CN217932759U - Refined construction management control system based on BIM technology - Google Patents

Abstract

A refined construction management control system based on a BIM technology relates to the technical field of bridge construction, and comprises a three-dimensional visual collaborative management platform connected with a plurality of terminal signals. The three-dimensional visual collaborative management platform comprises a model storage module, a management module and a camera, wherein the model storage module is used for storing and calling model data, and a BIM (building information modeling) model and a real scene model are stored in the model storage module; the management module is used for displaying relevant documents of the construction process and managing the construction process, and is in signal connection with the model storage module; the camera is used for monitoring the construction site and is in signal connection with the management module. The three-dimensional visual collaborative management platform of the embodiment of the application effectively combines a construction site and a model, and can manage aspects such as technical quality, safety, progress and field monitoring in the construction process, so that the construction process can be finely managed on one platform.

Description

Refined construction management control system based on BIM technology

Technical Field

The application relates to the technical field of bridge construction, in particular to a refined construction management control system based on a BIM technology.

Background

The BIM technology is used for constructing a three-dimensional building model according to the collection of related data information, and simulating the actual engineering situation by fully utilizing a simulation function, so that help is provided for the development of engineering design and engineering management work. With the continuous development of scientific technology, the BIM technology is widely applied to various projects. At present, BIM technology is applied to design, construction and cost management of highway bridges.

Particularly for large-scale projects such as large-span steel truss arch bridges, construction procedures are converted more, working conditions are complex, and the traditional construction control method is difficult to realize fine management control on the construction process on one platform.

Disclosure of Invention

The embodiment of the application provides a refined construction management control system based on a BIM (building information modeling) technology, and aims to solve the problem of how to improve refined management of engineering construction by applying the BIM technology in the construction process.

The utility model provides a construction management control system that becomes more meticulous based on BIM technique which characterized in that, construction management control system that becomes more meticulous includes three-dimensional visual collaborative management platform, three-dimensional visual collaborative management platform and a plurality of terminal signal connection, three-dimensional visual collaborative management platform includes:

the model storage module is used for storing and calling model data, and the BIM model and the live-action model are stored in the model storage module;

the management module is used for displaying relevant documents of the construction process and managing the construction process, and is in signal connection with the model storage module;

and the camera is used for monitoring a construction site and is in signal connection with the management module.

Further, the management module comprises a document storage module for displaying relevant documents of the construction process.

Furthermore, the management module comprises a checking and recording module which is used for recording information such as checking batches, procedure card control and the like, and the checking and recording module is in signal connection with the model storage module.

Furthermore, the management module comprises a schedule progress module, an actual progress module and a progress analysis module, the schedule progress module is used for recording schedule progress, the actual progress module is used for recording actual progress, the progress analysis module is used for comparing and analyzing the schedule progress and the actual progress, and the schedule progress module and the actual progress module are respectively in signal connection with the progress analysis module.

Furthermore, the refined construction management control system also comprises a BIM modeling module used for establishing a BIM model, and the BIM modeling module is in signal connection with the model storage module;

the system also comprises a live-action modeling module which is used for establishing a live-action model according to the shot picture, and the live-action modeling module is in signal connection with the model storage module.

Furthermore, the refined construction management control system further comprises a form platform used for displaying a model, and the form platform is in signal connection with the BIM modeling module and the real scene modeling module respectively.

Furthermore, the refined construction management control system further comprises a parametric modeling module for batch modeling, and the parametric modeling module is in signal connection with the BIM modeling module.

Furthermore, the refined construction management control system further comprises an unmanned aerial vehicle device used for shooting pictures with GPS positioning information, and the unmanned aerial vehicle device is in signal connection with the real scene modeling module.

Further, the unmanned aerial vehicle device includes a compression module for carrying out lightweight processing on the picture.

Furthermore, the refined construction management control system further comprises a model calculation module for performing structural calculation on the BIM, and the model calculation module is in signal connection with the BIM modeling module.

The beneficial effect that technical scheme that this application provided brought includes:

the embodiment of the application provides a refined construction management control system based on a BIM technology, which comprises a three-dimensional visual collaborative management platform, wherein the three-dimensional visual collaborative management platform effectively combines a construction site with a BIM model and a real scene model. In the three-dimensional visual collaborative management platform, on the basis of the BIM technology, the technical quality, safety, progress, field monitoring and the like in the construction process can be managed through the management module and the camera monitoring, so that the construction process can be finely managed and comprehensively controlled on one platform.

In addition, the plurality of terminals can transmit relevant documents of the construction process to the three-dimensional visual collaborative management platform, and can also check and call model information and relevant documents of the construction process on the three-dimensional visual collaborative management platform.

Drawings

In order to more clearly illustrate the technical solutions in the embodiments of the present application, the drawings required to be used in the description of the embodiments are briefly introduced below, and it is obvious that the drawings in the description below are only some embodiments of the present application, and it is obvious for those skilled in the art to obtain other drawings without creative efforts.

FIG. 1 is a system architecture diagram according to an embodiment of the present application;

FIG. 2 is a block diagram of the management module shown in FIG. 1.

Reference numerals:

1. a three-dimensional visual collaborative management platform; 2. a model storage module; 3. a management module; 4. a camera; 5. a document storage module; 6. a checking and recording module; 7. a schedule module; 8. an actual progress module; 9. a progress analysis module; 10. a BIM modeling module; 11. a live-action modeling module; 12. a fork platform; 13. a parameterized modeling module; 14. an unmanned aerial vehicle device; 15. and a model calculation module.

Detailed Description

In order to make the objects, technical solutions and advantages of the embodiments of the present application clearer, the technical solutions in the embodiments of the present application will be clearly and completely described below with reference to the drawings in the embodiments of the present application, and it is obvious that the described embodiments are some embodiments of the present application, but not all embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present application.

The embodiment of the application provides a refined construction management control system based on a BIM (building information modeling) technology, which can solve the problem of how to apply the BIM technology to improve the refined management of engineering construction in the construction process.

As shown in fig. 1, a refined construction management control system based on the BIM technology includes a three-dimensional visual collaborative management platform 1, where the three-dimensional visual collaborative management platform 1 is in signal connection with a plurality of terminals, and specifically, the terminals may be web terminals or mobile terminals, or may be an app.

The three-dimensional visual collaborative management platform 1 comprises a model storage module 2, a management module and a camera 4. The model storage module 2 is used for storing and retrieving model data, and the model storage module 2 stores a BIM model and a real scene model. The management module 3 is used for displaying relevant documents of the construction process and managing the construction process, and the management module 3 is in signal connection with the model storage module 2. The camera 4 is used for monitoring the construction site, and the camera 4 is in signal connection with the management module 3.

Specifically, the camera 4 may be installed at various positions of a construction site, or may be installed at an important position, such as a bearing platform, a box girder, a pile foundation, etc., according to a construction requirement. The manager or the constructor can check the monitoring video shot by the camera 4 on the three-dimensional visual collaborative management platform 1.

Specifically, in the model storage module 2, in some embodiments, a model ontology may be stored, and in other embodiments, related data of the model, such as rod information in the model, modeling process information, model result information, and the like, may also be stored.

The three-dimensional visual collaborative management platform 1 in the embodiment of the application can directly read model data so as to facilitate main bridge calculation and visual bottoms of intersection. For the calculation amount of the main bridge, the manual work can extract the coating area of the steel structure of the main bridge, the weight of the rod piece, the quantity information of small components such as high-strength bolts, joint splicing plates and the like from the BIM model in the model storage module 2, and the information is used for guiding factory processing and site hoisting construction. For the visual intersection, a detail model of a complex node can be manually extracted from the BIM model in the model storage module 2, and visual intersection is performed on field technicians and operation teams, so that the technicians and the operation personnel can be helped to deeply understand the design intention and the construction process.

Further, as shown in fig. 2, the management module 3 includes a document storage module 5, and the document storage module 5 is used for displaying relevant documents of the construction process.

Specifically, a constructor or a manager can upload documents such as a relevant scheme, a drawing, a cross-reference book and the like to the document storage module 5, and enter the three-dimensional visual collaborative management platform 1 through a mobile phone, so that the inspection of the whole construction process and the construction technology can be realized. In addition, aiming at the safety or quality problems in the patrol, the manager can lift the patrol records with the description of characters and photos on the platform and push the patrol records to the responsible person for adjustment, thereby realizing the fine management control on the technical quality and the safety in the construction process.

Further, as shown in fig. 2, the management module 3 includes a checking and recording module 6, the checking and recording module 6 is used for recording information such as checking batches, process control cards and the like, and the checking and recording module 6 is in signal connection with the model data storage module. Specifically, the inspection lot, the process control card and the like are accurate to specific engineering positions, so that the trace of the card control process is realized, and the information of the inspection lot, the process control card and the like can be directly retrieved.

For the inspection batch, inspection batch folders are manually uploaded to the inspection recording module 6, and the inspection batch folders can be linked with specific parts of the BIM so as to be convenient for constructors or managers to look up. For process card control, process data are manually filled in the inspection recording module 6 and process card control files are generated, the process card control files are automatically associated with the BIM and are accurate to specific parts of the BIM, and therefore fine management control on technical quality and safety in the construction process is achieved.

Further, as shown in fig. 2, the management module 3 includes a scheduled progress module 7, an actual progress module 8, and a progress analysis module 9. The schedule progress module 7 is used for recording schedule progress, the actual progress module 8 is used for recording actual progress, the progress analysis module 9 is used for comparing and analyzing the schedule progress and the actual progress, and the schedule progress module 7 and the actual progress module 8 are respectively in signal connection with the progress analysis module 9.

Specifically, the constructor or manager manually inputs the planned progress in the planned progress module 7, and fills the actual progress in the actual progress module 8 in real time, and the progress analysis module 9 can compare and analyze the relevant data of the planned progress and the actual progress, and can label and display different colors in advance, normal and delayed different situations.

Further, as shown in fig. 1, the refined construction management control system according to the embodiment of the present application further includes a BIM modeling module 10 and a real scene modeling module 11. The BIM modeling module 10 is used for building a BIM model, and the BIM modeling module 10 is in signal connection with the model storage module 2. Specifically, the BIM modeling module 10 may use Tekla as a primary modeling tool. The live-action modeling module 11 is used for establishing a live-action model according to the shot picture, and the live-action modeling module 11 is in signal connection with the model storage module 2.

Specifically, after the entity model is built by the BIM modeling module 10, the entity model is read by the model storage module 2 in the three-dimensional visual collaborative management platform 1. Similarly, after the real-scene modeling module 11 establishes the real-scene model, the model storage module 2 in the three-dimensional visual collaborative management platform 1 reads the real-scene model.

In the BIM modeling module 10, a manual work can deduce schemes of different members according to a construction drawing and a real-scene model, so as to realize optimization of the construction scheme and the site layout. In addition, when the steel beam is manufactured, the BIM model can generate processing parameters and drawing information, and the processing quality and efficiency of the project on the main bridge complex rod piece are improved. Meanwhile, constructors can adopt a total station instrument to check the pre-assembly of the rod pieces in the processing plant, and the manufacturing precision is improved.

In this embodiment, the refined construction management control system further includes a rendering module, where the rendering module is configured to render the BIM model, and the rendering module is in signal connection with the BIM modeling module 10. Optionally, the rendering module may use Lumion as a rendering tool.

Furthermore, the refined construction management control system of the embodiment of the application further comprises a form platform 12, wherein the form platform 12 is used for displaying the model, and the form platform 12 is in signal connection with the BIM modeling module 10 and the live-action modeling module 11 respectively.

Specifically, on the form platform 12, the BIM model and the live-action model can be displayed in three dimensions, so that a constructor or a manager can check and compare the two models from multiple angles, and the BIM modeling module 10 or the live-action modeling module 11 does not need to be opened independently, thereby improving the working efficiency.

Further, the refined construction management control system of the embodiment of the application further includes a parametric modeling module 13, and the parametric modeling module 13 is used for batch modeling. In particular, RHINO can be the main parametric modeling tool. The parametric modeler module 13 is in signal connection with the BIM modeler module 10. The parameterized modeling module 13 can also realize batch modeling of part of similar rod pieces, thereby improving the efficiency of building the BIM model.

Further, the refined construction management control system of the embodiment of the application further includes an unmanned aerial vehicle device 14 for shooting a picture with GPS positioning information, and the unmanned aerial vehicle device 14 is in signal connection with the real-scene modeling module 11.

Specifically, a picture with GPS positioning information is obtained by aerial photography using the unmanned aerial device 14, and is transmitted to the live-action modeling module 11, and the live-action modeling module 11 generates a live-action model. The real-scene model has complete geographical positioning, and can realize topographic analysis functions such as distance, area and volume measurement, so as to guide a field planning scheme and guide accurate positioning of large-scale temporary facilities.

Furthermore, the unmanned aerial vehicle device 14 includes a compression module for performing a light-weight process on the picture, so that the storage space occupied by the data can be reduced without reducing the data content, thereby achieving light weight.

Further, the refined construction management control system in the embodiment of the application further includes a model calculation module 15, the model calculation module 15 is used for performing structural calculation on the BIM model, and the model calculation module 15 is in signal connection with the BIM modeling module 10.

Specifically, the computing interface realizes the butt joint of the BIM model data and the model computing module 15, and reduces the workload of repeated modeling of the structural checking calculation and the large temporary structural design of the project in the construction scheme. Alternatively, the model calculation module 15 may be madas a main calculation tool.

Taking a certain bridge in the construction process of the applicant as an example, the implementation process of the embodiment of the application is introduced:

the total length of a certain bridge is about 2.754 kilometers, the main bridge is a three-span continuous steel truss tied arch bridge with a main span of 408m, the span-to-main span ratio is 1. Meanwhile, in order to consider the landscape, the lower chord of the main span is not provided with longitudinal and parallel connections, and a wind brace is arranged between every four sections. The total amount of the steel structure reaches 3 ten thousand tons, and the steel structure has the characteristics of complex structural stress, large construction scale, large technical difficulty, high safety risk, high quality requirement and the like. The bridge spans across sharp bends of river channels, large banks and urban main roads, the construction environment is complex, and water transportation is greatly influenced by seasonal water level changes of Hanjiang. And the bridge is adjacent to the water intake place of the water works, the requirement on environmental protection is high, and the north approach bridge spans the urban trunk road and passes through the light rail line. Therefore, the bridge has the advantages of more construction external restriction conditions, large construction safety risk, large traffic relief influence range, long duration, more pipeline moving and changing, large sign and tear difficulty, large external coordination workload and large construction disturbance complaint risk.

Aiming at the engineering characteristics and the construction surrounding environment condition of the bridge, the refined construction management control system of the embodiment of the application is adopted to assist the engineering construction, tekla is taken as a main modeling tool, and a form platform 12 capable of displaying the model is established by means of a rhinoceros RHINO parameterized modeling module 13, a Lumion rendering module, an unmanned aerial vehicle device 14 and a realistic modeling module 11. In addition, a three-dimensional visual collaborative management platform 1 is established, and interconnection and information sharing among elements such as technical quality management, safety management, progress management, field monitoring management and the like are achieved.

In the description of the present application, it should be noted that the terms "upper", "lower", and the like indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, which are merely for convenience of describing the present application and simplifying the description, but do not indicate or imply that the referred device or element must have a specific orientation, be configured and operated in a specific orientation, and thus, should not be construed as limiting the present application. Unless expressly stated or limited otherwise, the terms "mounted," "connected," and "connected" are intended to be inclusive and mean, for example, that they may be fixedly connected, detachably connected, or integrally connected; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meaning of the above terms in the present application can be understood by those of ordinary skill in the art as the case may be.

It is noted that, in this application, relational terms such as "first" and "second," and the like, are used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Also, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus. Without further limitation, an element defined by the phrases "comprising a," "8230," "8230," or "comprising" does not exclude the presence of additional like elements in a process, method, article, or apparatus that comprises the element.

The above description is merely exemplary of the present application and is presented to enable those skilled in the art to understand and practice the present application. Various modifications to these embodiments will be readily apparent to those skilled in the art, and the generic principles defined herein may be applied to other embodiments without departing from the spirit or scope of the application. Thus, the present application is not intended to be limited to the embodiments shown herein but is to be accorded the widest scope consistent with the principles and novel features disclosed herein.

Claims (10)

1. A construction management control system that becomes more meticulous based on BIM technique, its characterized in that, the construction management control system that becomes more meticulous includes three-dimensional visual collaborative management platform (1), three-dimensional visual collaborative management platform (1) and a plurality of terminal signal connection, three-dimensional visual collaborative management platform (1) includes:

the model storage module (2) is used for storing and calling model data, and the model storage module stores a BIM (building information modeling) model and a real scene model;

the management module (3) is used for displaying relevant documents of the construction process and managing the construction process, and the management module (3) is in signal connection with the model storage module (2);

the camera (4) is used for monitoring a construction site, and the camera (4) is in signal connection with the management module (3).

2. The refined construction management control system based on the BIM technology as claimed in claim 1, wherein: the management module comprises a document storage module (5) used for displaying relevant documents of the construction process.

3. The refined construction management control system based on the BIM technology as claimed in claim 1, wherein: the management module comprises a checking and recording module (6) for recording checking batch and process card control information, and the checking and recording module (6) is in signal connection with the model storage module (2).

4. The refined construction management control system based on the BIM technology as claimed in claim 1, wherein: the management module comprises a planned progress module (7), an actual progress module (8) and a progress analysis module (9), the planned progress module (7) is used for recording planned progress, the actual progress module (8) is used for recording actual progress, the progress analysis module (9) is used for comparing and analyzing the planned progress and the actual progress, and the planned progress module (7) and the actual progress module (8) are respectively in signal connection with the progress analysis module (9).

5. The refined construction management control system based on the BIM technology as claimed in claim 1, wherein: the refined construction management control system also comprises a BIM modeling module (10) used for establishing a BIM model, and the BIM modeling module (10) is in signal connection with the model storage module (2);

the system also comprises a live-action modeling module (11) for establishing a live-action model according to the shot picture, wherein the live-action modeling module (11) is in signal connection with the model storage module (2).

6. The refined construction management control system based on the BIM technology as claimed in claim 5, wherein: the refinement construction management control system further comprises a form platform (12) used for displaying a model, wherein the form platform (12) is in signal connection with the BIM modeling module (10) and the live-action modeling module (11) respectively.

7. The refined construction management control system based on the BIM technology as claimed in claim 5, wherein: the refined construction management control system further comprises a parametric modeling module (13) used for batch modeling, and the parametric modeling module (13) is in signal connection with the BIM modeling module (10).

8. The refined construction management control system based on the BIM technology as claimed in claim 5, wherein: the fine construction management control system further comprises an unmanned aerial vehicle device (14) for shooting pictures with GPS positioning information, and the unmanned aerial vehicle device (14) is in signal connection with the real scene modeling module (11).

9. The refined construction management control system based on the BIM technology as claimed in claim 8, wherein: the unmanned aerial vehicle device includes the compression module that is used for carrying out lightweight processing to the picture.

10. The refined construction management control system based on the BIM technology as claimed in claim 6, wherein: the fine construction management control system further comprises a model calculation module (15) used for carrying out structural calculation on the BIM, and the model calculation module (15) is in signal connection with the BIM modeling module (10).

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