CN112837105A - BIM-based whole-process engineering cost management method and system and electronic equipment - Google Patents

Abstract

The application relates to the technical field of engineering cost management, in particular to a BIM-based overall process engineering cost management method, system and electronic equipment, which comprises the steps of acquiring total data information of each stage in the overall process of engineering; extracting key point information of each stage in the whole engineering process based on the total data information; constructing a BIM (building information modeling) model according to key point information of each stage in the whole engineering process; monitoring the whole engineering process based on a BIM model, predicting tasks of all stages in the whole engineering process in real time, and generating prediction information of all stages; comparing the prediction information with a preset target, and judging whether the prediction information has a bad state or not; and if the bad state exists, generating corresponding prompt information. The application has the effect of improving the supervision efficiency.

Description

BIM-based whole-process engineering cost management method and system and electronic equipment

Technical Field

The application relates to the technical field of project cost management, in particular to a BIM-based overall process project cost management method, system and electronic equipment.

Background

The investment project supervision has the characteristics of complex project, huge supervision points, high information acquisition requirement and the like, if the extraction of target supervision key nodes is respectively carried out in the whole process of the project construction, the collection process is disordered due to time control difference, information isolation and the like, and a standardized information model is required to be established to realize real-time and dynamic management.

In the related technology, a manager supervises the whole process of a project through a whole-process project cost management system, and after a bad management running state is found, the manager immediately informs related responsible persons so as to make adjustment.

In view of the above-mentioned related art, the inventor believes that it takes a long time for a manager to perform a process from finding a problem to notifying a relevant person in charge, which causes a drawback of low supervision efficiency.

Disclosure of Invention

In order to improve the supervision efficiency, the application provides a BIM-based overall process engineering cost management method, a system and electronic equipment.

In a first aspect, the application provides a BIM-based overall process engineering cost management method, which adopts the following technical scheme:

the BIM-based whole process engineering cost management method comprises the following steps:

acquiring total data information of each stage in the whole engineering process;

extracting key point information of each stage in the whole engineering process based on the total data information;

constructing a BIM (building information modeling) model according to key point information of each stage in the whole engineering process;

monitoring the whole engineering process based on a BIM model, predicting tasks of all stages in the whole engineering process in real time, and generating prediction information of all stages;

comparing the prediction information with a preset target, and judging whether the prediction information has a bad state or not;

and if the bad state exists, generating corresponding prompt information.

By adopting the technical scheme, the BIM model constructed according to the key point information is beneficial to a manager to supervise each stage of the project, the prediction information generated automatically is convenient for rapidly judging whether the bad state exists, the corresponding prompt information is generated, and the prompt information is beneficial to the manager to find problems, so that the time for the manager to find the problems is shortened, the manager is also beneficial to directly sending the prompt information to relevant responsible persons, and the supervision efficiency is improved.

Optionally, after generating the corresponding prompt information if the bad status exists, the method further includes:

sending prompt information to a mobile terminal or a computer terminal of a relevant responsible person;

and issuing prompt information to the sharing platform.

By adopting the technical scheme, the time for informing the relevant responsible persons is shortened by the mode of automatically sending the prompt information and the mode of automatically issuing the prompt information, and the supervision efficiency is improved.

Optionally, after sending the prompt message to the mobile terminal or the computer terminal of the relevant responsible person, the method further includes:

receiving feedback information from a mobile terminal or a computer terminal of a related responsible person;

judging whether the related responsible person refers to the prompt information manually or not according to the feedback information;

if not, the prompt message is sent to the mobile terminal or the computer terminal of the relevant responsible person again.

By adopting the technical scheme, the feedback information is beneficial to judging whether the related responsible person artificially refers to the prompt information or not, the effect of ensuring that the related responsible person can see the prompt information is achieved by means of reissuing the prompt information, and the condition that the related responsible person misses the prompt information due to mistaken touch of the touch screen is reduced.

Optionally, the comparing the prediction information with a preset target, and determining whether the prediction information has a bad state includes:

reading the prediction information to obtain progress prediction data, expense prediction data, quality prediction data and safety prediction data;

comparing the progress prediction data, the expense prediction data, the quality prediction data and the safety prediction data with corresponding preset targets respectively;

if the difference value is greater than 10%, the state is determined to be bad.

By adopting the technical scheme, the progress prediction data, the expense prediction data, the quality prediction data and the safety prediction data are compared separately, so that whether a bad state exists or not can be judged accurately.

Optionally, if the notification message is not sent again to the mobile terminal or the computer of the relevant responsible person, the method further includes:

if the relevant responsible person is to look up the prompt information manually, obtaining problem information according to the prompt information and the corresponding prediction information;

obtaining processing scheme information associated with the issue information;

and sending the processing scheme information to a mobile terminal or a computer terminal of a related responsible person.

By adopting the technical scheme, the processing scheme information is automatically acquired after the problem information is obtained, and the effect of quickly sending the processing scheme information to the mobile terminal or the computer terminal of the relevant responsible person is achieved, so that the relevant responsible person can conveniently and properly adjust the project.

Optionally, the obtaining of the processing scheme information related to the problem information includes:

matching a corresponding processing scheme in a preset processing scheme database according to the problem information, and forming processing scheme information if the matching is successful;

and if the matching fails, acquiring the processing scheme information manually input by the manager.

By adopting the technical scheme, the preset processing scheme database is favorable for quickly matching the processing scheme information about the problem information, and a manager can also manually input the processing scheme information, so that better and faster supervision engineering is facilitated.

Optionally, after the building of the BIM model according to the key point information of each stage in the whole engineering process, the method further includes:

extracting document position information of all documents based on the total data information;

and linking the document position information with the BIM model.

By adopting the technical scheme, a manager can directly utilize the BIM to quickly search and position the document, thereby improving the efficiency.

In a second aspect, the present application provides a BIM-based overall process engineering cost management system, which adopts the following technical scheme:

BIM-based overall process engineering cost management system comprises:

the acquisition module is used for acquiring total data information of each stage in the whole engineering process;

the extraction module is used for extracting key point information of each stage in the whole engineering process based on the total data information;

the building module is used for building a BIM (building information modeling) model according to the key point information of each stage in the whole engineering process;

the prediction module is used for monitoring the whole engineering process based on the BIM model, predicting tasks of all stages in the whole engineering process in real time and generating prediction information of all stages;

the judging module is used for comparing the prediction information with a preset target and judging whether the prediction information has a bad state or not;

and the generating module is used for generating corresponding prompt information if the bad state exists.

By adopting the technical scheme, the extraction module can extract key point information based on the total data information obtained by the acquisition module, so that the BIM model constructed by the construction module is more accurate, the prediction module generates accurate prediction information, and after the judgment module judges that a bad state exists, the generation module generates prompt information, so that the prompt information is obtained more accurately.

In a third aspect, the present application provides an electronic device, which adopts the following technical solutions:

an electronic device comprising a memory and a processor, said memory having stored thereon a computer program capable of being loaded by the processor and executing any of the BIM based total project cost management methods described above.

By adopting the technical scheme, the method and the system are beneficial to supervision of each stage of the project by a manager, are convenient for rapidly judging whether bad states exist, and are also beneficial to finding problems by the manager, so that the time for finding the problems by the manager is shortened, and the manager is also beneficial to directly sending the prompt information to related responsible persons, thereby improving the supervision efficiency.

In a fourth aspect, the present application provides a computer-readable storage medium, which adopts the following technical solutions:

a computer readable storage medium storing a computer program capable of being loaded by a processor and executing any of the BIM based total project cost management methods described above.

By adopting the technical scheme, the method and the system are beneficial to supervision of each stage of the project by the manager, so that the time for the manager to find the problem is shortened, the manager is also beneficial to directly sending the prompt information to the relevant responsible person, and the supervision efficiency is improved.

In summary, the present application includes at least one of the following beneficial technical effects:

1. the BIM model constructed according to the key point information is beneficial for a manager to supervise each stage of the project, the prediction information generated automatically is convenient for rapidly judging whether the bad state exists or not, and the corresponding prompt information is generated, and the prompt information is beneficial for the manager to find the problem, so that the time for the manager to find the problem is shortened, the manager is also beneficial for the manager to directly send the prompt information to the relevant responsible person, and the supervision efficiency is improved.

2. The feedback information is beneficial to judging whether the related responsible person refers to the prompt information manually or not, the effect of ensuring that the related responsible person can see the prompt information is achieved by means of reissuing the prompt information, and the situation that the related responsible person misses the prompt information due to mistaken touch of the touch screen is reduced.

3. The extraction module can extract key point information based on the total data information obtained by the acquisition module, so that the BIM model constructed by the construction module is more accurate, the prediction module generates accurate prediction information, and after the prediction module judges that a bad state exists, the generation module generates prompt information, so that the prompt information is obtained more accurately.

Drawings

FIG. 1 is a flow chart of a BIM-based method for managing construction costs of a whole process project according to an embodiment of the present application.

FIG. 2 is a flow chart of a BIM-based overall process project cost management method according to another embodiment of the present application.

FIG. 3 is a flow chart of another BIM-based overall process project cost management method according to an embodiment of the present application.

FIG. 4 is a block diagram of a BIM-based overall process construction cost management system according to the present application.

Fig. 5 is a schematic structural diagram of an electronic device in the present application.

Detailed Description

The present application is described in further detail below with reference to figures 1-5.

In order to make the objects, technical solutions and advantages of the present application more apparent, the present application is further described in detail below with reference to fig. 1-5 and the embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the present application and are not intended to limit the present application.

The BIM-based overall process engineering cost management method provided by the embodiment of the application can be executed by a BIM-based overall process engineering cost management system, and the BIM-based overall process engineering cost management system comprises a memory and a processor. The memory stores BIM software, which may be, but is not limited to, revit software. Also stored in the memory is a computer program executable by the processor for implementing a BIM based overall process engineering cost management method.

Generally, the engineering investment work center of gravity shifts to the establishment of an investment plan and the supervision of the use condition of investment funds, but the mechanism is simplified, the working pressure is high, the management force is insufficient, the working efficiency is difficult to guarantee, the risk of out-of-control investment is high, and the fund management should become one of the core contents of monitoring. The supervision of investment engineering relates to a plurality of departments, and effective supervision is difficult to realize, so that a collaborative supervision mechanism for overall coordination is necessary to be established among different departments and supervision objects.

The investment project supervision has the characteristics of complex project, huge number of supervision points, high information acquisition requirement and the like, if the extraction of the supervision key nodes of the targets (five targets of cost, progress, quality, safety and environment) is respectively carried out on the whole life of the project construction, the collection process is disordered due to time control difference, information isolation, lack of a sharing platform and the like, and a standardized information model is necessary to be established to realize real-time and dynamic management. And when finding a bad operation state, the manager needs to inform each relevant responsible person in time so as to be convenient for the relevant responsible person to adjust the project adaptively. However, it generally takes a long time for a manager to notify a relevant person in charge from the discovery of a bad operation state, which often causes a situation of untimely adjustment, and is likely to cause low supervision efficiency.

Based on the above principle and the above application scenario, it should be noted that the present application provides a BIM-based overall process engineering cost management method, that is, the method is described from the perspective of a processor, and the BIM-based overall process engineering cost management method can be implemented on an intelligent device through programming as a computer program, which includes but is not limited to a computer, a network host, an intelligent terminal, and the like.

Referring to fig. 1, a BIM-based overall process engineering cost management method disclosed in one embodiment of the present application includes:

and S100, acquiring total data information of each stage in the whole engineering process.

Each stage in the whole engineering process is an engineering planning stage, an engineering preparation stage, an engineering construction stage, a completion acceptance stage and an engineering operation stage. The total data information refers to information about the project that all phases relate to.

Specifically, the manager manually inputs the total data information into the BIM-based whole process construction cost management system according to the project list.

And S110, extracting key point information of each stage in the whole engineering process based on the total data information.

Each stage includes a cost dimension, a progress dimension, a quality dimension, and a security dimension. The key point information refers to data of key links of each target in each stage.

And (3) engineering planning stage: the key links of the cost dimension comprise a bid inviting scheme, quota design, bidder qualification review, economic review, contract terms, economic risk, a design task book and a work summary report; the key links of the progress dimension comprise planning progress, engineering time sequence, project construction period determination, total plane planning and resource requirement planning; the key links of the quality dimension comprise establishment of management organization, establishment of post responsibility system, proposal of management scheme and determination of the quality dimension and level; the key links of the safety dimension comprise establishment of an organization, engineering condition analysis, management scheme proposal presentation, regulation standard determination, influence factor analysis and influence comprehensive evaluation.

A project preparation stage: the key links of the cost dimension comprise the deduction of quota design condition, the utilization value engineering optimization design scheme condition, investment estimation examination, design approximate calculation control, design budget control, technical examination and economic examination; the key links of the progress dimension comprise a work outline, progress tracking, report auditing and acceptance, engineering scheme design, construction organization design and a progress management plan; key links of quality dimension comprise bid inviting preparation, bid inviting process, contract signing, primary design control, construction drawing design control and matching quality control plan; the key links of the safety dimension comprise primary design, technical design, construction drawing design, design scheme evaluation, matching scheme design and safety department examination and approval.

And (3) engineering construction stage: the key links of the cost dimension comprise field construction cost management, project payment record, project quantity control, project money accounting, cost result analysis and project variable cost control; the key links of the progress dimension comprise implementation plan making, field arrangement and entry, approval of start permission, resource implementation, construction organization and cooperation, project implementation record, resource input record and progress analysis and control; key links of quality dimensionality comprise bid inviting management, construction preparation management, measure arrangement, program execution, execution condition inspection and execution condition summarization; the key links of the safety dimension comprise hidden danger investigation, protective measure preparation, system implementation, education and delivery, measure arrangement, program execution, execution condition inspection and execution condition summarization.

And (3) in the engineering completion acceptance stage: the key links of the expense dimension comprise budget control basis compiling, payment certificate settlement, legacy problem solving, project cost accounting, audit report compiling, completion financial settlement, project completion drawing and project expense; the key links of the progress dimension comprise field inspection, completion report examination, project and file transfer, evaluation after management planning, evaluation after management implementation and evaluation after management measures; key links of quality dimension comprise main project acceptance, quality grade evaluation, quality of technical documents and compilation of acceptance reports; the key links of the safety dimension comprise installation facility acceptance, management effect inspection and post-management evaluation.

And (3) engineering operation stage: the key links of the expense dimension comprise operation expense prediction, cost management, financial management, personnel management and engineering demolition; the key links of the progress dimension comprise operation scheme formulation, resource demand planning, cost analysis, post setting, benefit analysis and overall process evaluation; key links of the quality dimension comprise operation management, resource optimization, cost control, personnel optimization, profit allocation and engineering overall process evaluation; key links of the security dimension comprise security measure evaluation, operation condition analysis, cost expenditure rationality analysis, enterprise culture establishment, management benefit evaluation and sustainability analysis.

And S120, constructing a BIM (building information modeling) model according to the key point information of each stage in the whole engineering process.

The BIM model is a complete information model, and can integrate engineering information, processes and resources of engineering projects at different stages in a full life cycle into one model, so that the BIM model can be conveniently used by all engineering participants.

Specifically, the BIM is constructed through revit software by using the key point information of each stage, namely the key point information of each stage can be embodied in the BIM so as to be convenient for visualizing the key point information of each stage, and the supervision of a manager is facilitated.

And S130, monitoring the whole engineering process based on the BIM, predicting tasks of all stages in the whole engineering process in real time, and generating prediction information of all stages.

Specifically, based on the BIM model, the BIM simulation function is utilized to perform cost simulation, progress simulation, quality simulation and safety simulation, so that prediction is performed, and prediction information of each key link in each stage is obtained.

And S140, comparing the prediction information with a preset target, and judging whether the prediction information has a bad state.

The preset targets comprise a cost target, a progress target, a quality target and a safety target of different key links in each stage, namely target parameters are preset in each key link of each stage of the engineering.

Specifically, the prediction information is read to obtain progress prediction data, cost prediction data, quality prediction data and safety prediction data; comparing the progress prediction data, the expense prediction data, the quality prediction data and the safety prediction data with corresponding preset targets respectively; if the difference value is greater than 10%, the state is determined to be bad.

The progress prediction data comprises prediction data of each key link in the progress latitude; the cost prediction data comprises prediction data of each key link in the cost latitude; the quality prediction data comprises prediction data of each key link in the quality latitude; the safety prediction data comprises prediction data of each key link in the safety latitude.

And S150, if the bad state exists, generating corresponding prompt information.

The prompt information includes phase data and key link prompts, for example: in the engineering preparation stage, a progress tracking link of the progress dimension has a bad state, and the bad state is that the predicted data of the progress tracking is 11% lower than the preset target, the prompt information is as follows: "engineering preparation phase, progress dimension, progress trace present bad status (11% lower than preset target)".

Specifically, reading the stage and the key link of the bad state; and generating prompt information according to the stage and the key link to which the bad state belongs.

Referring to fig. 2, a BIM-based overall process construction cost management method disclosed in another embodiment of the present application is different from the above-described embodiment in that: if the bad state exists, after the corresponding prompt information is generated, the method further comprises the following steps:

and S260, sending the prompt information to the mobile terminal or the computer terminal of the relevant responsible person.

Another embodiment of S260 is: sending prompt information to a mobile terminal or a computer terminal of a relevant responsible person; receiving feedback information from a mobile terminal or a computer terminal of a related responsible person; judging whether the related responsible person refers to the prompt information manually or not according to the feedback information; if not, the prompt message is sent to the mobile terminal or the computer terminal of the relevant responsible person again.

The feedback information refers to the total time of the prompt information viewed by the related responsible person. In this embodiment, if the total time for the relevant person in charge to view the prompt information is greater than 5 seconds, it is determined that the relevant person in charge belongs to the artificial review prompt information.

Further, if not, the prompt message is retransmitted to the mobile terminal or the computer terminal of the relevant responsible person, and another implementation manner is as follows: if not, the prompt message is sent to the mobile terminal or the computer terminal of the relevant responsible person again; if the relevant responsible person is to look up the prompt information manually, obtaining problem information according to the prompt information and the corresponding prediction information; obtaining processing scheme information associated with the issue information; and sending the processing scheme information to a mobile terminal or a computer terminal of a related responsible person.

Specifically, obtaining the processing scheme information related to the question information includes: matching a corresponding processing scheme in a preset processing scheme database according to the problem information, and forming processing scheme information if the matching is successful; and if the matching fails, acquiring the processing scheme information manually input by the manager.

The question information refers to relevant questions appearing in the prompt information, and the questions are originated from each key link in each stage. The processing solution information refers to a solution for solving a related problem, which corresponds to the related problem, and the processing solution is derived from a network, a solution library preset in a memory, or contents temporarily manually input by a manager.

For example, if the prompt message is: "engineering preparation stage, progress dimension, progress tracking have bad state (11% lower than the preset target)", then the problem information is: the progress tracking is 11% lower than the expected target, and then a processing scheme is matched in a preset scheme library, if the matching is successful, the scheme is directly adopted, and if the matching is failed, the processing scheme is matched in the network; if the match still fails in the network, manual input by the administrator is required. The processing scheme information of the problem information is as follows: accelerating progress tracking, namely reducing the difference value between the progress tracking and an expected target to be within 10% or 0%;

if the prompt information is: "engineering construction stage, expense dimension, engineering money accounting have bad state (than preset target height or 11% lower)" then the problem information is: the project money accounting is higher or lower than the expected target by 11 percent, and then the project money is matched with the processing scheme in a preset scheme library, if the matching is successful, the project money is directly adopted, and if the matching is failed, the project money is matched with the processing scheme in the network; if the match still fails in the network, manual input by the administrator is required. The processing scheme information of the problem information is as follows: recalculating, namely reducing the difference value between the progress tracking and the expected target to be within 10% or 0%;

if the prompt information is: in the process of acceptance check after construction, quality dimension and quality of technical files have poor states (11% lower than the preset target quality), the problem information is as follows: the method comprises the steps that 'the quality of a technical file is 11% lower than that of an expected target', then a processing scheme is matched in a preset scheme library firstly, if matching is successful, the technical file is directly adopted, and if matching fails, the processing scheme is matched in a network; if the match still fails in the network, manual input by the administrator is required. The processing scheme information of the problem information is as follows: "re-make the relevant technical file, reduce the quality of the technical file and the quality of the expected goal within 10% or reduce to 0";

if the prompt information is: "engineering operation stage, safety dimension, safety measure evaluation has bad state (11% worse than preset target)", then the problem information is: the safety measure evaluation is 11% worse than the expected target, and then the scheme is matched and processed in a preset scheme library, if the matching is successful, the scheme is directly adopted, and if the matching is failed, the processing scheme is matched in the network; if the match still fails in the network, manual input by the administrator is required. The processing scheme information of the problem information is as follows: adding safety measures or repairing the existing safety measures, and reducing the difference value between the safety measure evaluation and the expected target to be within 10% or 0%.

And S270, issuing prompt information to the sharing platform.

The shared platform refers to a network platform on which relevant responsible persons can log in through an account and then view information. After the prompt information is issued to the sharing platform, the related responsible person can log in the sharing platform and immediately consult.

Referring to fig. 3, a BIM-based overall process construction cost management method disclosed in another embodiment of the present application is different from the above-described embodiment in that: after the BIM model is constructed according to the key point information of each stage in the whole engineering process, the method further comprises the following steps:

s330, extracting the document position information of all the documents based on the total data information.

The document refers to all relevant drawings, equipment lists, equipment purchasing information and documents during construction.

And S340, linking the document position information with the BIM model.

After the document position information is linked with the BIM model, the three-dimensional model is directly utilized to carry out rapid search and rapid positioning on the document, thereby being beneficial to improving the supervision efficiency.

In conclusion, the process implemented by the method is beneficial to building a BIM (building information modeling) model according to the key point information, a manager can supervise each stage of the project, the prediction information is automatically generated, whether the bad state exists or not can be conveniently and quickly judged, the corresponding prompt information is generated, the prompt information is beneficial to finding problems by the manager, the time for finding the problems by the manager is shortened, the manager can directly send the prompt information to the relevant responsible person, and the supervision efficiency is improved.

Referring to fig. 4, the embodiment of the present application further discloses a BIM-based overall process engineering cost management system, including:

an obtaining module 400, configured to obtain total data information of each stage in the whole engineering process;

an extraction module 410, configured to extract, based on the total data information, key point information of each stage in the overall engineering process;

the building module 420 is used for building a BIM (building information modeling) model according to the key point information of each stage in the whole engineering process;

the prediction module 430 is used for monitoring the whole engineering process based on the BIM model, predicting tasks of each stage in the whole engineering process in real time and generating prediction information of each stage;

the judging module 440 is configured to compare the prediction information with a preset target, and judge whether the prediction information has a bad state;

the generating module 450 is configured to generate corresponding prompt information if there is a bad status.

To sum up, the extraction module 400 can extract the key point information based on the total data information obtained by the acquisition module 400, so that the BIM model constructed by the construction module is more accurate, and further the prediction module 430 generates accurate prediction information, and after the determination by the determination module 440, a bad state exists, and then the generation module 450 generates prompt information, so that the prompt information is obtained more accurately.

Referring to fig. 5, an embodiment of the present application further discloses an electronic device.

An electronic device 500 comprising a memory 510 and a processor 520, the memory 510 having stored thereon a computer program that can be loaded and executed by the processor 520, the computer program, when executed by the processor 520, performing the steps of: acquiring total data information of each stage in the whole engineering process; extracting key point information of each stage in the whole engineering process based on the total data information; constructing a BIM (building information modeling) model according to key point information of each stage in the whole engineering process; monitoring the whole engineering process based on a BIM model, predicting tasks of all stages in the whole engineering process in real time, and generating prediction information of all stages; comparing the prediction information with a preset target, and judging whether the prediction information has a bad state or not; and if the bad state exists, generating corresponding prompt information.

Optionally, in an embodiment of the present application, when the computer program is executed by the processor 520, the following steps are performed: sending prompt information to a mobile terminal or a computer terminal of a relevant responsible person; and issuing prompt information to the sharing platform.

Optionally, in an embodiment of the present application, when the computer program is executed by the processor 520, the following steps are performed: receiving feedback information from a mobile terminal or a computer terminal of a related responsible person; judging whether the related responsible person refers to the prompt information manually or not according to the feedback information; if not, the prompt message is sent to the mobile terminal or the computer terminal of the relevant responsible person again.

Optionally, in an embodiment of the present application, when the computer program is executed by the processor 520, the following steps are performed: reading the prediction information to obtain progress prediction data, expense prediction data, quality prediction data and safety prediction data; comparing the progress prediction data, the expense prediction data, the quality prediction data and the safety prediction data with corresponding preset targets respectively; if the difference value is greater than 10%, the state is determined to be bad.

Optionally, in an embodiment of the present application, when the computer program is executed by the processor 520, the following steps are performed: if the relevant responsible person is to look up the prompt information manually, obtaining problem information according to the prompt information and the corresponding prediction information; obtaining processing scheme information associated with the issue information; and sending the processing scheme information to a mobile terminal or a computer terminal of a related responsible person.

Optionally, in an embodiment of the present application, when the computer program is executed by the processor 520, the following steps are performed: matching a corresponding processing scheme in a preset processing scheme database according to the problem information, and forming processing scheme information if the matching is successful; and if the matching fails, acquiring the processing scheme information manually input by the manager.

Optionally, in an embodiment of the present application, when the computer program is executed by the processor 520, the following steps are performed: extracting document position information of all documents based on the total data information; and linking the document position information with the BIM model.

The embodiment of the application also discloses a computer readable storage medium, which stores a computer program capable of being loaded and executed by the processor, and when the computer program is executed by the processor, the steps of any BIM-based whole process engineering cost management method are realized, and the same effect can be achieved.

The computer-readable storage medium includes, for example: various media capable of storing program codes, such as a usb disk, a removable hard disk, a Read-only memory (ROM), a Random Access Memory (RAM), a magnetic disk, or an optical disk.

The foregoing is a preferred embodiment of the present application and is not intended to limit the scope of the application in any way, and any features disclosed in this specification (including the abstract and drawings) may be replaced by alternative features serving equivalent or similar purposes, unless expressly stated otherwise. That is, unless expressly stated otherwise, each feature is only an example of a generic series of equivalent or similar features.

Claims (10)

1. The BIM-based whole process engineering cost management method is characterized by comprising the following steps:

acquiring total data information of each stage in the whole engineering process;

extracting key point information of each stage in the whole engineering process based on the total data information;

constructing a BIM (building information modeling) model according to key point information of each stage in the whole engineering process;

monitoring the whole engineering process based on a BIM model, predicting tasks of all stages in the whole engineering process in real time, and generating prediction information of all stages;

comparing the prediction information with a preset target, and judging whether the prediction information has a bad state or not;

and if the bad state exists, generating corresponding prompt information.

2. The BIM-based overall process construction cost management method according to claim 1, wherein after generating corresponding prompt information if there is a bad condition, the method further comprises:

sending prompt information to a mobile terminal or a computer terminal of a relevant responsible person;

and issuing prompt information to the sharing platform.

3. The BIM-based overall process engineering cost management method according to claim 2, wherein after sending the prompt message to the mobile terminal or the computer terminal of the relevant responsible person, the method further comprises:

receiving feedback information from a mobile terminal or a computer terminal of a related responsible person;

judging whether the related responsible person refers to the prompt information manually or not according to the feedback information;

if not, the prompt message is sent to the mobile terminal or the computer terminal of the relevant responsible person again.

4. The BIM-based overall process engineering cost management method according to claim 1, wherein the comparing the prediction information with a preset target and judging whether the prediction information has a bad state comprises:

reading the prediction information to obtain progress prediction data, expense prediction data, quality prediction data and safety prediction data;

comparing the progress prediction data, the expense prediction data, the quality prediction data and the safety prediction data with corresponding preset targets respectively;

if the difference value is greater than 10%, the state is determined to be bad.

5. The BIM-based overall process engineering cost management method according to claim 3, wherein if the indication message is not sent again to the mobile terminal or the computer terminal of the relevant responsible person, the method further comprises:

if the relevant responsible person is to look up the prompt information manually, obtaining problem information according to the prompt information and the corresponding prediction information;

obtaining processing scheme information associated with the issue information;

and sending the processing scheme information to a mobile terminal or a computer terminal of a related responsible person.

6. The BIM-based total process construction cost management method according to claim 5, wherein the obtaining of the processing solution information related to the problem information comprises:

matching a corresponding processing scheme in a preset processing scheme database according to the problem information, and forming processing scheme information if the matching is successful;

and if the matching fails, acquiring the processing scheme information manually input by the manager.

7. The BIM-based overall process engineering cost management method according to claim 1, wherein after constructing the BIM model according to the key point information of each stage in the overall process of the engineering, the method further comprises:

extracting document position information of all documents based on the total data information;

and linking the document position information with the BIM model.

8. BIM-based overall process engineering cost management system is characterized by comprising:

the acquisition module is used for acquiring total data information of each stage in the whole engineering process;

the extraction module is used for extracting key point information of each stage in the whole engineering process based on the total data information;

the building module is used for building a BIM (building information modeling) model according to the key point information of each stage in the whole engineering process;

the prediction module is used for monitoring the whole engineering process based on the BIM model, predicting tasks of all stages in the whole engineering process in real time and generating prediction information of all stages;

the judging module is used for comparing the prediction information with a preset target and judging whether the prediction information has a bad state or not;

and the generating module is used for generating corresponding prompt information if the bad state exists.

9. An electronic device comprising a memory and a processor, the memory having stored thereon a computer program that can be loaded by the processor and that executes the method according to any of claims 1 to 7.

10. A computer-readable storage medium, in which a computer program is stored which can be loaded by a processor and which executes the method of any one of claims 1 to 7.

Images