CN112884290A - BIM-based field construction management method - Google Patents

Abstract

The invention discloses a field construction management method based on BIM, and relates to the technical field of field construction management methods. The invention comprises the following steps: s1 deepening design: combining construction operation specifications and construction processes based on a BIM model; carrying out refined modeling on the project steel structure; generating a secondary structure reserved hole map by using BIM after the comprehensive arrangement of pipelines is finished; s2 field cloth management; s3 group management: simulating, analyzing and optimizing a project construction scheme by adopting a BIM technology; and S4 progress management: adding information into the three-dimensional model by combining the construction progress plan, and performing 4D construction simulation; s5 materials, equipment management: providing basis for material requirement plans of different stages of a project; s6, quality and safety management: simulating engineering quality and safety key control points based on a BIM model; and S7 completion management: forming a complete BIM model. The high-efficiency transmission and real-time sharing of construction site information are realized, and the construction management level is improved.

Description

BIM-based field construction management method

Technical Field

The invention relates to the technical field of field construction management methods, in particular to a field construction management method based on BIM.

Background

With the development of urbanization, the requirements of society on building quality are continuously improved. In the building engineering management process, a project planning decision-making stage, a building design stage, a construction and construction stage and a completion input operation management stage are involved. The existing design drawing is a two-dimensional drawing, and is difficult to communicate with non-professionals, and the communication of the professionals depends on imagination, so that the situation that deviation is difficult to find easily occurs; in the construction process, multiple specialties are needed to work cooperatively, and a large amount of time and energy are consumed by the cooperative work.

Therefore, a field construction management method based on BIM is urgently needed, which realizes the efficient transmission and real-time sharing of construction field information, improves the construction management level, and performs multi-professional coordination, field arrangement optimization, construction progress, quality management, safety management and resource and cost management in the construction process, thereby greatly reducing rework and saving construction cost.

Disclosure of Invention

Aiming at the defects in the prior art, the invention provides a BIM-based field construction management method, which realizes the high-efficiency transmission and real-time sharing of construction field information, improves the construction management level, and performs multi-professional coordination, field arrangement optimization, construction progress, quality management, safety management, resource and cost management in the construction process, thereby greatly reducing rework and saving construction cost.

The invention specifically adopts the following technical scheme:

the BIM-based field construction management method comprises the following steps:

s1 deepening design: carrying out comprehensive collision inspection on buildings, structures and electromechanical equipment based on a BIM model in combination with construction operation specifications and a construction process; carrying out refined modeling on the project steel structure, and marking the specification, material, weight, axis and elevation information of the component; generating a secondary structure reserved hole map by using BIM after the comprehensive arrangement of pipelines is finished;

and S2 field layout management: planning, arranging, analyzing and optimizing site terrain, existing facilities, surrounding environment, construction area, temporary road and facilities, processing area, material yard, construction machinery and safe and civilized construction facilities in each construction stage based on the BIM model;

s3 group management: simulating, analyzing and optimizing a project construction scheme by adopting a BIM technology;

and S4 progress management: adding information into the three-dimensional model by combining the construction progress plan, performing 4D construction simulation through dynamic linkage of the plan progress model and the actual progress model, integrating the construction model with on-site facility, machinery, equipment and pipeline information, and checking the space and the space, wherein the space and time matching degree is obtained;

s5 materials, equipment management: on the basis of a BIM model, the BIM software is used for exporting various professional material and equipment lists, and bases are provided for material demand plans of different stages of a project;

s6, quality and safety management: performing analog simulation and scheme optimization on engineering quality and safety key control points based on a BIM model;

and S7 completion management: and adding completion acceptance information to the model based on the construction BIM model, and correcting according to completion requirements to further form a completion BIM model.

The present invention is further preferred: the refined modeling of the project steel structure in S1 is based on TEKLA software.

The present invention is further preferred: and after the project steel structure is refined and modeled in S1, counting the specifications and the quantity of materials required by a local area or a construction section, providing a basis for material planning, and providing a relevant basis for field level arrangement, tower crane model selection and climbing.

The present invention is further preferred: and S1, deeply arranging all water pipe wells and electric wells of the project, reasonably setting the positions of the supports and the pipelines in the well, and finally generating a two-dimensional drawing.

The present invention is further preferred: and S1, comprehensively arranging all machine rooms based on the BIM technology, and transmitting the machine rooms to field operators in a drawing mode.

The present invention is further preferred: and S3, the construction process is displayed in an animation demonstration mode before formal construction, so that the problem of edge folding and closing caused by quality reworking easily in the construction process is solved.

The present invention is further preferred: the construction progress plan in S4 is compiled by project, and the information is added to the three-dimensional model by means of Navisvorks software.

The present invention is further preferred: and the EBIM platform mobile equipment is used for checking and accepting the quality and the safety of the field engineering, and the dynamic tracking and recording of quality and safety management are realized.

The present invention is further preferred: and the EBIM platform uploads the BIM model to a server after the BIM model is lightened, and the PC end and the mobile end are mutually associated through the cloud platform.

The invention has the beneficial effects that:

the invention coordinates multiple specialties, optimizes site layout, manages construction progress, quality, safety and resources and cost during construction, greatly reduces rework and saves construction cost. Through the deepening design, the comprehensive collision inspection of the majors such as buildings, structures, electromechanical equipment and the like is carried out, the collision problem of each major is solved, the construction optimization design is completed, the construction model is perfected, and the reasonability, the accuracy and the checking performance of each major are improved. Through the refined modeling, a basis is provided for a material plan, and a related basis can also be provided for field level arrangement, tower crane model selection, climbing and the like. Through field distribution management, the field arrangement is scientific and reasonable. Through group management, zero collision, zero conflict and zero rework are realized as much as possible, so that the rework cost is greatly reduced, the resource waste, conflict and safety problems are reduced, and real construction is guided. The problems which can occur in the construction can be found before the construction is started through schedule management so as to be dealt with in advance; the method can also be used as a feasibility guidance of construction, and helps to determine a reasonable construction scheme, a personnel and equipment configuration scheme and the like. Through material and equipment management, on the premise of ensuring the requirement of site construction progress, the material and capital cost are saved to the greatest extent. Through completion management, completion acceptance information is added to the model and is corrected according to completion requirements, so that a completion BIM model is formed and serves as an important reference basis for completion data.

Detailed Description

Hereinafter, embodiments of the present invention will be described in detail. The following examples are only for illustrating the technical solutions of the present invention more clearly, and therefore are only examples, and the protection scope of the present invention is not limited thereby.

It is to be noted that, unless otherwise specified, technical or scientific terms used herein shall have the ordinary meaning as understood by those skilled in the art to which the invention pertains.

What is called BIM, the national standard for BIM in the united states is explained as follows: "digital representation of physical and functional characteristics of a construction project; an information sharing platform; an information process for realizing the whole life cycle management of the construction engineering; a collaborative work platform for realizing the insertion, extraction, update and modification of information of different stages of a building project.

The BIM-based field construction management method comprises the following steps:

s1 deepening design: carrying out comprehensive collision inspection on buildings, structures and electromechanical equipment based on a BIM model in combination with construction operation specifications and a construction process; the problem of collision of each specialty is solved, the construction optimization design is completed, the construction model is perfected, and the reasonability, the accuracy and the checking performance of each specialty of construction are improved. Carrying out refined modeling on the project steel structure, and marking the specification, material, weight, axis and elevation information of the component; after the comprehensive arrangement of pipelines is completed in the electromechanical industry, a hole pattern reserved for a secondary structure is generated by using BIM (building information modeling) to realize one-layer-one-row-one-wall-one-figure, and after the drawings are confirmed by each party, a labor team is issued to construct according to the drawings, so that the construction quality is greatly improved, and convenience is provided for later-stage pipeline installation.

And S2 field layout management: and planning, arranging, analyzing and optimizing site terrain, existing facilities, surrounding environment, construction area, temporary road and facilities, processing area, material yard, construction machinery and safety civilized construction facilities in each construction stage based on the BIM model.

S3 group management: simulating, analyzing and optimizing a project construction scheme by adopting a BIM technology; therefore, problems possibly occurring in construction are found, preventive measures are taken before construction until an optimal construction scheme is obtained, and zero collision, zero conflict and zero rework are realized as far as possible, so that the rework cost is greatly reduced, the resource waste, conflict and safety problems are reduced, and real construction is guided.

And S4 progress management: adding information into the three-dimensional model by combining the construction progress plan, performing 4D construction simulation through dynamic linkage of the plan progress model and the actual progress model, integrating the construction model with on-site facility, machinery, equipment and pipeline information, and checking whether space conflicts with space and time so as to find possible problems in construction before construction is started and process in advance; the method can also be used as a feasibility guidance of construction, and helps to determine a reasonable construction scheme, a personnel and equipment configuration scheme and the like.

S5 materials, equipment management: on the basis of the BIM model, the BIM software is used for exporting the detailed lists of all professional materials and equipment, so that a basis is provided for material demand plans of different stages of a project, and the materials and the capital cost are saved to the greatest extent on the premise of ensuring the requirements of site construction progress.

S6, quality and safety management: and performing analog simulation and scheme optimization on the engineering quality and the safety key control points based on the BIM model.

And S7 completion management: and adding completion acceptance information to the model based on the construction BIM model, and correcting according to completion requirements to further form a completion BIM model as an important reference basis for completion data.

The present invention is further preferred: the refined modeling of the project steel structure in S1 is based on TEKLA software.

The present invention is further preferred: and after the project steel structure is refined and modeled in S1, counting the specifications and the quantity of materials required by a local area or a construction section, providing a basis for material planning, and providing a relevant basis for field level arrangement, tower crane model selection and climbing.

The present invention is further preferred: and S1, aiming at the characteristics of narrow pipe wells and dense pipelines of the project, deeply arranging all the pipe wells and the electric wells of the project, reasonably setting the positions of the supports and the pipelines in the well, finally generating a two-dimensional drawing, issuing labor service, and guiding site construction and prefabrication and processing of the supports.

The present invention is further preferred: the machine room construction drawing provided by a design institute is not detailed for the spatial position of a pipeline, generally focuses on a certain specialty, cannot completely consider the comprehensive arrangement of the pipeline of multiple specialties, the selection of equipment is often selected according to experience when the construction drawing is drawn, and has larger deviation with equipment provided by a manufacturer in the later period, so that the construction drawing in the earlier period has larger difference with the actual installation on the site in the later period, and all machine rooms are comprehensively arranged by means of a BIM technology at present and are transmitted to site operators in a CAD drawing mode. The method has the advantages that the influence of human factors on the construction process and the difficulty of specific operation are reduced, the construction efficiency is improved, the cost is reduced, and the engineering quality is improved. And S1, comprehensively arranging all machine rooms based on the BIM technology, and transmitting the machine rooms to field operators in a drawing mode.

The present invention is further preferred: and S3, the construction process is displayed in an animation demonstration mode before formal construction, so that the problem of edge folding and closing of quality reworking easily occurs in the construction process, the reworking rate is reduced, repeated construction is avoided, and the purpose of 'one-time survival' is achieved. Meanwhile, the overall display effect can be predicted, and the construction scheme can be guided.

The present invention is further preferred: the construction progress plan in S4 is compiled by project, and the information is added to the three-dimensional model by means of Navisvorks software.

The present invention is further preferred: and the EBIM platform mobile equipment is used for checking and accepting the quality and the safety of the field engineering, and the dynamic tracking and recording of quality and safety management are realized.

The present invention is further preferred: the EBIM platform uploads the BIM to the server after being lightened, and the PC end and the mobile end are mutually associated through the cloud platform, so that the work communication of each construction unit in safety, quality and other construction contents is realized, and the personnel operation management and quality management are greatly enhanced.

Finally, it should be noted that: the above embodiments are only used to illustrate the technical solution of the present invention, and not to limit the same; while the invention has been described in detail and with reference to the foregoing embodiments, it will be understood by those skilled in the art that: the technical solutions described in the foregoing embodiments may still be modified, or some or all of the technical features may be equivalently replaced; such modifications and substitutions do not depart from the spirit and scope of the present invention, and they should be construed as being included in the following claims and description.

Claims (9)

1. A field construction management method based on BIM is characterized in that: the method comprises the following steps:

s1 deepening design: carrying out comprehensive collision inspection on buildings, structures and electromechanical equipment based on a BIM model in combination with construction operation specifications and a construction process; carrying out refined modeling on the project steel structure, and marking the specification, material, weight, axis and elevation information of the component; generating a secondary structure reserved hole map by using BIM after the comprehensive arrangement of pipelines is finished;

and S2 field layout management: planning, arranging, analyzing and optimizing site terrain, existing facilities, surrounding environment, construction area, temporary road and facilities, processing area, material yard, construction machinery and safe and civilized construction facilities in each construction stage based on the BIM model;

s3 group management: simulating, analyzing and optimizing a project construction scheme by adopting a BIM technology;

and S4 progress management: adding information into the three-dimensional model by combining the construction progress plan, performing 4D construction simulation through dynamic linkage of the plan progress model and the actual progress model, integrating the construction model with on-site facility, machinery, equipment and pipeline information, and checking the space and the space, wherein the space and time matching degree is obtained;

s5 materials, equipment management: on the basis of a BIM model, the BIM software is used for exporting various professional material and equipment lists, and bases are provided for material demand plans of different stages of a project;

s6, quality and safety management: performing analog simulation and scheme optimization on engineering quality and safety key control points based on a BIM model;

and S7 completion management: and adding completion acceptance information to the model based on the construction BIM model, and correcting according to completion requirements to further form a completion BIM model.

2. The BIM-based construction site management method according to claim 1, wherein: the refined modeling of the project steel structure in S1 is based on TEKLA software.

3. The BIM-based construction site management method according to claim 1, wherein: and after the project steel structure is refined and modeled in S1, counting the specifications and the quantity of materials required by a local area or a construction section, providing a basis for material planning, and providing a relevant basis for field level arrangement, tower crane model selection and climbing.

4. The BIM-based construction site management method according to claim 1, wherein: and S1, deeply arranging all water pipe wells and electric wells of the project, reasonably setting the positions of the supports and the pipelines in the well, and finally generating a two-dimensional drawing.

5. The BIM-based construction site management method according to claim 1, wherein: and S1, comprehensively arranging all machine rooms based on the BIM technology, and transmitting the machine rooms to field operators in a drawing mode.

6. The BIM-based construction site management method according to claim 1, wherein: and S3, the construction process is displayed in an animation demonstration mode before formal construction, so that the problem of edge folding and closing caused by quality reworking easily in the construction process is solved.

7. The BIM-based construction site management method according to claim 1, wherein: the construction progress plan in S4 is compiled by project, and the information is added to the three-dimensional model by means of Navisvorks software.

8. The BIM-based construction site management method according to claim 1, wherein: and the EBIM platform mobile equipment is used for checking and accepting the quality and the safety of the field engineering, and the dynamic tracking and recording of quality and safety management are realized.

9. The BIM-based construction site management method according to claim 8, wherein: and the EBIM platform uploads the BIM model to a server after the BIM model is lightened, and the PC end and the mobile end are mutually associated through the cloud platform.