly distributing a first key value for each target feature attribute in the factory exploded structure perspective element, wherein the first key value corresponding to each target feature attribute is different;

packaging a plurality of target characteristic attributes corresponding to each target factory object and a unique first key value corresponding to each target characteristic attribute into a data block to obtain a data block corresponding to the target factory object;

and taking the factory exploded structure perspective template as a display layer, taking the data block corresponding to the target factory object as a data layer, and taking the data block corresponding to the target factory object as data corresponding to the second factory object position number in the factory exploded structure perspective template to obtain the factory exploded structure perspective.

In one possible implementation manner, the obtaining the call request corresponding to the first feature attribute transmitted by the target system includes:

receiving a call message transmitted by a target system;

analyzing the call message to obtain a call request corresponding to the first characteristic attribute, wherein the call request comprises a second factory object bit number corresponding to the data block, an attribute column value of the second factory object bit number and a second key value corresponding to the second characteristic attribute corresponding to the second factory object bit number.

In one possible implementation manner, the parsing of the first feature attribute in the stored factory exploded structure perspective based on the first key value corresponding to the first feature attribute in the factory exploded structure perspective and the second key value corresponding to the first feature attribute in the call request to obtain a feature attribute parsing result includes:

according to the second factory object position number in the call request, matching is carried out in the storage factory exploded structure perspective view, and the first factory object position number corresponding to the second factory object position number is determined; if the matching is empty, directly returning to the empty set;

judging whether the attribute column value corresponding to the second factory object position number is the same as the determined attribute column value of the first factory object position number, if so, carrying out attribute calling, otherwise, rejecting the calling requirement; the attribute column value is used for representing the attribute quantity of the factory object;

reading the data block corresponding to the determined first factory object bit number to obtain a target data block;

and acquiring a feature attribute analysis result according to a second key value corresponding to the second feature attribute in the call request and the target data block.

In one possible implementation manner, according to a second key value corresponding to a second feature attribute in the call request and the target data block, obtaining a feature attribute analysis result includes:

according to a second key value corresponding to a second characteristic attribute in the call request, matching a first key value in a target data block, and if the matching is successful, extracting a first characteristic attribute corresponding to the first key value to obtain an analysis result corresponding to the second key value, wherein the first characteristic attribute comprises a first attribute name and a first attribute parameter; if the matching is unsuccessful, setting the analysis result corresponding to the second key value as null;

and obtaining an analysis result corresponding to each second key value, and taking the analysis results corresponding to all the second key values as characteristic attribute analysis results.

In one possible implementation manner, before submitting the feature attribute analysis result to the target system, the method further includes:

and acquiring the MAC address and the IP address of the equipment corresponding to the call request, judging whether the MAC address and the IP address exist in an intranet address library, if so, determining that the network type of the call request sent by the target system is the intranet, otherwise, determining that the network type of the call request sent by the target system is the extranet.

In one possible implementation, submitting the feature attribute resolution result to a target system includes:

determining a network type of a call request sent by a target system, wherein the network type comprises an intranet or an extranet;

if the network type is intranet, directly submitting the characteristic attribute analysis result to a target system;

if the network type is the external network, encrypting the characteristic attribute analysis result to obtain encrypted data, and submitting the encrypted data to a target system.

In one possible implementation manner, after encrypting the feature attribute analysis result, obtaining encrypted data includes: and encrypting the characteristic attribute analysis result by adopting a public key of the equipment corresponding to the sending calling request to obtain encrypted data.

According to the engineering attribute dynamic analysis and submission method based on the plant object position number, which is provided by the invention, by endowing key values to the characteristic attributes of each plant object in the plant exploded structure perspective view, engineering data of the plant object can be submitted to a required system more flexibly, and a data structure suitable for scenes can be output only by simply describing service requirement rules, so that data requirements of various scenes can be flexibly met, and the data calling efficiency is improved; when the demand comes, only simple configuration is needed to get the target attribute group, and only the target attribute group is transferred, so that the safety of the data is effectively ensured.

Drawings

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

Fig. 1 is a flow chart of a dynamic analysis and submission method for engineering properties based on a factory object position number according to an embodiment of the present invention.

Specific embodiments thereof have been shown by way of example in the drawings and will herein be described in more detail. These drawings and the written description are not intended to limit the scope of the inventive concepts in any way, but to illustrate the concepts of the present application to those skilled in the art by reference to specific embodiments.

Description of the embodiments

The following description of the embodiments of the present invention is provided to facilitate understanding of the present invention by those skilled in the art, but it should be understood that the present invention is not limited to the scope of the embodiments, and all the inventions which make use of the inventive concept are protected by the spirit and scope of the present invention as defined and defined in the appended claims to those skilled in the art.

Embodiments of the present invention are described in detail below with reference to the accompanying drawings.

As shown in FIG. 1, a method for dynamically analyzing and submitting engineering properties based on a plant object position number comprises the following steps:

s11, acquiring a first factory object position number and a first characteristic attribute corresponding to the first factory object position number, and constructing a factory exploded structure perspective view according to the first factory object position number, the first characteristic attribute corresponding to the first factory object position number and the factory exploded structure, wherein each first characteristic attribute in the factory exploded structure perspective view is provided with a corresponding first key value.

The first factory object bit number and the first characteristic attribute corresponding to the first factory object bit number can be data which is stored in a database in advance, can be data transmitted by other equipment or data generated by man-machine interaction, and can construct a factory exploded structure perspective view based on the data, so that the factory exploded structure perspective view can serve as a basis for multi-dimensional attribute calling.

It should be noted that, the feature attribute described in this embodiment may represent a single attribute, or may represent a group of attributes, and may be adjusted according to practical applications.

S12, acquiring a call request corresponding to a first characteristic attribute transmitted by a target system, wherein the call request comprises at least one first key value corresponding to the first characteristic attribute, and the target system is used for representing an external system requesting to call the first characteristic attribute in the factory exploded structure perspective view.

S13, analyzing the first characteristic attribute in the stored factory exploded structure perspective based on the first key value corresponding to the first characteristic attribute in the factory exploded structure perspective and the first key value corresponding to the first characteristic attribute in the call request to obtain a factory exploded structure perspective analysis result with the first characteristic attribute, and submitting the factory exploded structure perspective analysis result with the first characteristic attribute to a target system to complete factory exploded structure perspective analysis and submission of the factory object with the first characteristic attribute.

In one possible implementation manner, the method includes obtaining a first factory object position number and a first feature attribute corresponding to the first factory object position number, and constructing a factory exploded structure perspective according to the first factory object position number and the first feature attribute corresponding to the first factory object position number, including:

and acquiring the first factory object position numbers and first characteristic attributes corresponding to the first factory object position numbers to obtain factory exploded structure perspective view data, wherein each first factory object position number corresponds to at least one first characteristic attribute.

Acquiring a factory exploded structure perspective template, wherein the factory exploded structure perspective template comprises a multi-hierarchy structure, second factory object position numbers corresponding to each hierarchy, position numbers corresponding to each second factory object position number and a plurality of second characteristic attributes corresponding to each second factory object position number; the second characteristic attribute comprises a second attribute name and a second attribute parameter, and the second attribute parameter is null, namely data to be stored.

And extracting corresponding data from the factory exploded structure perspective data according to the factory exploded structure perspective template to generate a plurality of factory exploded structure perspective elements, wherein each factory exploded structure perspective element corresponds to one factory object.

A factory exploded structural perspective is obtained from a plurality of factory exploded structural perspective elements as well as a factory exploded structural perspective template that serves as a display layer, the factory exploded structural perspective elements serving as a data layer through which data support is provided for the display layer.

In one possible embodiment, extracting corresponding data from the factory exploded perspective data according to the factory exploded perspective template to generate a plurality of factory exploded perspective elements includes:

and extracting the first factory object position number from the factory exploded structure perspective data according to the second factory object position number corresponding to each level in the factory exploded structure perspective template to obtain the target factory object.

And extracting a plurality of first characteristic attributes from the factory exploded structure perspective data according to a plurality of second characteristic attributes corresponding to each second factory object position number in the factory exploded structure perspective template to obtain target characteristic attributes.

And taking each target factory object and the target characteristic attribute corresponding to the target factory object as factory exploded structure perspective elements.

In one possible embodiment, obtaining a factory exploded perspective from a plurality of factory exploded perspective elements and a factory exploded perspective template, comprises:

and randomly distributing a first key value for each target feature attribute in the factory exploded structure perspective element, wherein the first key value corresponding to each target feature attribute is different.

And packaging the plurality of target characteristic attributes corresponding to each target plant object and the unique first key value corresponding to each target characteristic attribute into a data block to obtain the data block corresponding to the target plant object.

And taking the factory exploded structure perspective template as a display layer, taking the data block corresponding to the target factory object as a data layer, and taking the data block corresponding to the target factory object as data corresponding to the second factory object position number in the factory exploded structure perspective template to obtain the factory exploded structure perspective.

Alternatively, a key value allocation rule may be preset, and then a first key value may be allocated to the target feature attribute according to the key value allocation rule. By assigning a value to each target feature attribute, each target feature attribute can be called according to a unique key value, and returned by utilizing a universal data interface so as to adapt to various requirements and scenes, and the analysis and submission of engineering data of a factory object are realized.

In one possible implementation manner, the obtaining the call request corresponding to the first feature attribute transmitted by the target system includes:

and receiving the call message transmitted by the target system.

Analyzing the call message to obtain a call request corresponding to the first characteristic attribute, wherein the call request comprises a second factory object bit number corresponding to the data block, an attribute column value of the second factory object bit number and a second key value corresponding to the second characteristic attribute corresponding to the second factory object bit number.

The target data block can be quickly matched through the second factory object bit number and the attribute column value of the second factory object bit number, and then data pulling is carried out through the second key value corresponding to the second characteristic attribute, so that the pulling of the appointed data is realized.

In one possible implementation manner, the parsing of the first feature attribute in the stored factory exploded structure perspective based on the first key value corresponding to the first feature attribute in the factory exploded structure perspective and the second key value corresponding to the first feature attribute in the call request to obtain a feature attribute parsing result includes:

according to the second factory object position number in the call request, matching is carried out in the storage factory exploded structure perspective view, and the first factory object position number corresponding to the second factory object position number is determined; if the matching is empty, directly returning to the empty set;

judging whether the attribute column value corresponding to the second factory object position number is the same as the determined attribute column value of the first factory object position number, if so, carrying out attribute calling, otherwise, rejecting the calling requirement; the attribute column value is used for representing the attribute quantity of the factory object;

reading the data block corresponding to the determined first factory object bit number to obtain a target data block;

and acquiring a feature attribute analysis result according to a second key value corresponding to the second feature attribute in the call request and the target data block.

In one possible implementation manner, according to a second key value corresponding to a second feature attribute in the call request and the target data block, obtaining a feature attribute analysis result includes:

according to a second key value corresponding to a second characteristic attribute in the call request, matching a first key value in a target data block, and if the matching is successful, extracting a first characteristic attribute corresponding to the first key value to obtain an analysis result corresponding to the second key value, wherein the first characteristic attribute comprises a first attribute name and a first attribute parameter; if the matching is unsuccessful, setting the analysis result corresponding to the second key value as null;

and obtaining an analysis result corresponding to each second key value, and taking the analysis results corresponding to all the second key values as characteristic attribute analysis results.

In one possible implementation manner, before submitting the feature attribute analysis result to the target system, the method further includes:

and acquiring an MAC (Media Access Control ) address and an IP (Internet Protocol, internet protocol) address of the device corresponding to the call request, judging whether the MAC address and the IP address exist in an intranet address library, if so, determining that the network type of the target system for sending the call request is intranet, otherwise, determining that the network type of the target system for sending the call request is extranet. It should be noted that other conventional methods may be used to determine whether the device sending the call request is from an intranet or an extranet.

In one possible implementation, submitting the feature attribute resolution result to a target system includes:

determining a network type of a call request sent by a target system, wherein the network type comprises an intranet or an extranet;

if the network type is intranet, directly submitting the characteristic attribute analysis result to a target system;

if the network type is the external network, encrypting the characteristic attribute analysis result to obtain encrypted data, and submitting the encrypted data to a target system.

In one possible implementation manner, after encrypting the feature attribute analysis result, obtaining encrypted data includes: and encrypting the characteristic attribute analysis result by adopting a public key of the equipment corresponding to the sending calling request to obtain encrypted data.

Optionally, the embodiment provides a data encryption and transmission method, which may include: data requestor flow, and data holder flow.

The data requesting party flow comprises the following steps: first, a first encryption factor a1, a second encryption factor a2 and a third encryption factor a3 which are larger than a set threshold value are randomly determined, and according to the first encryption factor a1, the second encryption factor a2 and the third encryption factor a3, a comprehensive encryption factor n=a1×a2×a3 is obtained, and the euler function value of the comprehensive encryption factor n is.

And determining a third encryption factor e by taking the Euler function value as a limiting condition, wherein the limiting condition of the third encryption factor e is that gcd represents a function of returning the greatest common divisor of two or more integers.

According to the Euler function value and the third encryption factor e, obtaining a modulus inverse element d of the third encryption factor e under the Euler function value as follows: where mod represents the remainder function.

According to the third encryption factor e and the comprehensive encryption factor n, a public key is constructed as PK= { e, n }, and according to the first encryption factor a1, the second encryption factor a2, the third encryption factor a3, the modulo inversion element d and the comprehensive encryption factor n, a private key is constructed as SK= { a1, a2, a3, d, n }.

The public key PK is transmitted to the data holder and the private key SK is stored locally.

The data holder flow includes: dividing ciphertext to be encrypted into a plurality of groups to obtain a plurality of plaintext blocks; and converting each plaintext block m into a decimal number, wherein the converted decimal number is smaller than the comprehensive encryption factor n, encrypting the plaintext block m into ciphertext blocks, and finally, sequentially arranging all the ciphertext blocks and sending the ciphertext blocks to a data requester.

The data requester flow also includes: and decrypting the ciphertext c to obtain plaintext data by connecting the decrypted plaintext blocks according to the segmentation sequence.

The block chain can be introduced, and the public key and the encrypted data are transmitted through the block chain, so that the data can be effectively prevented from being tampered.

The invention discloses a dynamic analysis and submission method of engineering properties based on a factory object position number, which belongs to the field of data call in the metallurgical industry, and constructs a factory decomposition structure perspective view and flexibly configures an engineering position number property group by endowing key values to characteristic properties of each factory object position number in a factory decomposition structure, and more flexibly submits engineering data of a factory object to a required system, and can output a data structure suitable for scenes only by simple business requirement rule description, so that the data requirements of various scenes can be flexibly met; based on the attribute service requirement, the target attribute group is obtained through simple configuration, and only the target attribute group is transmitted, so that the safety of data is effectively ensured.

It should be noted that any method using the inventive concept should be within the scope of the present invention. Other embodiments of the invention will be apparent to those skilled in the art from consideration of the specification and practice of the invention disclosed herein. This invention is intended to cover any variations, uses, or adaptations of the invention following, in general, the principles of the invention and including such departures from the present disclosure as come within known or customary practice within the art to which the invention pertains.

It is to be understood that the invention is not limited to the precise arrangements and instrumentalities shown in the drawings, which have been described above, and that various modifications and changes may be effected without departing from the scope thereof. The scope of the invention is limited only by the appended claims.

Claims (10)

1. The dynamic analysis and submission method of engineering properties based on the position number of the factory object is characterized by comprising the following steps:

acquiring a first factory object position number and a first characteristic attribute corresponding to the first factory object position number, and constructing a factory exploded structure perspective view according to the first factory object position number, the first characteristic attribute corresponding to the first factory object position number and a factory exploded structure, wherein each first characteristic attribute in the factory exploded structure perspective view is provided with a corresponding first key value;

acquiring a call request corresponding to a first characteristic attribute transmitted by a target system, wherein the call request comprises at least one first key value corresponding to the first characteristic attribute, and the target system is used for representing an external system requesting to call the first characteristic attribute in a factory exploded structure perspective;

analyzing the first characteristic attribute in the stored factory exploded structure perspective based on the first key value corresponding to the first characteristic attribute in the factory exploded structure perspective and the first key value corresponding to the first characteristic attribute in the call request to obtain a factory exploded structure perspective analysis result with the first characteristic attribute, and submitting the factory exploded structure perspective analysis result with the first characteristic attribute to a target system to complete factory exploded structure perspective analysis and submission of the factory object with the first characteristic attribute.

2. The method for dynamically analyzing and submitting engineering properties based on plant objects according to claim 1, wherein obtaining a first plant object position number and a first characteristic property corresponding to the first plant object position number, and constructing a plant exploded structure perspective according to the first plant object position number and the first characteristic property corresponding to the first plant object position number, comprises:

acquiring a first factory object position number and first characteristic attributes corresponding to the first factory object position number, and obtaining factory exploded structure perspective view data, wherein each first factory object position number corresponds to at least one first characteristic attribute;

acquiring a factory exploded structure perspective template, wherein the factory exploded structure perspective template comprises a multi-hierarchy structure, second factory object position numbers corresponding to each hierarchy, position numbers corresponding to each second factory object position number and a plurality of second characteristic attributes corresponding to each second factory object position number; the second characteristic attribute comprises a second attribute name and a second attribute parameter;

extracting corresponding data from the factory exploded structure perspective data according to the factory exploded structure perspective template to generate a plurality of factory exploded structure perspective elements, wherein each factory exploded structure perspective element corresponds to one factory object;

a factory exploded structural perspective is obtained from a plurality of factory exploded structural perspective elements as well as a factory exploded structural perspective template that serves as a display layer, the factory exploded structural perspective elements serving as a data layer through which data support is provided for the display layer.

3. The method for dynamically resolving and rendering engineering properties based on plant objects according to claim 2, wherein extracting corresponding data from the plant exploded perspective data according to the plant exploded perspective template to generate a plurality of plant exploded perspective elements comprises:

according to the position number of the second factory object corresponding to each level in the factory exploded structure perspective template, extracting second factory exploded perspective elements from the factory exploded structure perspective data to obtain a target factory object;

obtaining a target factory exploded structure perspective according to a plurality of first characteristic attributes corresponding to each first factory object position number and a plurality of second characteristic attributes corresponding to each second factory object position number in the factory exploded structure perspective template;

and taking each target factory object and the target characteristic attribute corresponding to the target factory object as factory exploded structure perspective elements.

4. The method for dynamically resolving and rendering engineering properties based on plant objects according to claim 3, wherein the step of obtaining a plant exploded perspective view from a plurality of plant exploded perspective view elements and a plant exploded perspective view template comprises:

randomly distributing a first key value for each target feature attribute in the factory exploded structure perspective element, wherein the first key value corresponding to each target feature attribute is different;

packaging a plurality of target characteristic attributes corresponding to each target factory object and a unique first key value corresponding to each target characteristic attribute into a data block to obtain a data block corresponding to the target factory object;

and taking the factory exploded structure perspective template as a display layer, taking the data block corresponding to the target factory object as a data layer, and taking the data block corresponding to the target factory object as data corresponding to the second factory object position number in the factory exploded structure perspective template to obtain the factory exploded structure perspective.

5. The method for dynamically analyzing and submitting an engineering property based on a plant object according to claim 4, wherein obtaining a call request corresponding to a first feature property transmitted by a target system comprises:

receiving a call message transmitted by a target system;

analyzing the call message to obtain a call request corresponding to the first characteristic attribute, wherein the call request comprises a second factory object bit number corresponding to the data block, an attribute column value of the second factory object bit number and a second key value corresponding to the second characteristic attribute corresponding to the second factory object bit number.

6. The method for dynamically analyzing and submitting engineering properties based on plant objects according to claim 5, wherein analyzing the first feature properties in the stored plant exploded structure perspective based on the first key value corresponding to the first feature properties in the plant exploded structure perspective and the second key value corresponding to the first feature properties in the call request to obtain the feature property analysis result comprises:

according to the second factory object position number in the call request, matching is carried out in the stored factory exploded structure perspective, and the first factory object position number corresponding to the second factory object position number is determined; if the matching is empty, directly returning to the empty set;

judging whether the attribute column value corresponding to the second factory object position number is the same as the determined attribute column value of the first factory object position number, if so, carrying out attribute calling, otherwise, rejecting the calling requirement; the attribute column value is used for representing the attribute quantity of the factory object;

reading the data block corresponding to the determined first factory object bit number to obtain a target data block;

and acquiring a feature attribute analysis result according to a second key value corresponding to the second feature attribute in the call request and the target data block.

7. The method for dynamically analyzing and submitting an engineering attribute based on a plant object according to claim 6, wherein obtaining a feature attribute analysis result according to a second key value corresponding to a second feature attribute in the call request and the target data block includes:

according to a second key value corresponding to a second characteristic attribute in the call request, matching a first key value in a target data block, and if the matching is successful, extracting a first characteristic attribute corresponding to the first key value to obtain an analysis result corresponding to the second key value, wherein the first characteristic attribute comprises a first attribute name and a first attribute parameter; if the matching is unsuccessful, setting the analysis result corresponding to the second key value as null;

and obtaining an analysis result corresponding to each second key value, and taking the analysis results corresponding to all the second key values as characteristic attribute analysis results.

8. The method for dynamically resolving and submitting an engineering property based on a plant object according to claim 1, wherein before submitting the feature property resolving result to a target system, the method further comprises:

and acquiring the MAC address and the IP address of the equipment corresponding to the call request, judging whether the MAC address and the IP address exist in an intranet address library, if so, determining that the network type of the call request sent by the target system is the intranet, otherwise, determining that the network type of the call request sent by the target system is the extranet.

9. The method for dynamically resolving and submitting a plant object-based engineering property according to claim 8, wherein submitting the feature property resolving result to a target system comprises:

determining a network type of a call request sent by a target system, wherein the network type comprises an intranet or an extranet;

if the network type is intranet, directly submitting the characteristic attribute analysis result to a target system;

if the network type is the external network, encrypting the characteristic attribute analysis result to obtain encrypted data, and submitting the encrypted data to a target system.

10. The method for dynamically analyzing and submitting engineering properties based on plant objects according to claim 9, wherein encrypting the feature property analysis result to obtain encrypted data comprises: and encrypting the characteristic attribute analysis result by adopting a public key of the equipment corresponding to the sending calling request to obtain encrypted data.

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