CN113743893B - Intelligent cooperative processing system and method for whole life cycle of engineering project - Google Patents

Abstract

The application provides an intelligent cooperative processing system, method, electronic equipment and storage medium of engineering project life cycle, wherein the system comprises: the method comprises the steps of obtaining a screened target item through a screening module of the item, obtaining a first group of data information through a modularized combination model in a planning module, obtaining a second group of data information deeply designed according to a design investment, a standardized template and a calculation model in a design cost integration module, editing collaborative management implementation process data of the target item by a plurality of clients in a project collaborative management module, and finally obtaining project post-evaluation information based on a project post-evaluation module.

Description

Intelligent cooperative processing system and method for whole life cycle of engineering project

Technical Field

The application relates to the technical field of engineering project design management, in particular to an intelligent collaborative processing system, an intelligent collaborative processing method, electronic equipment and a storage medium for the whole life cycle of an engineering project.

Background

Under the new development concept, the intelligent development of the digital energy-enabled engineering project provides advanced and reliable power for innovation development. In the prior art, intelligent collaborative services of the project can not cover the whole life cycle and the whole elements of the project, and mainly focus on part of links or focus on a plurality of stages in the project process, and the data information and the evaluation utility of the evaluation after fusion are not found, so that the data of the whole project process can not be effectively managed.

Disclosure of Invention

The application provides an intelligent cooperative processing system, an intelligent cooperative processing method, electronic equipment and a storage medium for the whole life cycle of engineering projects.

The embodiment of the first aspect of the application provides an intelligent collaborative processing system for the whole life cycle of engineering projects, which comprises a project screening module, a planning module, a design cost integrated module, a project collaborative management module and a project post-evaluation module, wherein: the screening module of the project is used for calculating the income level of each project according to the calculation model and the investment calculation model of the income rate in the project; carrying out item screening by adopting auxiliary investment decision according to the income level of each item so as to obtain screened target items; the planning module is used for calling a corresponding basic module to process technical parameters of the target item according to the feature description of the target item so as to obtain a first group of data information; the design and cost integrated module is used for calculating the project cost according to the association relation between the design data and the cost information in the standardized template of the target project and the calculation model so as to obtain a second group of data information; the project collaborative management module is used for responding to maintenance instructions of a plurality of clients and editing a third group of data information corresponding to each client, wherein the third group of data information is collaborative management implementation process data of the target project; the post-project evaluation module is used for acquiring required evaluation data from a fourth group of data information according to preset evaluation indexes and calculation models, and processing the evaluation data by adopting the evaluation indexes and the calculation models to obtain post-project evaluation information, wherein the fourth group of data information is implementation process data of the screening module, the planning module, the design cost integrated module and the project collaborative management module.

In one embodiment of the present application, the design and cost integrated module includes: the receiving sub-module is used for receiving the design data and the cost information of the target project and compiling the design data and the cost information according to the association relation of the design data and the cost information to obtain a standardized template; wherein the cost information includes one or more of a combination of equipment, material price, and quota; the fund-extracting submodule is used for carrying out local modification according to the design data in the standardized template to finish fund extraction, and calculating project cost by combining price information in the standardized template and a calculation model to obtain a second group of data information; and the checking sub-module is used for checking the second group of data information according to preset quality information and checking and auditing models to obtain the deeply designed second group of data information.

In one embodiment of the present application, the design and cost integrated module further includes: and the comparison analysis calculation sub-module is used for analyzing and calculating the second group of data information through the data platform if the design data and the cost information are changed, so as to obtain a changed fifth group of data information, taking the data of the fifth group of data information as the data information after the target item is changed, and completing comparison analysis.

In one embodiment of the present application, the project collaborative management module includes an evaluation sub-module, wherein: and the evaluation submodule is used for evaluating each client through a scoring model of a plurality of clients in the project collaborative management after the project collaborative management is completed.

In one embodiment of the application, the post-project evaluation module comprises a feedback sub-module, wherein: the feedback sub-module is used for feeding back the fourth group of data information of the target item to each module of the item, analyzing reasons according to an evaluation model aiming at indexes with large deviation rate, and determining corresponding measure suggestions according to analysis results; wherein each module comprises: the system comprises a project screening module, a planning module, a design cost integrated module, a project collaborative management module and a project post-evaluation module.

The application provides an intelligent collaborative processing system for a project full life cycle, which is characterized in that a screening module of the project is utilized to obtain a screened target project, a planning module is utilized to obtain a first group of data information through a modularized combination model, a design cost integration module is utilized to obtain a second group of data information deeply designed according to a design investment, a standardized template and a calculation model, a plurality of clients can edit collaborative management implementation process data of the target project in the project collaborative management module, and finally, a post-project evaluation module is utilized to obtain post-project evaluation information, so that in the intelligent collaborative processing process of the project full life cycle, the intelligent collaborative processing of the project full life cycle can be automatically realized based on the intelligent design and management of the project full life cycle by each module of different project stages, thereby optimizing the service flow, improving the processing level, better playing the data utility and realizing the feedback and closed loop of the data.

The embodiment of the second aspect of the application provides an intelligent collaborative processing method for the whole life cycle of engineering projects, which comprises the following steps: acquiring a calculation model of the internal yield of the project and an investment calculation model, and calculating the yield level of each project; carrying out project screening by adopting auxiliary investment decision according to the income level of each project so as to obtain screened target projects; acquiring feature description of the target item, and calling a corresponding basic module to process technical parameters of the target item so as to obtain a first group of data information; acquiring the association relation between design data and cost information in a standardized template of the target project and a calculation model, and calculating the project cost to obtain a second group of data information; acquiring a third group of data information of the collaborative management implementation process of the target item, responding to maintenance instructions of a plurality of clients, and editing the third group of data information corresponding to each client; and acquiring required evaluation data from fourth group of data information according to a preset evaluation index and a calculation model, and processing the evaluation data by adopting the evaluation index and the calculation model to obtain post-engineering evaluation.

In one embodiment of the present application, obtaining the association between design data and cost information in the standardized template of the target item and a calculation model, calculating the cost of the item to obtain a second set of data information, includes: receiving design data and cost information of the target project, and compiling the design data and the cost information according to the association relation of the design data and the cost information to obtain a standardized template; wherein the cost information includes one or more of a combination of equipment, material price, and quota; carrying out local modification according to design data in the standardized template to finish the funding, and calculating project cost by combining price information and a calculation model in the standardized template to obtain a second group of data information; and checking the second group of data information according to preset quality information and checking and auditing models aiming at the second group of data information to obtain the deeply designed second group of data information.

In one embodiment of the present application, the method further includes obtaining an association between design data and cost information in a standardized template of the target item and a calculation model, calculating the cost of the item to obtain a second set of data information, and further including: and if the design data and the cost information are changed, analyzing and calculating the second group of data information through a data platform to obtain a changed fifth group of data information, taking the data of the fifth group of data information as the data information of the changed target item, and completing comparison analysis.

In one embodiment of the present application, a third set of data information of a collaborative management implementation process of the target item is obtained, and in response to maintenance instructions of a plurality of clients, editing operations are performed on the third set of data information corresponding to each client, and the method further includes: and obtaining scoring models of a plurality of clients in the collaborative management implementation process of the target item in the data platform so as to obtain the result of evaluating all the clients.

In one embodiment of the present application, after acquiring the data information of the screened target item implementation process, the first set of data information, the second set of data information, and the fourth set of data information formed by the third set of data information, and acquiring required evaluation data from the fourth set of data information according to a preset evaluation index and a calculation model, processing the evaluation data by using the evaluation index and the calculation model to obtain a post-engineering evaluation, the method further includes: acquiring a fourth group of data information of the target item, and feeding the fourth group of data information back to each stage of the target item; and receiving feedback results of each stage of the target project, analyzing reasons according to an evaluation model in the data platform aiming at indexes with large deviation rate, and providing measure suggestions, wherein each stage comprises all the processes of the intelligent collaborative processing method of the whole life cycle of the engineering project.

The application provides an intelligent collaborative processing method for a project full life cycle, which comprises the steps of obtaining a screened target project through a project screening module, obtaining a first group of data information through a modularized combination model in a planning module, obtaining a second group of data information deeply designed according to a design cost integration module, a design cost lifting, a standardized template and a calculation model, editing collaborative management implementation process data of the target project by a plurality of clients in a project collaborative management module, and finally obtaining post-project evaluation information based on a project post-evaluation module.

An embodiment of a third aspect of the present application provides an electronic device, including: the intelligent collaborative processing method comprises a memory, a processor and a computer program stored in the memory and capable of running on the processor, wherein the processor realizes the intelligent collaborative processing method of the whole life cycle of the engineering project in the embodiment of the application when executing the program.

An embodiment of the fourth aspect of the present application provides a computer readable storage medium having a computer program stored thereon, which when executed by a processor implements the intelligent collaborative processing method for a whole life cycle of an engineering project in an embodiment of the present application.

An embodiment of the fifth aspect of the present application proposes a computer program product, which when executed by an instruction processor in the computer program product implements the intelligent co-processing method of the whole life cycle of the engineering project in the embodiment of the present application.

Other effects of the above alternative will be described below in connection with specific embodiments.

Drawings

FIG. 1 is a schematic diagram of a project life cycle intelligent co-processing system according to one embodiment of the present application;

FIG. 2 is a schematic diagram of a life cycle intelligent co-processing system for engineering projects according to another embodiment of the present application;

FIG. 3 is a schematic flow chart of an intelligent collaborative processing method for a project life cycle according to an embodiment of the present application;

FIG. 4 is a system flow diagram of intelligent collaborative processing of a project life cycle provided by an embodiment of the present application;

FIG. 5 is a flow chart of another intelligent collaborative processing method for engineering project life cycle provided by an embodiment of the present application;

FIG. 6 is a diagram of the steps performed by the screening module for items according to an embodiment of the present application;

FIG. 7 is a diagram of steps for implementing a planning module according to an embodiment of the present application;

FIG. 8 is a diagram of the implementation steps of a design and cost integration module provided by an embodiment of the present application;

fig. 9 is a block diagram of an electronic device of one embodiment of the application.

Detailed Description

Embodiments of the present application are described in detail below, examples of which are illustrated in the accompanying drawings, wherein like or similar reference numerals refer to like or similar elements or elements having like or similar functions throughout. The embodiments described below by referring to the drawings are illustrative and intended to explain the present application and should not be construed as limiting the application.

The following describes an intelligent co-processing system, method and electronic equipment for the whole life cycle of engineering projects according to an embodiment of the application with reference to the accompanying drawings.

FIG. 1 is a schematic diagram of a project life cycle intelligent co-processing system in accordance with one embodiment of the present application.

As shown in fig. 1, the project full life cycle intelligent co-processing system 100 includes:

the project screening module 101 is used for calculating the income level of each project according to a calculation model and an investment calculation model of the income rate in the project; and (5) carrying out item screening by adopting auxiliary investment decisions according to the income level of each item so as to obtain screened target items.

And the planning module 102 is used for calling the corresponding basic module to process the technical parameters of the target item according to the feature description of the target item so as to obtain a first group of data information.

The design cost integration module 103 is configured to calculate the cost of the project according to the association relationship between the design data and the cost information in the standardized template of the target project and the calculation model, so as to obtain a second set of data information.

The project collaborative management module 104 is configured to respond to maintenance instructions of a plurality of clients, and edit a third set of data information corresponding to each client, where the third set of data information is collaborative management implementation process data of a target project.

A post-project evaluation module 105, configured to obtain required evaluation data from the fourth set of data information according to a preset evaluation index and a calculation model; and processing the evaluation data by adopting an evaluation index and a calculation model to obtain post-engineering evaluation information, wherein the fourth group of data information is implementation process data of a screening module, a planning module, a design cost integrated module and a project collaborative management module.

Any module in the project is independent, and any one or more modules in the project and other projects can be called to obtain corresponding results.

Wherein, the data information includes: the latest policy files and market information, comprehensive regulation specifications and industry standards, engineering technical schemes and cost indexes, historical engineering information (including design scheme description, cost information, financial analysis, post-evaluation data and the like), equipment prices (caliber including contract price, information price, market price, and the like), material prices (caliber including contract price, information price, market price, and the like), engineering quantity information accumulated in construction map budgeting and engineering settlement processes, and pricing basis, calculation model, quality information and the like applied in intelligent calculation and collaborative management service, but the embodiment is not limited to this.

In some embodiments, the system may be applied to a local area network, may be configured to support access by an internet terminal on the internet, and may also be applied to a client, but is not limited thereto.

The application provides an intelligent collaborative processing system for a project full life cycle, which is characterized in that a screening module of the project is used for obtaining a screened target project, a planning module is used for obtaining a first group of data information through a modularized combination model, a design cost integration module is used for obtaining a second group of data information deeply designed according to a design investment, a standardized template and a calculation model, a plurality of clients can edit collaborative management implementation process data of the target project in the project collaborative management module, and finally, a post-project evaluation module is used for obtaining post-project evaluation information, so that in the intelligent collaborative management process of the project full life cycle, intelligent collaborative design management of the project full life cycle can be automatically realized based on the intelligent collaborative design management of the project full life cycle of each module in different project stages, thereby optimizing a service flow, improving a processing level, better playing data utility and realizing data feedback and closed loop.

FIG. 2 is a schematic diagram of a life cycle intelligent co-processing system for engineering projects according to another embodiment of the present application.

As shown in fig. 2, the design cost integration module 103 includes: a receiving submodule 1031, a funding submodule 1032, and a checking submodule 1033.

The receiving submodule 1031 is used for receiving design data and cost information of a target project, and compiling the design data and the cost information according to the association relation of the design data and the cost information to obtain a standardized template; wherein the cost information includes one or more of a combination of equipment, material price, and quota.

And the fund-extracting sub-module 1032 is used for carrying out local modification according to the design data in the standardized template to finish fund extraction, and calculating the project cost by combining the price information in the standardized template and the calculation model to obtain a second group of data information.

And a checking sub-module 1033, configured to check the second set of data information according to preset quality information and checking models, so as to obtain the second set of data information that is deeply designed.

The price information may be all information related to price, but is not limited thereto, so as to complete the quotation of the target item.

As shown in fig. 2, the design and cost integrated module 103 further includes: a computation submodule 1034.

And the comparison analysis calculation sub-module 1034 is configured to analyze and calculate the second set of data information through the data platform to obtain a modified fifth set of data information if the design data and the cost information are modified, take the data of the fifth set of data information as the data information after the modification of the target item, and complete comparison analysis.

As shown in fig. 2, the project co-management module 104 includes an evaluation sub-module 1041.

The evaluation sub-module 1041 is configured to evaluate each client through a scoring model of a plurality of clients in the project collaborative management after the project collaborative management is completed.

As shown in FIG. 2, post-project evaluation module 105 includes a feedback sub-module 1051.

The feedback sub-module 1051 is configured to feed back a fourth set of data information of the target item forward to each module of the item, perform cause analysis according to the evaluation model for the index with a large deviation rate, and determine a corresponding measure suggestion according to the analysis result; wherein each module comprises: the system comprises a project screening module, a planning module, a design cost integrated module, a project collaborative management module and a project post-evaluation module.

The application provides an intelligent collaborative processing system for a project full life cycle, which is characterized in that a screening module of the project is utilized to obtain a screened target project, a planning module is utilized to obtain a first group of data information through a modularized combination model, a design cost integration module is utilized to obtain a second group of data information deeply designed according to a design investment, a standardized template and a calculation model, a plurality of clients can edit collaborative management implementation process data of the target project in the project collaborative management module, and finally, a post-project evaluation module is utilized to obtain post-project evaluation information, so that the intelligent collaborative processing for the project full life cycle can be automatically realized based on the intelligent collaborative design and management process of the project full life cycle of each module in different project stages, thereby optimizing the service flow, improving the processing level, better playing the data utility and realizing the feedback and closed loop of the data.

FIG. 3 is a flow chart of an intelligent collaborative processing method for a project life cycle according to an embodiment of the present application. It should be noted that, the execution main body of the intelligent collaborative processing method of the engineering project full life cycle provided in this embodiment is an intelligent collaborative processing system of the engineering project full life cycle, where the intelligent collaborative processing system of the engineering project full life cycle may be implemented by software and/or hardware, the intelligent collaborative processing system of the engineering project full life cycle in this embodiment may be configured in an electronic device, and the electronic device in this embodiment may include a server, a terminal device, etc., and this embodiment does not specifically limit the electronic device.

FIG. 3 is a flow chart of an intelligent collaborative processing method for a project life cycle according to an embodiment of the present application.

Step 301, obtaining a calculation model and an investment calculation model of the internal yield of the project, and calculating the yield level of each project; and carrying out project screening by adopting auxiliary investment decision according to the income level of each project so as to obtain screened target projects.

In some embodiments, the calculation model and the investment calculation model are preset and stored in the system, the calculation model of the yield in the system is called to calculate all the projects so as to obtain the yield level of each project, and the calculation model and the investment decision model are combined to carry out auxiliary screening on each project according to the yield level of each project so as to obtain the target project meeting the expected requirement.

Step 302, obtaining a feature description of the target item, and calling a corresponding basic module to process technical parameters of the target item so as to obtain a first group of data information.

In some embodiments, under the condition that the project budget and calculation regulation, quota and other regulation specifications of various project types are met, the target project calls a basic module according to the feature description and the technical parameters, and a stored combined calculation model and other cost automatic calculation models are preset in the system to realize the first quotation of the target project so as to obtain a first group of data information.

Step 303, obtaining the association relation between the design data and the cost information in the standardized template of the target project and a calculation model, and calculating the project cost to obtain a second set of data information.

In some embodiments, design data and cost information of a target project are obtained, and are compiled according to association relation between the design data and the cost information, so that a standardized template is obtained, after the design data in the standardized template is obtained by a related design department, the design data is locally modified to finish the investment, price information and a calculation model in the standardized template are combined, the project cost is calculated to obtain a second quotation, and finally, the second quotation is checked according to preset quality information and checking and auditing models in the system to obtain an optimized second group of data information.

In still other embodiments, after completing the second price quotation for the target item to obtain the optimized second set of data information, if the design data and the cost information are changed, re-analyzing and calculating the second price quotation by the data platform to obtain a changed fifth set of data information, taking the data of the fifth set of data information as the changed data information of the target item, and completing the comparison analysis.

In some embodiments, the design data for the target item may be part of a selection from a bill of materials of the device, but is not limited thereto.

Step 304, obtaining a third group of data information in the collaborative management implementation process of the target item, and responding to maintenance instructions of a plurality of clients to edit the third group of data information corresponding to each client.

In some embodiments, after obtaining the optimized second set of data information, the system may receive maintenance instructions of the data information in the data platform by the plurality of clients, and edit the data information corresponding to each of the plurality of clients, so as to implement collaborative office of the plurality of clients, where it may be understood that different clients may receive different instructions, for example, clients that receive purchase instructions, audit instructions, and receive different instructions and perform different editing operations.

After the multiparty clients realize collaborative office, scoring models of a plurality of clients in the implementation process of collaborative management of target projects in a data platform are obtained, and each client is evaluated to obtain the evaluation result of all the clients in the implementation process of the projects.

Step 305, obtaining a fourth set of data information consisting of the process data information, the first set of data information, the second set of data information and the third set of data information of the screened target item, obtaining required evaluation data from the fourth set of data information according to a preset evaluation index and a preset calculation model, and processing the evaluation data by adopting the evaluation index and the calculation model to obtain post-engineering evaluation.

In some embodiments, the pre-set evaluation index is some related parameter combined by the profession of technology, cost, environmental protection, etc., but is not limited thereto.

In some embodiments, the required relevant evaluation data is obtained from the target project, which may include equipment price (caliber includes contract price, information price, market price, etc.), material price (caliber includes contract price, information price, market price, etc.), etc., but not limited to this, the evaluation data is processed in combination with the evaluation index and the calculation model in the system, so as to obtain post-evaluation information of the target project.

In other embodiments, after post-evaluation information of the project of the target project is obtained, a fourth set of data information is fed back to each stage of the target project, feedback results of each stage of the target project are received, and for the index with a large deviation rate, according to an evaluation model in the data platform, reasons are analyzed and measures are proposed, wherein each stage comprises all processes of the intelligent collaborative processing method of the whole life cycle of the project.

The application provides an intelligent collaborative processing method for a project life cycle, which is characterized in that the profit level of each project is calculated by acquiring a calculation model of the internal profit rate of the project, the investment calculation model is adopted to carry out auxiliary project screening according to the profit level of each project, so as to obtain a screened target project, then the characteristic description of the target project is acquired, a corresponding basic module is called to process the technical parameters of the target project, so as to obtain a first group of data information, the project cost is calculated according to the association relation between design data and cost information in a standardized template of the target project and the calculation model, so as to obtain a second group of data information, the third group of data information of a collaborative management implementation process of the target project is continuously required to be acquired, the maintenance instructions of a plurality of clients are responded, finally the required evaluation data is acquired from the fourth group of data information according to a preset evaluation index and calculation model, and the evaluation data is processed by adopting the evaluation index and the calculation model, so that the intelligent collaborative design and management of the project life cycle can be realized, the intelligent collaborative management of the project life cycle can be better realized, and the service cycle can be better realized, and the intelligent collaborative management life cycle can be better realized.

In some embodiments, as shown in fig. 4, in combination with any stage of the whole process of the engineering project, the system realizes intelligent collaborative processing of the whole process of the engineering project by providing services such as comprehensive data information, perfect standard system, innovative whole process evaluation, intelligent computing, collaborative management and the like, namely, rapid screening and calculation are performed according to an internal yield computing model in a project screening stage, modular combined quotation is completed according to a technical scheme and cost indexes in a planning stage, and a design cost integrated function optimization business process is realized in a feasibility research and preliminary design stage, and meanwhile, the functions of project collaborative management, post-engineering evaluation, whole process flow of data information, multi-party users are served, and a data closed loop is realized.

FIG. 5 is a flow chart of another intelligent collaborative processing method for a project life cycle according to an embodiment of the present application.

Step 501, obtaining a calculation model and an investment calculation model of the internal yield of the project, and calculating the yield level of each project; and carrying out project screening by adopting auxiliary investment decision according to the income level of each project so as to obtain screened target projects.

In some embodiments, as shown in FIG. 6, one implementation of obtaining the profit level of the project is to input the basic parameters of the project into a calculation model of the internal profit rate, and calculate the internal profit of the project to obtain the profit level of the project.

Step 502, obtaining a feature description of a target item, and calling a corresponding basic module to process technical parameters of the target item so as to obtain a first group of data information.

In some embodiments, as shown in fig. 7, the feature description of the target item is obtained, and the corresponding basic module is invoked to process the technical parameters of the target item, so as to obtain a first set of data information, that is, the first set of data information of the target item, namely, the item design and the cost, is output by the system by inputting the feature description of the target item to the system, then matching the basic module conforming to the basic parameters, and simultaneously obtaining the first quote of the target item by using the combined calculation model, the other cost calculation model and the summarized cost.

Step 503, receiving design data and cost information of the target project, and compiling the design data and the cost information according to the association relation of the design data and the cost information to obtain a standardized template; wherein the cost information includes one or more of a combination of equipment, material price, and quota.

Step 504, according to the design data in the standardized template, local modification is performed to complete the funding, and the price information and the calculation model in the standardized template are combined to calculate the project cost so as to obtain a second set of data information.

And 505, checking the second group of data information according to preset quality information and checking and auditing models to obtain the deeply designed second group of data information.

In some embodiments, as shown in fig. 8, the design data is a part of a bill of materials of the device, the design data conforming to the project is selected from the bill of materials of the device, and is compiled by combining the association relation between the design data and the cost information to obtain a standardized template, and is locally modified to complete the investment, then the system calculates other fees and summarized fees by using a preset calculation model, and the system checks and examines the investment differences according to preset quality information and check and audit models to obtain a second quotation, so as to obtain an optimized second set of data information, and the system outputs the difference and check opinion of the first quotation in the second quotation, wherein the quotation difference is also called the investment difference.

Step 506, obtaining a third group of data information of the collaborative management implementation process of the target item, and responding to the maintenance instructions of the plurality of clients to edit the third group of data information corresponding to each client.

Step 507, obtaining a fourth set of data information consisting of the process data information, the first set of data information, the second set of data information and the third set of data information of the screened target item, obtaining required evaluation data from the fourth set of data information according to a preset evaluation index and a preset calculation model, and processing the evaluation data by adopting the evaluation index and the calculation model to obtain post-engineering evaluation.

It should be noted that, regarding the specific implementation manner of steps 506 to 507, reference may be made to the related description in the above embodiments.

The application provides an intelligent collaborative processing method of a project life cycle, which comprises the steps of calculating the income level of each project by acquiring a calculation model of the income rate inside the project, adopting an investment measuring and calculating model to carry out auxiliary project screening according to the income level of each project to obtain a screened target project, then acquiring the characteristic description of the target project, calling a corresponding basic module to process the technical parameters of the target project to obtain a first group of data information, then receiving design information and cost information of the target project, programming the design information according to the association relation between the design information and the cost information, obtaining a standardized template, carrying out local modification according to the design information to finish the resource lifting, combining price information and the calculation model in the standardized template, calculating the cost of the project, obtaining a second group of data information, continuously needing to obtain a third group of data information of a collaborative management implementation process of the target project, responding to a plurality of maintenance instructions of clients, finally carrying out editing operation on the third group of data information corresponding to each client, carrying out the intelligent project life cycle based on the preset evaluation index and the calculation model, carrying out the full-scale on the project life cycle, and realizing the full-cycle of the intelligent project life cycle based on the full-time evaluation of the intelligent project.

Fig. 9 is a block diagram of an electronic device of one embodiment of the application.

As shown in fig. 9, the electronic device includes:

memory 901, processor 902, and computer instructions stored on memory 901 and executable on processor 902.

The processor 902, when executing instructions, implements the intelligent co-processing method for the whole life cycle of the engineering project provided in the above embodiments.

Further, the electronic device further includes:

a communication interface 903 for communication between the memory 901 and the processor 902.

Memory 901 for storing computer instructions executable on processor 902.

Memory 901 may comprise high-speed RAM memory or may also include non-volatile memory (non-volatile memory), such as at least one disk memory.

The processor 902 is configured to implement the intelligent collaborative processing method for the whole life cycle of the engineering project according to the above embodiment when executing the program.

If the memory 901, the processor 902, and the communication interface 903 are implemented independently, the communication interface 903, the memory 901, and the processor 902 may be connected to each other through a bus and perform communication with each other. The bus may be an industry standard architecture (Industry Standard Architecture, abbreviated ISA) bus, an external device interconnect (Peripheral Component, abbreviated PCI) bus, or an extended industry standard architecture (Extended Industry Standard Architecture, abbreviated EISA) bus, among others. The buses may be divided into address buses, data buses, control buses, etc. For ease of illustration, only one thick line is shown in fig. 9, but not only one bus or one type of bus.

Alternatively, in a specific implementation, if the memory 901, the processor 902, and the communication interface 903 are integrated on a chip, the memory 901, the processor 902, and the communication interface 903 may communicate with each other through internal interfaces.

The processor 902 may be a central processing unit (Central Processing Unit, abbreviated as CPU) or an application specific integrated circuit (Application Specific Integrated Circuit, abbreviated as ASIC) or one or more integrated circuits configured to implement embodiments of the present application.

Furthermore, the terms "first," "second," and the like, are used for descriptive purposes only and are not to be construed as indicating or implying a relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defining "a first" or "a second" may explicitly or implicitly include at least one such feature. In the description of the present application, the meaning of "plurality" means at least two, for example, two, three, etc., unless specifically defined otherwise.

In the description of the present specification, a description referring to terms "one embodiment," "some embodiments," "examples," "specific examples," or "some examples," etc., means that a particular feature, structure, material, or characteristic described in connection with the embodiment or example is included in at least one embodiment or example of the present application. In this specification, schematic representations of the above terms are not necessarily directed to the same embodiment or example. Furthermore, the particular features, structures, materials, or characteristics described may be combined in any suitable manner in any one or more embodiments or examples. Furthermore, the different embodiments or examples described in this specification and the features of the different embodiments or examples may be combined and combined by those skilled in the art without contradiction.

While embodiments of the present application have been shown and described above, it will be understood that the above embodiments are illustrative and not to be construed as limiting the application, and that variations, modifications, alternatives and variations may be made to the above embodiments by one of ordinary skill in the art within the scope of the application.

Claims (12)

1. The intelligent cooperative processing system for the project whole life cycle is characterized by comprising a project screening module, a planning module, a design and cost integrated module, a project cooperative management module and a project post-evaluation module, wherein:

the screening module of the project is used for calculating the income level of each project according to the calculation model and the investment calculation model of the income rate in the project; carrying out item screening by adopting auxiliary investment decision according to the income level of each item so as to obtain screened target items;

the planning module is used for calling a corresponding basic module to process technical parameters of the target item according to the feature description of the target item so as to obtain a first group of data information;

the design and cost integrated module is used for calculating the project cost according to the association relation between the design data and the cost information in the standardized template of the target project and the calculation model so as to obtain a second group of data information;

The project collaborative management module is used for responding to maintenance instructions of a plurality of clients and editing a third group of data information corresponding to each client, wherein the third group of data information is collaborative management implementation process data of the target project;

the post-project evaluation module is used for acquiring required evaluation data from the fourth group of data information according to preset evaluation indexes and a calculation model; processing the evaluation data by adopting the evaluation index and the calculation model to obtain post-engineering evaluation information, wherein the fourth group of data information is implementation process data of a screening module, a planning module, a design cost integrated module and a project collaborative management module;

the planning module is specifically configured to match a basic module according with basic parameters through feature description of a target item, and obtain a first quote of the target item by using a combined calculation model, other cost calculation models and summarized cost, so as to output a first set of data information of the target item.

2. The intelligent co-processing system for a project life cycle of claim 1, wherein the design cost integration module comprises:

The receiving sub-module is used for receiving the design data and the cost information of the target project and compiling the design data and the cost information according to the association relation of the design data and the cost information to obtain a standardized template; wherein the cost information includes one or more of a combination of equipment, material price, and quota;

the fund-extracting submodule is used for carrying out local modification according to the design data in the standardized template to finish fund extraction, and calculating project cost by combining price information in the standardized template and a calculation model to obtain a second group of data information;

and the checking sub-module is used for checking the second group of data information according to preset quality information and checking and auditing models to obtain the deeply designed second group of data information.

3. The engineering project life cycle intelligent co-processing system of claim 2, wherein the design cost integration module further comprises:

and the comparison analysis calculation sub-module is used for analyzing and calculating the second group of data information through the data platform if the design data and the cost information are changed, so as to obtain a changed fifth group of data information, taking the data of the fifth group of data information as the data information of the changed target item, and completing comparison analysis.

4. The intelligent collaborative processing system of an engineering project life cycle of claim 1, wherein the project collaborative management module comprises an evaluation sub-module, wherein:

and the evaluation submodule is used for evaluating each client through a scoring model of a plurality of clients in the project collaborative management after the project collaborative management is completed.

5. The intelligent collaborative processing system of a project lifecycle of claim 1, wherein the post-project evaluation module comprises a feedback sub-module, wherein:

the feedback sub-module is used for feeding back the fourth group of data information of the target item to each module of the item, analyzing reasons according to an evaluation model aiming at indexes with large deviation rate, and determining corresponding measure suggestions according to analysis results; wherein each module comprises: the system comprises a project screening module, a planning module, a design cost integrated module, a project collaborative management module and a project post-evaluation module.

6. An intelligent collaborative processing method for a whole life cycle of an engineering project is characterized by comprising the following steps:

acquiring a calculation model of the internal yield of the project and an investment calculation model, and calculating the yield level of each project; carrying out project screening by adopting auxiliary investment decision according to the income level of each project so as to obtain screened target projects;

Acquiring feature description of the target item, and calling a corresponding basic module to process technical parameters of the target item so as to obtain a first group of data information;

acquiring the association relation between design data and cost information in a standardized template of the target project and a calculation model, and calculating the project cost to obtain a second group of data information;

acquiring a third group of data information of the collaborative management implementation process of the target item, responding to maintenance instructions of a plurality of clients, and editing the third group of data information corresponding to each client;

the process data information, the first group of data information, the second group of data information and the third group of data information of the screened target item form fourth group of data information, required evaluation data are obtained from the fourth group of data information according to preset evaluation indexes and a calculation model, and the evaluation data are processed by adopting the evaluation indexes and the calculation model to obtain post-engineering evaluation;

the obtaining the feature description of the target item, calling a corresponding basic module to process the technical parameters of the target item to obtain a first group of data information, including: and matching basic modules conforming to basic parameters through the feature description of the target item, and obtaining a first quotation of the target item by utilizing the combined calculation model, other cost calculation models and the summarized cost, thereby outputting a first group of data information of the target item.

7. The intelligent collaborative processing method for a complete life cycle of an engineering project according to claim 6, wherein obtaining an association of design data and cost information in a standardized template of the target project and a calculation model, calculating the project cost to obtain a second set of data information, comprises:

receiving design data and cost information of the target project, and compiling the design data and the cost information according to the association relation of the design data and the cost information to obtain a standardized template; wherein the cost information includes one or more of a combination of equipment, material price, and quota;

carrying out local modification according to design data in the standardized template to finish the funding, and calculating project cost by combining price information and a calculation model in the standardized template to obtain a second group of data information;

and checking the second group of data information according to preset quality information and checking and auditing models aiming at the second group of data information to obtain the deeply designed second group of data information.

8. The intelligent collaborative processing method for a complete life cycle of an engineering project according to claim 7, wherein obtaining an association between design data and cost information in a standardized template of the target project and a calculation model, calculating the project cost to obtain a second set of data information, further comprises:

And if the design data and the cost information are changed, analyzing and calculating the second group of data information through a data platform to obtain a changed fifth group of data information, taking the data of the fifth group of data information as the data information of the changed target item, and completing comparison analysis.

9. The intelligent collaborative processing method according to claim 6, wherein a third set of data information of a collaborative management implementation process of the target project is obtained, and in response to maintenance instructions of a plurality of clients, editing operations are performed on the third set of data information corresponding to each client, and further comprising:

and obtaining scoring models of a plurality of clients in the collaborative management implementation process of the target item in the data platform so as to obtain the result of evaluating all the clients.

10. The intelligent collaborative processing method according to claim 6, wherein after obtaining a fourth set of data information comprising the data information of the filtered implementation process of the target project, the first set of data information, the second set of data information, and the third set of data information, and obtaining required evaluation data from the fourth set of data information according to a preset evaluation index and a calculation model, processing the evaluation data by using the evaluation index and the calculation model to obtain a post-engineering evaluation, further comprising:

Acquiring a fourth group of data information of the target item, and feeding the fourth group of data information back to each stage of the target item;

and receiving feedback results of each stage of the target project, analyzing reasons according to an evaluation model in the data platform aiming at indexes with large deviation rate, and providing measure suggestions, wherein each stage comprises all the processes of the intelligent collaborative processing method of the whole life cycle of the engineering project.

11. An electronic device, comprising:

a memory, a processor and a computer program stored on the memory and executable on the processor, wherein the processor implements the intelligent co-processing method of the engineering project life cycle according to any one of claims 6-10 when executing the program.

12. A computer readable storage medium having stored thereon a computer program, which when executed by a processor implements the intelligent co-processing method of the engineering project life cycle of any one of claims 6-10.