CN113656868A - BIM technology-based hospital construction collaborative management platform - Google Patents
BIM technology-based hospital construction collaborative management platform Download PDFInfo
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Abstract
The application relates to a hospital construction collaborative management platform based on BIM technique relates to construction technical field, aims at solving BIM technique and is being applied to hospital construction in-process, and it is more to participate in the construction side, can't improve the technical problem of construction efficiency, and it includes: the cloud server is used for storing the BIM software and the three-dimensional model and receiving data sent by the mobile terminal; a model conversion module for converting an actual building element into a virtual three-dimensional model; the collaborative modeling module is used for receiving building model data which are built by each mobile terminal based on the three-dimensional model; the collaborative management module is used for sending the modified building model data and the management data to each mobile terminal; and the data display module is connected with the cooperative management module and is used for displaying the building model data and the management data on the mobile terminal. The method and the device have the effects that multiple parties cooperate in modeling and management through cloud computing, and the building cooperation efficiency is remarkably improved.
Description
Technical Field
The application relates to the field of building construction, in particular to a hospital construction collaborative management platform based on a BIM technology.
Background
Building Information Model (BIM) is a new tool in architecture, engineering and civil engineering, and with the development of intelligent progress, the BIM technology is widely applied.
In the related art, chinese patent publication No. CN107292042A discloses a BIM modeling method, which includes: obtaining a building skin to a CATIA platform; dividing and numbering the building surface; establishing design rules of the section bar model diagram; establishing a standard component; testing and modifying the standard part; integrally generating a model according to the standard component; and generating a corresponding machining diagram and a machining list according to the model. The BIM modeling method is standardized, simple and convenient to use, and can be used for dividing and marking the surface, so that the position can be quickly confirmed when modification is needed, and the modification is very convenient.
In view of the above-mentioned related technologies, the BIM technology has not only made a great progress in the building field, but also applied to a plurality of fields; the BIM modeling method can only be used for modeling the building model in the building process, and the inventor thinks that the BIM technology has the defects that the building participation is more and the building efficiency cannot be improved when the BIM technology is applied to the hospital building process.
Disclosure of Invention
In order to improve the efficiency of hospital construction, the application provides a hospital construction collaborative management platform based on the BIM technology.
The application provides a hospital construction collaborative management platform based on BIM technique adopts following technical scheme:
a hospital construction collaborative management platform based on BIM technology includes:
the cloud server is used for storing the BIM software and the three-dimensional model and receiving data sent by the mobile terminal;
the model conversion module is carried on the cloud server and used for converting an actual building component into a virtual three-dimensional model;
the collaborative modeling module is connected with the model conversion module and used for receiving building model data built by each mobile terminal based on the three-dimensional model;
the collaborative management module is connected with the collaborative modeling module and used for sending modified building model data and management data to each mobile terminal, wherein the management data at least comprises environmental information, construction progress, quality problems and document data; and the number of the first and second groups,
and the data display module is connected with the cooperative management module and is used for displaying the building model data and the management data on the mobile terminal.
By adopting the technical scheme, each responsibility main body of the building converts the building component into the three-dimensional model through the model conversion module, constructs the building model on the cloud server through the collaborative modeling module, edits and modifies the building model through the collaborative management module, and displays the building model through the data display module.
Preferably, the cooperation management module includes:
the system comprises an environment monitoring module, a data processing module and a data processing module, wherein the environment monitoring module is used for acquiring sensor data arranged at each position of a construction site to form environment data;
the progress updating module is used for adding a three-dimensional model on the original building model data based on the building construction progress so as to update the building model;
the safety supervision module is used for establishing a quality problem form of safety supervision according to the construction patrol condition; and the number of the first and second groups,
and the document management module is used for storing files required in the construction process for the mobile terminal to access.
By adopting the technical scheme, each party responsibility main body can monitor the environmental data of the construction site through the environment monitoring module in the cooperative management and update the construction progress in real time through the progress updating module, can monitor the potential safety hazard problem discovered by inspection personnel in the construction process through the safety supervision module, and can store the safety standard, policy regulation, reinforcing method and various data required to be used in the construction process through the document management module.
Preferably, the environment monitoring module includes:
the environment data acquisition module is used for acquiring foundation pit data, meteorological data and geological data of a construction environment;
the environment data analysis module is connected with the environment data acquisition module and used for measuring and calculating collapse probability according to the foundation pit data, the meteorological data and the geological data;
and the foundation pit reinforcing suggestion module is connected to the environmental data analysis module and used for sending the foundation pit reinforcing suggestion to the mobile terminal based on the environmental data when the collapse probability is greater than the warning value.
By adopting the technical scheme, the foundation pit is the foundation of building construction, and great danger is generated on the building site if the foundation pit collapses under the comprehensive action of environmental factors, so that the environmental data is collected by the environmental data collection module in the environmental monitoring module, the collapse probability is measured and calculated by the environmental data analysis module, and the foundation pit reinforcement suggestion module is used for retrieving the reinforcement method when the probability exceeds the preset value, so that a constructor can conveniently refer to the foundation pit and reinforce the foundation pit.
Preferably, the environment data analysis module includes:
the boundary analysis module is connected with the environment data acquisition module and used for calculating the collapse probability of each side of the foundation pit according to the foundation pit data, the meteorological data and the geological data;
the probability early warning module is connected with the boundary analysis module and used for marking different colors on the boundary according to the collapse probability, the boundary with the collapse probability exceeding the warning value is marked as red, and the boundary with the collapse probability lower than the preset value is marked as blue;
and the risk early warning module is connected with the probability early warning module and used for storing and sending the foundation pit state of the red mark to each mobile terminal.
By adopting the technical scheme, because geological environments on four sides of the foundation pit possibly have differences, the probability of collapse of each boundary is analyzed through the boundary analysis module, and the probability early warning module marks the collapse probability to be red when the collapse probability exceeds a preset value and gives an alarm through the risk early warning module, so that early warning is carried out on the cloud platform, and the foundation pit reinforcement is guaranteed to be implemented in time.
Preferably, the foundation pit reinforcement suggestion module includes:
the keyword selection module is connected to each edge analysis module and used for selecting keywords when the collapse probability exceeds a preset value;
the method retrieval module is connected with the keyword selection module and used for retrieving foundation pit reinforcement suggestions in the database according to the keywords;
and the suggestion sending module is connected with the method retrieval module and used for sending the foundation pit reinforcing suggestions obtained by retrieval to each mobile terminal.
By adopting the technical scheme, the keyword selection module in the foundation pit reinforcement suggestion module can select and take out the keywords in the environmental parameters when the probability of the foundation pit exceeds the preset value, and the method retrieval module retrieves in the database based on the selected keywords, so that the reinforcement method suitable for the current environment is retrieved and is sent to each responsibility main body through the suggestion sending module, and a construction party can conveniently consult the reinforcement method to perform foundation pit reinforcement in time.
Preferably, the keyword selection module includes:
the foundation pit analysis module is used for determining the type of the foundation pit according to the foundation pit data so as to determine the key words of the foundation pit;
the geological analysis module is used for determining geological types according to geological data so as to determine geological keywords;
and the weather analysis module is used for determining weather conditions according to the weather data so as to determine weather keywords.
By adopting the technical scheme, the foundation pit analysis module is used for analyzing the foundation pit data so as to select the key words related to the foundation pit, the geological analysis module is used for selecting the key words related to the geology according to the geological data, the weather analysis module determines the weather condition based on the meteorological data and selects the meteorological key words so as to provide the multidimensional key words of the environmental data, and therefore the method retrieval is convenient to carry out.
Preferably, the method retrieval module comprises:
the keyword combination module is connected to the keyword selection module and used for combining all the keywords to obtain a combination result;
the combined retrieval module is connected with the keyword combined module and used for retrieving a reinforcement method in the database by taking the combined result as a retrieval basis;
and the repeated removing module is connected with the combined retrieval module and is used for removing the repeated reinforcement method.
By adopting the technical scheme, the method retrieval module carries out arrangement and combination of a plurality of keywords through the keyword combination module and carries out retrieval one by one through the combination retrieval module, so that the retrieval range is fully expanded, all related reinforcement methods can be covered by retrieval, and the repeated elimination module can eliminate repeated reinforcement methods in the reinforcement methods, so that the repeated reinforcement methods are reduced, and the reference efficiency is improved.
Preferably, the combination retrieval module includes:
the combined sorting module is connected with the keyword combined module and used for arranging the number of the keywords in the combined result according to a sequence from more keywords to less keywords;
and the sequence retrieval module is connected with the combination sorting module and is used for sequentially retrieving the combination results according to the arranged sequence.
By adopting the technical scheme, the combined results can be sorted according to the number of the keywords through the combined sorting module in the combined retrieval module, the sequential retrieval module retrieves according to the sorted combined results, and naturally obtained results can be also sorted sequentially according to the number of the keywords.
Preferably, the duplicate elimination module includes:
the method sorting module is connected with the sequential retrieval module and used for sorting the retrieved reinforced methods and marking keywords adopted in retrieval;
and the selection and elimination module is connected with the method sorting module and used for selecting the reinforcement method with the most keywords in the repeated reinforcement methods and eliminating the remaining repeated reinforcement methods.
By adopting the technical scheme, the method sorting module can sort the combined results again according to the number of the keywords, and the number of the keywords is marked after the retrieved reinforcement method is used; and when finding the repeated reinforcement method, the selective elimination module preferentially selects the reinforcement method with the most keywords and eliminates the rest reinforcement methods, so that the repeated reinforcement methods are reduced, and the most keywords contained in the reinforcement method can be reserved.
Preferably, the method retrieval module further comprises:
the relevancy grading module is connected with the combined retrieval module and is used for grading the relevancy according to the number of the keywords;
and the association degree marking module is connected with the association degree grading module and used for assigning the corresponding association degree to the reinforcement method corresponding to the target combination result.
By adopting the technical scheme, the relevancy degree grading module can grade the relevancy degree of the reinforcement method and the current foundation pit based on different keyword numbers, and the relevancy degree marking module can mark the relevancy degree corresponding to the reinforcement algorithm based on the keyword numbers, so that a construction party can preferentially match the reinforcement method with the most keywords.
In summary, the present application includes at least one of the following beneficial technical effects:
1. by adopting the technology of matching the cloud server, the model conversion module, the collaborative modeling module, the collaborative management module and the data display module, the building construction efficiency is obviously improved;
2. by adopting the technology of matching the collaborative management module, the environment monitoring module, the data acquisition module, the environment data analysis module, the boundary analysis module, the probability early warning module, the color marking module, the risk early warning module, the foundation pit reinforcement suggestion module, the progress updating module, the safety supervision module, the data management module, the document management module, the keyword selection module, the foundation pit analysis module, the geological analysis module and the meteorological analysis module, the foundation pit collapse probability piece can be conveniently predicted, and the collapse risk can be reduced.
3. By adopting the technology of matching the method retrieval module, the keyword combination module, the combination retrieval module, the combination sorting module, the sequence retrieval module, the repeated elimination module, the method sorting module, the selection elimination module, the association degree grading module, the association degree marking module, the suggestion sending module and the data display module, the reinforcement method can be matched conveniently when the collapse probability of the foundation pit is greater than the warning value, and the reference effect of a construction party is facilitated.
Drawings
FIG. 1 is a structural block diagram of a hospital construction collaborative management platform based on BIM technology in the embodiment of the present application;
FIG. 2 is a block diagram of a structure for exposing a collaboration management module in an embodiment of the present application;
FIG. 3 is a block diagram of an environment monitoring module for displaying in an embodiment of the present application;
FIG. 4 is a structural block diagram of a module for presenting foundation pit reinforcement suggestions in an embodiment of the present application;
FIG. 5 is a block diagram of a method retrieval module for presenting in an embodiment of the present application.
Description of reference numerals: 1. a cloud server; 2. a model conversion module; 3. a collaborative modeling module; 4. a collaborative management module; 41. an environment monitoring module; 411. a data acquisition module; 412. an environmental data analysis module; 4121. a boundary analysis module; 4122. a probability early warning module; 4123. a risk early warning module; 413. a foundation pit reinforcement suggestion module; 42. a progress update module; 43. a safety supervision module; 44. a data management module; 45. a document management module; 46. a keyword selection module; 461. a foundation pit analysis module; 462. a geological analysis module; 463. a weather analysis module; 47. a method retrieval module; 471. a keyword combination module; 472. a combined retrieval module; 4721. a combined sorting module; 4722. a sequential retrieval module; 473. a repeated elimination module; 4731. a method sorting module; 4732. selecting a rejecting module; 474. a relevancy grading module; 475. a relevancy marking module; 48. a suggestion sending module; 5. and a data display module.
Detailed Description
The present application is described in further detail below with reference to figures 1-5.
The embodiment of the application provides a hospital construction collaborative management platform based on BIM technology, and above-mentioned platform is built promptly at the initial stage of hospital establishment, and the participation construction side includes hospital, health and welfare commission, undertaking construction side, supervision side and people's government. All parties need to master the progress of hospital construction and manage and control risks possibly generated in the construction process. The contractor also comprises a plurality of subcontractors, and in the process of hospital construction, coordination and communication among multiple parties are needed.
The embodiment of the application discloses a hospital construction collaborative management platform based on the BIM technology. Referring to fig. 1, the BIM technology-based hospital construction collaborative management platform includes a cloud server 1, a model conversion module 2, a collaborative modeling module 3, a collaborative management module 4, and a data display module 5. Wherein:
the cloud server 1 is mounted on the cloud and accessed through the internet. The BIM software and the three-dimensional model are stored in the cloud server 1, and a plurality of accounts can log in and receive data sent by the mobile terminal in the using process, so that the BIM software on the cloud server 1 can be edited and modified by the mobile terminals.
The model conversion module 2 is mounted on the cloud server 1, and the model conversion module 2 can convert an actual building component into a virtual three-dimensional model based on the size, shape and structure of the actual component and the scaling ratio of the three-dimensional model to the actual component in the using process, so that each mobile terminal can edit and modify the three-dimensional model on the cloud server 1 in real time and synchronously through the BIM.
The collaborative modeling module 3 is connected to the model conversion module 2, the mobile terminals call the three-dimensional models in the model conversion module 2 through the collaborative modeling module 3, each mobile terminal builds building model data on BIM software based on the three-dimensional models and displays the building model data on each mobile terminal in real time, and the multiple mobile terminals can model the parts responsible for the mobile terminals to the cloud server 1 so as to share and access the other mobile terminals.
The collaborative management module 4 is connected to the collaborative modeling module 3, and the collaborative management module 4 sends the modified building model data and the management data to each mobile terminal. The mobile terminal accesses the cloud server 1 when receiving the modified building model data, can look up the building model on the cloud server 1 in real time, and can see the modified part by comparing the historical building models. Meanwhile, the cooperation management module 4 can send management data to the mobile terminal, the management data at least including environment information, construction progress, quality problems, and document data.
The data display module 5 is connected with the cooperative management module 4; the data display module 5 displays the building model data and the management data on the mobile terminal when the mobile terminal accesses the cloud server 1, so that all the parties in hospital construction can participate in the mobile terminal in a cooperative manner, and the communication efficiency is improved.
Referring to fig. 2, the collaboration management module 4 includes, among other things, an environment monitoring module 41, a progress updating module 42, a security supervision module 43, a data management module 44, and a document management module 45. The environment monitoring module 41 includes pressure sensors, displacement sensors, and tension sensors distributed around the foundation pit. Meanwhile, the surveyor of the construction can input the basic situation of the foundation pit, the underground water situation, the geological situation and the hydrological situation periodically through the environment monitoring module 41. In addition, the environment monitoring module 41 is connected to the internet to periodically acquire meteorological data published on the internet as a reference basis for judgment.
The progress updating module 42 is connected to the model conversion module 2 and the collaborative modeling module 3; and the progress updating module 42 receives and stores the data modified by the mobile terminal aiming at the building model, and realizes that a three-dimensional model is added on the original building model data based on the building construction progress so as to update the building model. After the target mobile terminal completes updating a part of the building model, the progress updating module 42 sends the updated building model to other mobile terminals.
The document management module 45, during the construction process, the safety supervision department needs a certain emergency plan to deal with the emergency situation, and the constructor needs to store the policy files and the solution for the possible problems. The document management module 45 is used for storing the files required in the construction process for the access of the mobile terminal, so that the files are convenient to consult.
Referring to fig. 3, the environment monitoring module 41 includes an environment data collecting module 411, an environment data analyzing module 412 and a foundation pit reinforcement suggesting module 413. The environmental data collection module 411 has a main function of collecting reference parameters of a construction environment, and the reference parameters at least include foundation pit data, meteorological data and geological data. Wherein the foundation pit data is confirmed through the data of sensor and reconnaissance personnel input that distribute in the foundation pit, and the foundation pit data includes: the size of the foundation pit, the range of the supporting force and the flow rate of drainage; the meteorological data has the environmental data acquisition module 411 to obtain through visiting the internet, and the meteorological data includes: days of rainfall, wind speed and wind direction; and the geological data is derived from data which is regularly surveyed and input by a surveying staff, and comprises soil property type, soil mobility and vegetation coverage.
The environmental data analysis module 412 is connected to the environmental data acquisition module 411, and after the environmental data analysis obtains foundation pit data, meteorological data and geological data, the data are input into the multi-factor prediction model, and the collapse probability is measured and calculated through the multi-factor prediction model, so that the probability of collapse possibly occurring under the future meteorological conditions is predicted.
The environmental data analysis module 412 includes a boundary analysis module 4121, a probability pre-warning module 4122, and a risk pre-warning module 4123. Wherein, the boundary analysis module 4121 is connected to the environmental data collection module 411; since the environments of the sides of the foundation pit may be different, the boundary analysis module 4121 calculates the collapse probability of each side of the foundation pit according to the foundation pit data, the meteorological data, and the geological data, respectively.
The probability early warning module 4122 is connected to each edge analysis module, and when the collapse probability of each boundary is measured by the boundary analysis module 4121, the probability early warning module 4122 calculates the specific gravity of red and blue in the boundary marker according to the collapse probability, if the collapse probability is higher than the warning value, the boundary of the foundation pit is marked as red, if the collapse probability is lower than the preset value, the boundary of the foundation pit is marked as blue, and if the collapse probability is between the warning value and the preset value, the boundary of the foundation pit is marked as yellow.
The risk early warning module 4123 is connected to the probability early warning module 4122, and the risk early warning module 4123 stores and sends the foundation pit state corresponding to the red label to each mobile terminal when the collapse probability is higher than the warning value, so that each mobile terminal can timely obtain the area where the collapse is likely to occur, and timely take countermeasures.
The foundation pit reinforcing suggestion module 413 is connected to the environment data analysis module 412, a collapse probability early warning threshold value is arranged in the foundation pit reinforcing suggestion module 413, and when the collapse probability is larger than a warning value, the foundation pit reinforcing suggestion module 413 retrieves a foundation pit reinforcing method based on the environment data and sends a foundation pit reinforcing suggestion to the mobile terminal. The environmental data includes pit data, meteorological data, and geological data.
Referring to fig. 4, the foundation pit reinforcement suggestion module 413 specifically includes a keyword selection module 46, a method retrieval module 47, and a suggestion sending module 48. The keyword selection module 46 is connected to each edge analysis module, and when the collapse probability exceeds a preset value, the keyword selection module 46 selects a keyword in the environmental data corresponding to the boundary.
The keyword selection module 46 specifically includes a foundation pit analysis module 461, a geological analysis module 462, and a meteorological analysis module 463. The foundation pit analysis module 461 determines foundation pit keywords according to the foundation pit data and the foundation pit type, wherein the foundation pit keywords include a special foundation pit, a first-level foundation pit, a second-level foundation pit and a third-level foundation pit.
And the geological analysis module 462 determines the geological category according to geological data based on the classification of the prospecting personnel in the geological prospecting process, so as to determine the geological key words. Geological keywords include soft soil, general soil, hard soil, gravel hard soil, soft stones, sub-hard stones, extra hard stones, surface water flow, soil mobility, and vegetation coverage.
And a weather analysis module 463, configured to determine weather conditions according to the weather data, so as to determine weather keywords. Weather keywords include: continuous rainfall.
The method retrieval module 47 is connected to the keyword selection module 46, and since the reinforcing method is stored in the cloud server 1 in advance and forms a database, the method retrieval module 47 retrieves the foundation pit reinforcing suggestion in the database according to the keyword, so that a construction party can access the foundation pit reinforcing suggestion through the mobile terminal for reference.
And the suggestion sending module 48 is connected to the method retrieving module 47 and is used for sending the retrieved foundation pit reinforcement suggestions to each mobile terminal, and displaying the ordered reinforcement methods and the corresponding association degrees of the reinforcement methods on the mobile terminals, so that a construction party can conveniently refer to the foundation pits and adopt a proper reinforcement method to reinforce the foundation pits.
Referring to fig. 5, the method retrieving module 47 specifically includes a keyword combination module 471, a combination retrieving module 472, a repeated rejecting module 473, an association degree grading module 474 and an association degree marking module 475, where the keyword combination module 471 is connected to the keyword selecting module 46, and is configured to arrange and combine all selected keywords to obtain a combination result, so as to maximize a range of the retrieval result as much as possible.
The combination retrieval module 472 is connected to the keyword combination module 471, and configured to retrieve the combined result after the permutation and combination as a retrieval basis in the database to obtain a reinforcement method, so that the reinforcement method obtained by the retrieval is as comprehensive as possible.
The combination retrieval module 472 specifically includes a combination ranking module 4721 and a sequence retrieval module 4722, wherein the combination ranking module 4721 is connected to the keyword combination module 471. The combination ranking module 4721 ranks the number of keywords in the combined result in order from most to least, so that the combined result with the largest number of keywords in the combined result is ranked at the top, and the combined result with one keyword is ranked at the bottom.
The sequential retrieval module 4722 is connected to the combination ranking module 4721, and the sequential retrieval module 4722 sequentially retrieves the combination results in the order after the combination results are arranged, and sequentially arranges the reinforcement method documents after the combination results are retrieved.
The duplicate elimination module 473 is connected to the sequential retrieval module 4722 in the combined retrieval module 472 and is configured to eliminate duplicate reinforcement method files, thereby reducing the problem of document duplication caused by retrieval. Wherein the repeat culling module 473 specifically includes a method sort module 4731 and a selection culling module 4732.
A method sorting module 4731 connected to the sequential searching module 4722 and used for sorting the reinforcing methods obtained by searching according to the searching sequence and marking the keywords adopted in searching after the reinforcing methods.
And the selective elimination module 4732 is connected with the method sorting module 4731 and is used for selecting the reinforcement method with the most keywords in the repeated reinforcement methods and eliminating the remaining repeated reinforcement methods, so that repeated reinforcement method files generated in the retrieval process are greatly reduced.
An association degree ranking module 474 connected to the combined search module 472 for ranking the association degree according to the number of the keywords; for example, if 10 keywords are searched for, the association degree of the combination result including all 10 keywords is 100%, and the association degree of the combination result including 1 keyword is 10%.
The relevancy marking module 475 is connected to the relevancy ranking module 474, and configured to assign the corresponding relevancy to the reinforcement method corresponding to the target combination result, that is, each reinforcement method is assigned with the relevancy corresponding to the combination result.
The implementation principle of the hospital construction collaborative management platform based on the BIM technology in the embodiment of the application is as follows:
in the hospital construction process, a building side converts a building component into a three-dimensional model through a model conversion module 2, and builds a building model on a cloud server 1 through a collaborative modeling module 3 based on BIM software. And other construction parties and supervision parties can modify, check and budget the construction modules through the mobile terminal and the cooperative management module 4, so that the circulation time of drawings among different responsibility subjects is saved, and the cooperative management efficiency of construction is improved.
The above embodiments are preferred embodiments of the present application, and the protection scope of the present application is not limited by the above embodiments, so: all equivalent changes made according to the structure, shape and principle of the present application shall be covered by the protection scope of the present application.
Claims (10)
1. The utility model provides a hospital construction collaborative management platform based on BIM technique which characterized in that includes:
the cloud server (1) is used for storing the BIM software and the three-dimensional model and receiving data sent by the mobile terminal;
a model conversion module (2) which is mounted on the cloud server (1) and converts an actual building component into a virtual three-dimensional model;
the collaborative modeling module (3) is connected to the model conversion module (2) and is used for receiving building model data built by each mobile terminal based on the three-dimensional model;
the collaborative management module (4) is connected with the collaborative modeling module (3) and is used for sending modified building model data and management data to each mobile terminal, and the management data at least comprises environmental information, construction progress, quality problems and document data; and the number of the first and second groups,
and the data display module (5) is connected with the cooperative management module (4) and is used for displaying the building model data and the management data on the mobile terminal.
2. The BIM technology-based hospital construction collaborative management platform according to claim 1, wherein the collaborative management module (4) comprises:
an environmental monitoring module (41) for acquiring sensor data arranged at various locations on a construction site to form environmental data;
a progress updating module (42) for adding a three-dimensional model to the original building model data based on the construction progress to update the building model;
the safety supervision module (43) is used for establishing a quality problem form of safety supervision according to the construction patrol condition; and the number of the first and second groups,
and the document management module (45) is used for storing files required in the construction process for the access of the mobile terminal.
3. The BIM technology-based hospital construction collaborative management platform according to claim 2, wherein the environment monitoring module (41) comprises:
the environment data acquisition module (411) is used for acquiring foundation pit data, meteorological data and geological data of a construction environment;
the environment data analysis module (412) is connected to the environment data acquisition module (411) and used for measuring and calculating collapse probability according to the foundation pit data, the meteorological data and the geological data;
and the foundation pit reinforcing suggestion module (413) is connected to the environmental data analysis module (412) and is used for sending the foundation pit reinforcing suggestion to the mobile terminal based on the environmental data when the collapse probability is greater than the warning value.
4. The BIM technology-based hospital construction collaborative management platform according to claim 3, wherein the environmental data analysis module (412) comprises:
the boundary analysis module (4121) is connected to the environment data acquisition module (411) and used for calculating collapse probability of each side of the foundation pit according to the foundation pit data, the meteorological data and the geological data;
the probability early warning module (4122) is connected with the boundary analysis module (4121) and is used for marking different colors on the boundary according to the collapse probability, the boundary with the collapse probability exceeding the warning value is marked as red, and the boundary with the collapse probability lower than the preset value is marked as blue;
and the risk early warning module (4123) is connected with the probability early warning module (4122) and used for storing and sending the foundation pit state marked by the red color to each mobile terminal.
5. The BIM technology-based hospital construction collaborative management platform according to claim 3, wherein the foundation pit reinforcement suggestion module (413) comprises:
the keyword selection module (46) is connected to each edge analysis module and is used for selecting keywords when the collapse probability exceeds a preset value;
the method retrieval module (47) is connected with the keyword selection module (46) and used for retrieving foundation pit reinforcement suggestions in the database according to the keywords;
and the suggestion sending module (48) is connected to the method retrieval module (47) and is used for sending the retrieved foundation pit reinforcement suggestion to each mobile terminal.
6. The BIM technology-based hospital construction collaborative management platform according to claim 5, wherein the keyword extraction module (46) comprises:
the foundation pit analysis module (461) is used for determining the foundation pit type according to the foundation pit data so as to determine the key words of the foundation pit;
a geological analysis module (462) for determining geological categories from the geological data, thereby determining geological keywords;
and a weather analysis module (463) for determining weather conditions from the weather data, thereby determining weather keywords.
7. The BIM technology-based hospital construction collaborative management platform according to claim 6, wherein the method retrieval module (47) comprises:
the keyword combination module (471) is connected to the keyword selection module (46) and used for combining all keywords to obtain a combination result;
the combined retrieval module (472) is connected with the keyword combination module (471) and is used for retrieving a reinforcement method in the database by taking the combined result as a retrieval basis;
and a repeated elimination module (473) connected to the combination retrieval module (472) and used for eliminating the repeated reinforcement method.
8. The BIM technology-based hospital construction collaborative management platform according to claim 7, wherein the combined search module (472) comprises:
the combination sorting module (4721) is connected with the keyword combination module (471) and used for arranging the number of the keywords in the combination result according to the sequence from most to least;
and a sequence searching module (4722) connected to the combination sorting module (4721) and used for sequentially searching the combination results according to the arranged sequence.
9. The BIM technology-based hospital construction collaborative management platform of claim 7, wherein the duplicate culling module (473) comprises:
the method sorting module (4731) is connected with the sequence retrieval module (4722) and used for sorting the retrieved reinforced methods and marking the keywords adopted during retrieval;
and the selection and elimination module (4732) is connected with the method sorting module (4731) and is used for selecting the reinforcement method with the most keywords in the repeated reinforcement methods and eliminating the rest repeated reinforcement methods.
10. The BIM technology-based hospital construction collaborative management platform according to claim 6, wherein the method retrieval module (47) further comprises:
a relevancy ranking module (474) connected to the combined search module (472) for ranking the relevancy according to the number of the keywords;
and the relevancy marking module (475) is connected to the relevancy grading module (474) and is used for assigning the corresponding relevancy to the reinforcement method corresponding to the target combination result.
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