CN111444568A - Engineering monitoring BIM cooperative platform based on Internet of things - Google Patents

Abstract

An engineering monitoring BIM cooperative platform based on the Internet of things comprises: the progress management module is used for progress control and comprises the following steps of comparing feasibility of on-site actual construction progress and planned progress based on the aerial photo of the unmanned aerial vehicle and the real-time generation characteristic of the BIM three-dimensional model, and ensuring that the engineering progress is controllable; and based on BIM progress plan and simulation, continuously refining and adjusting the project progress plan by using a visual and transparent BIM model and the actual field progress condition, and ensuring the possibility of reasonable, feasible and shorter construction period to be deduced under the basic progress target; the field visual monitoring management module is used for field visual monitoring, combining BIM, and controlling personnel and equipment safety standard through mobile intelligent video monitoring to ensure the progress and quality of the project; the quality management module, the cost control module, the safety management module and the labor management module are used for personnel management and performing real-time background management and allocation on site constructors based on the intuition of the BIM model and the internet data.

Description

Engineering monitoring BIM cooperative platform based on Internet of things

Technical Field

The invention relates to the field of transformer substation construction, in particular to an engineering monitoring BIM (building information modeling) cooperative platform based on the Internet of things.

Background

BIM has been developed from the construction industry in the united states and is gradually expanded to developed countries such as europe and japan and korea. From the application field, the BIM technology is applied to the design and construction of building engineering and the maintenance and management stage after the building is built abroad, the corresponding application software is mature day by day, and the application value and the application potential are verified. The commercial property professional committee rate of the national real estate industry association was first organized in 2010 and published the "BIM application research report of the national commercial property" for guiding and tracking the application and development of the BIM technology in the commercial property field. However, in the prior art, if the BIM technology is well applied to the whole process of the construction period of the transformer substation, the problem to be solved still remains.

Disclosure of Invention

In order to solve the above problems, the invention provides an engineering monitoring BIM collaboration platform based on the internet of things, which comprises:

the progress management module is used for controlling the progress, and the feasibility comparison of the actual construction progress and the planned progress on the site is carried out on the basis of the aerial photo of the unmanned aerial vehicle and the real-time generation characteristic of the BIM three-dimensional model, so that the project progress is controlled; and on the basis of BIM progress plan and simulation, the BIM model and the actual field progress condition are utilized to continuously refine and adjust the project progress plan, so that the possibility of reasonable, feasible and shorter construction period is ensured to be deduced under the basic progress target;

the quality management module is used for checking the design safety, the reasonability and the constructability based on the BIM model, finding potential problems and improving the engineering quality; based on the BIM, the BIM is adopted to comprehensively coordinate each specialty and schedule the process, so that the one-time installation qualification rate is improved, and the engineering quality is improved; collision check between civil engineering and electromechanical equipment pipe networks is carried out based on the BIM technology so as to improve the engineering quality;

a cost control module: based on BIM multi-professional design examination, the 'missing and missing defects' on a construction drawing are eliminated before formal construction, design change is carried out in advance, and the conditions of labor waste and waste materials such as idling and reworking are avoided; model-based bill of materials, managing and controlling material costs;

the safety management module is used for carrying out safety production: on-site arrangement and management based on BIM, namely on the basis of a virtual construction BIM model added with a field and tool equipment model and information, more reasonable and safe on-site arrangement and multi-working-surface parallel arrangement under the change of a 4D time axis are researched and analyzed;

the labor management module is used for carrying out personnel management and carrying out real-time background management and allocation on site constructors based on the intuitiveness of the BIM model and the internet data;

the on-site visual monitoring management module is used for video monitoring environment and large-scale equipment, combines BIM, and through portable wisdom video monitoring, management and control personnel equipment safety standard ensures engineering progress and quality, calls at any time on-site monitoring video information through the platform simultaneously, carries out visual monitoring.

Furthermore, the BIM data and the multi-source data are fused in the three-dimensional GIS, and the multi-source data including images, terrains, oblique photography models, laser point clouds and underground pipelines are used for data monitoring and visual display.

Further, laser scanning, GPS, mobile communication, internet technology and BIM model of the project are integrated to guide, record, track and analyze various activities of the operation site;

further, acquiring the topography and landform of the engineering transformer substation through the orthographic aerial photography and oblique photography of the unmanned aerial vehicle, developing total-station three-dimensional modeling according to BIM, formulating data collection, extraction, cleaning, quality inspection and warehousing processes, and completing integration and warehouse building work of a three-dimensional visual special subject database; the information is collected through the mobile phone app and the web side, the system is automatically arranged, the information is displayed in the model section, the data is stored in the cloud, and a special subject database integrating collection, extraction, cleaning, quality inspection and warehousing is formed.

Has the advantages that:

according to the intelligent transformer substation operation and maintenance system, the BIM technology is popularized and applied in the capital construction implementation project by exploring the application point scheme of the transformer substation using the BIM technology in the whole process of design, construction and operation and maintenance, the project planning, design and construction whole process of projects is monitored and displayed through the platform, the efficiency is improved, the cost is saved, the construction period is shortened, a set of 3D visual intelligent transformer substation operation and maintenance system linked with the intelligent sensor of the Internet of things is delivered in the operation and maintenance stage, and efficient management of operation units in the future is facilitated.

Drawings

FIG. 1-a: the invention monitors and arranges the dot diagram on the spot;

FIG. 1-b: the invention monitors a point video image;

FIG. 2: the invention relates to a 4D construction simulation diagram;

FIG. 3: mobile phone APP, WEB, model terminal diagram;

FIG. 4: system block diagram of the present invention.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. The components of embodiments of the present invention generally described and illustrated in the figures herein may be arranged and designed in a wide variety of different configurations. Thus, the following detailed description of the embodiments of the present invention, presented in the figures, is not intended to limit the scope of the invention, as claimed, but is merely representative of selected embodiments of the invention. All other embodiments, which can be derived by a person skilled in the art from the embodiments of the present invention without making any creative effort, shall fall within the protection scope of the present invention.

The invention provides an engineering monitoring BIM (building information modeling) cooperative platform based on the Internet of things, which can be used for establishing an engineering construction process three-dimensional model, is applied to a monitoring platform, completes construction of a three-dimensional visual special subject database in the engineering construction process, realizes integration and library construction of related data in the engineering construction process, completes construction of an engineering construction progress data acquisition and reporting system, an engineering construction process data management and analysis system and an engineering construction process three-dimensional simulation and application system, and provides an informationized technical means support for operation and maintenance management.

In the invention, BIM modeling technology is utilized to carry out construction progress simulation, construction organization simulation and the like. For example: the BIM supervision platform realizes the management of the whole construction process through early-stage prejudgment, process recording and post-event tracing, and has the main functions of a progress management submodule, a quality management module, a cost control module, a safety management module, a labor management module and a field visual monitoring management module.

1) A progress control module:

1. and performing feasibility comparison on the actual construction progress and the planned progress on the site based on the aerial photo of the unmanned aerial vehicle and the real-time generation characteristic of the BIM, and ensuring that the engineering progress is controllable.

2. And the progress plan and the simulation based on the BIM are utilized, and the visual and transparent BIM model and the field actual progress condition are utilized to continuously refine and adjust the project progress plan, so that the possibility of reasonable, feasible and shorter construction period is ensured to be deduced under the basic progress target.

2) A quality control module:

1. based on the BIM model, the design safety, the reasonability and the constructability audit are realized, potential problems are found, and the engineering quality is improved;

2. based on the BIM, the BIM can achieve effective balance in the aspects of rationality, constructability, attractiveness and the like, improve the one-time installation qualification rate and improve the engineering quality;

3. and the design quality is improved and the engineering quality is guaranteed based on other professional analysis of the BIM model.

4. Collision check between civil engineering and electromechanical equipment pipe networks is carried out based on the BIM technology so as to improve the engineering quality;

3) a cost control module:

1. based on BIM multi-professional design examination, the 'missing and missing collision' on a construction drawing is eliminated before formal construction, design change is carried out in advance, the conditions of labor waste and waste materials such as idling and reworking are avoided, the engineering quality is improved, and the construction period and cost waste are avoided;

2. and the material cost is effectively managed and controlled based on the bill of materials of the model.

4) A safety management module:

1. on the basis of BIM field arrangement and management, namely on the basis of a virtual construction BIM model added with models and information such as a field, tool equipment and the like, more reasonable and safe field arrangement and multi-working-surface parallel arrangement under the change of a 4D time axis are researched and analyzed, and guarantee is provided for engineering safety production.

2. The project is created and managed virtually in a computer, so that the visualization and the fine management of the project are realized.

3. The BIM model is utilized to carry out technical background of important schemes for operators, so that the operators can see the important schemes at a glance, the operators have a certain mind, and the safety factor is improved.

As shown in fig. 2, the ship lock project is associated with a relevant time dimension, a specific node is bound to a specific model unit, and the creation and management of the project are virtually performed in a computer along with a time axis, so that the visualization and the fine management of the project are realized; the BIM model is utilized to carry out technical interaction of important schemes for operators, so that the operators can see the important schemes at a glance, the operators have a certain mind, and the safety factor is improved;

5) and a labor management module:

and based on the intuition of the BIM model and the development of the Internet +, the field constructors are subjected to real-time background management and allocation.

6) The field visualization management module:

the environment and large-scale equipment video monitoring module is characterized in that a place marked by a red circle shown in a figure 1-a is a video monitoring point and is used for on-site visual monitoring, BIM is combined, the safety specification of management and control personnel and equipment is realized through mobile intelligent video monitoring, the progress and the quality of engineering are guaranteed, and meanwhile, on-site monitoring video information can be called at any time through a platform, so that the visual monitoring strength is better promoted as shown in a figure 1-b;

the whole life cycle of the BIM, from planning, designing, constructing to operation and maintenance, is specific to the building main body, but the surrounding macroscopic geographic environment elements are very important, such as geographic landforms, roads and the like, which need to take into account the existing natural environment and man-made environment information. The three-dimensional GIS researches a macroscopic geographic environment and can provide various spatial inquiry and spatial analysis capabilities. At each stage of BIM, the three-dimensional GIS can provide visual display, management, decision support and other technical methods for the BIM.

The three-dimensional GIS technology is mainly applied to the field of construction process management, and comprises the steps of building a real three-dimensional landform and a refined earth surface three-dimensional scene of a construction site, providing a three-dimensional GIS basic platform environment, and providing a three-dimensional visual display mode for project construction progress management by combining a three-dimensional virtual simulation technology to truly reproduce construction site environments and construction states at different stages of project construction.

The three-dimensional GIS integrates a large amount of multi-source data such as images, terrains, oblique photography models, laser point clouds, underground pipelines and the like, BIM data and the multi-source data can be fused in the three-dimensional GIS, and macroscopic and comprehensive visual display and management are achieved.

1) The method comprises the following steps that BIM three-dimensional modeling and collision inspection in a power grid design stage, pipeline optimization and the like are relatively mature, deep research is needed on application points in a construction stage and an operation and maintenance stage, and GIS geographic information (technologies such as oblique photography and laser point cloud) is also needed to be combined to assist in solving the problems of construction and operation and maintenance; the operation and maintenance stage is deeply combined with the existing intelligent sensor of the intelligent construction site, a set of BIM visual intelligent substation operation and maintenance system is developed, and the difficulty faced by the first BIM intelligent substation is outstanding.

2) The technology of laser scanning, GPS, mobile communication, Internet and the like is integrated with the BIM model of the project to guide, record, track and analyze various activities of the operation site, so that the important errors are not generated during construction, and an accurate and visual BIM database is prepared for project operation and maintenance.

3) The BIM model and the requirements of a construction or operation management field are integrated, and then the maximum support of the BIM for building the intelligent transformer substation is formed by combining the technologies of Internet, mobile communication and the like.

4) The method comprises the steps of acquiring the landform and the landform of an engineering transformer substation through the orthographic aerial photography and oblique photography of an unmanned aerial vehicle, developing total-station three-dimensional modeling according to BIM, formulating data collection, extraction, cleaning, quality inspection and warehousing processes, and completing integration and warehouse building work of a three-dimensional visual special subject database.

And formulating data collection, extraction, cleaning, quality inspection and warehousing processes to complete the integration and database building work of the three-dimensional visual special subject database. As shown in fig. 3, information is collected through a mobile phone app and a web port, the system automatically sorts the information, the information is displayed in a model section, and data is stored in a cloud end to form a special subject database integrating collection, extraction, cleaning, quality inspection and warehousing. Fig. 4 is a system block diagram of the present invention, in which some of the modules have been embodied in the above embodiments.

According to one embodiment of the invention, the intelligent substation operation and maintenance system adopting 3D visualization and linkage with the intelligent sensor of the Internet of things is a 500kV substation with BIM operation and maintenance results in the southern power grid, so that integration of construction resources, knowledge sharing, flow reconstruction, mode innovation and value chain recombination of the novel power grid substation are promoted, lean management, digital construction and electronic handover levels of substation construction are improved, and guarantee is provided for realizing higher-quality field management and field safety, progress and quality.

Although illustrative embodiments of the present invention have been described above to facilitate the understanding of the present invention by those skilled in the art, it should be understood that the present invention is not limited to the scope of the embodiments, but various changes may be apparent to those skilled in the art, and it is intended that all inventive concepts utilizing the inventive concepts set forth herein be protected without departing from the spirit and scope of the present invention as defined and limited by the appended claims.

Claims (5)

1. The utility model provides an engineering monitoring BIM platform in coordination based on thing networking which characterized in that includes:

the progress management module is used for controlling the progress, and the feasibility comparison of the actual construction progress and the planned progress on the site is carried out on the basis of the aerial photo of the unmanned aerial vehicle and the real-time generation characteristic of the BIM three-dimensional model, so that the project progress is controlled; and on the basis of BIM progress plan and simulation, the BIM model and the actual field progress condition are utilized to continuously refine and adjust the project progress plan, so that the possibility of reasonable, feasible and shorter construction period is ensured to be deduced under the basic progress target;

the quality management module is used for checking the design safety, the reasonability and the constructability based on the BIM model, finding potential problems and improving the engineering quality; based on the BIM, the BIM is adopted to comprehensively coordinate each specialty and schedule the process, so that the one-time installation qualification rate is improved, and the engineering quality is improved; collision check between civil engineering and electromechanical equipment pipe networks is carried out based on the BIM technology so as to improve the engineering quality;

a cost control module: based on BIM multi-professional design examination, the 'missing and missing defects' on a construction drawing are eliminated before formal construction, design change is carried out in advance, and the conditions of labor waste and waste materials such as idling and reworking are avoided; model-based bill of materials, managing and controlling material costs;

the safety management module is used for carrying out safety production: on-site arrangement and management based on BIM, namely on the basis of a virtual construction BIM model added with a field and tool equipment model and information, more reasonable and safe on-site arrangement and multi-working-surface parallel arrangement under the change of a 4D time axis are researched and analyzed;

the labor management module is used for carrying out personnel management and carrying out real-time background management and allocation on site constructors based on the intuitiveness of the BIM model and the internet data;

the on-site visual monitoring management module is used for video monitoring environment and large-scale equipment, combines BIM, and through portable wisdom video monitoring, management and control personnel equipment safety standard ensures engineering progress and quality, calls at any time on-site monitoring video information through the platform simultaneously, carries out visual monitoring.

2. The engineering monitoring BIM cooperative platform based on the Internet of things of claim 1,

and fusing the BIM data and the multi-source data in the three-dimensional GIS system, and carrying out data monitoring and visual display by using the multi-source data including images, terrain, oblique photography models, laser point clouds and underground pipelines.

3. The engineering monitoring BIM cooperative platform based on the Internet of things of claim 1,

and integrating laser scanning, GPS, mobile communication, Internet technology and BIM models of projects to guide, record, track and analyze various activities of the operation site.

4. The IOT-based engineering monitoring BIM collaboration platform of claim 1, wherein the quality control module:

based on the BIM model, the design safety, the reasonability and the constructability audit are realized, potential problems are found, and the engineering quality is improved;

based on BIM (building information modeling) professional comprehensive coordination and process scheduling, the method can achieve effective balance in the aspects of rationality, constructability and attractiveness, improve the one-time installation qualification rate and improve the engineering quality;

based on other professional analysis of the BIM model, the design quality is improved, and the engineering quality is guaranteed;

and collision inspection between civil engineering and electromechanical equipment pipe networks is carried out based on the BIM technology so as to improve the engineering quality.

5. The engineering monitoring BIM cooperative platform based on the Internet of things of claim 3,

acquiring the topography and landform of an engineering transformer substation through the acquisition of an unmanned aerial vehicle through orthographic aerial photography and oblique photography, developing total-station three-dimensional modeling according to BIM, formulating data collection, extraction, cleaning, quality inspection and warehousing processes, and completing integration and warehouse building work of a three-dimensional visual special subject database; the information is collected through the mobile phone app and the web side, the system is automatically arranged, the information is displayed in the model section, the data is stored in the cloud, and a special subject database integrating collection, extraction, cleaning, quality inspection and warehousing is formed.

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