CN115294248A

CN115294248A - Super high-rise building engineering supervision method and terminal

Info

Publication number: CN115294248A
Application number: CN202210879030.9A
Authority: CN
Inventors: 冯建新; 胡峥; 孙煜; 吴政界; 刘若愚
Original assignee: Wuxi Project Management & Consultation Co ltd
Current assignee: Wuxi Project Management & Consultation Co ltd
Priority date: 2022-07-25
Filing date: 2022-07-25
Publication date: 2022-11-04
Anticipated expiration: 2042-07-25
Also published as: CN115294248B

Abstract

The invention relates to a method and a terminal for supervising super high-rise building engineering, which belong to the field of building construction supervision, wherein the method comprises the following steps: after receiving a construction starting signal aiming at a first floor, calling a first floor standard chart corresponding to the first floor; generating a first floor live map corresponding to the first floor based on the first floor standard map; after receiving the construction completion signal, identifying a target building structure to which the construction completion signal is directed and actual measurement data corresponding to the target building structure; updating a target live structure diagram corresponding to the target building structure in the first floor standard diagram based on the measured data, and setting the target live structure diagram to be in a display state; and after receiving a construction condition viewing request aiming at the first floor, feeding back the first floor standard diagram and the first floor live diagram at the current moment. The method and the device have the effects of being convenient for finding out that construction is poor in time and reducing the possibility of poor accumulation.

Description

Super high-rise building engineering supervision method and terminal

Technical Field

The invention relates to the field of building supervision, in particular to a super high-rise building engineering supervision method and a terminal.

Background

At present, a construction control net refers to a measurement control net laid for engineering construction, and the function of the measurement control net is to control the construction three-dimensional position (plane position and elevation) of the area. The construction control net is the basis for construction lofting, completion of engineering, settlement observation of buildings and reconstruction and extension of buildings in future. When some super high-rise buildings are constructed, a plane control network is generally adopted for vertical transmission, all transmitted data are superposed, and in the transmission process, errors of the data are accumulated along with the data.

In the process of implementing the present application, the inventors found that the above-mentioned technology has at least the following problems: due to the position of the high-rise building, if the accumulated errors are not found in time, on one hand, the construction quality is poor, and on the other hand, the inconvenience of rework is also caused by the delay of finding the errors.

Disclosure of Invention

In order to find out construction failure in time and reduce the possibility of failure accumulation, the application provides a method and a terminal for supervising super high-rise building engineering.

In a first aspect, the present application provides a method for supervising super high-rise building engineering, which adopts the following technical scheme:

a super high-rise building project supervision method is based on a project supervision terminal, BIM (building information modeling) building drawings are stored in the project supervision terminal, the BIM building drawings comprise a plurality of floor standard drawings which correspond to floors one by one, the floor standard drawings comprise a plurality of standard structure drawings which correspond to building structures one by one, and the method comprises the following steps:

after receiving a construction starting signal aiming at a first floor, calling a first floor standard chart corresponding to the first floor;

generating a first floor live map corresponding to the first floor based on the first floor standard map, wherein the first floor live map comprises a plurality of live structure maps, the live structure maps correspond to the building structures one by one, and each live structure map is in a hidden state initially;

after receiving a construction completion signal, identifying a target building structure to which the construction completion signal is directed and measured data corresponding to the target building structure;

updating a target live structure chart corresponding to the target building structure in the first floor standard chart based on the measured data, and setting the target live structure chart to be in a display state;

after receiving a construction condition viewing request aiming at the first floor, feeding back the first floor standard graph and the first floor live graph at the current moment.

By adopting the technical scheme, in the construction process, the supervision personnel can input a construction starting signal aiming at the first floor into the engineering supervision terminal after the construction of the first floor is about to start, so that the engineering supervision terminal can call the first floor standard drawing corresponding to the first floor, and then the engineering supervision terminal can copy and generate a new drawing based on the extracted first floor standard drawing, namely the first floor live drawing corresponding to the first floor. Along with the construction process, every time the construction of a building structure is completed, the supervision personnel can measure and obtain measured parameters and input a construction completion signal aiming at the building structure into the engineering supervision terminal, so that the engineering supervision terminal updates the first floor standard diagram. After receiving a construction condition checking request aiming at the first floor, the project supervision terminal feeds back the first floor standard graph and the first floor live graph at the current moment for display. On one hand, the first floor live map can be updated by taking a single building structure as a unit, so that the supervision personnel can control the construction process in stages, the possibility of rework due to error accumulation is reduced, and on the other hand, only the live structure map corresponding to the building structure after construction is in a display state in the first floor live map, so that the supervision personnel can lock the focus of attention and grasp the construction process in time.

Optionally, after the updating the target live-action structure diagram corresponding to the target building structure in the first floor standard diagram based on the measured data, the method further includes:

and verifying the construction quality of the target building structure based on the measured data and a preset building quality judgment rule, and setting a display mode of the target live structure chart based on a verification result.

Optionally, in each floor standard map, at least one building structure is a basic frame structure;

after the construction completion signal is received and the target building structure to which the construction completion signal is directed is identified, the method further comprises:

when the target building structure is recognized to be a basic frame structure and all the basic frame structures in the first floor are constructed, obtaining laser projection control points corresponding to the first floor based on live structure diagrams corresponding to all the basic frame structures;

and converting to obtain the actual position of the laser projection control point in the first floor, and sending to a preset user terminal.

Optionally, the method further includes:

and after recognizing that all live structure graphs in the first floor live graph are updated, generating or updating a building live graph based on the current first floor live graph, wherein the building live graph is recorded with floor live graphs of construction floors which are completed currently according to a building sequence.

Optionally, the method further includes:

after updating the building live map is completed, counting accumulated construction errors of all currently completed construction floors based on the building live map;

and when the target accumulated construction error exceeds a corresponding preset accumulated error threshold value, generating prompt information aiming at the target accumulated construction error.

Optionally, the accumulated construction error may include one or more of an accumulated inclination, an accumulated horizontal offset, and an accumulated bad number.

In a second aspect, the present application provides an engineering supervision terminal, which adopts the following technical scheme:

an engineering supervision terminal comprising:

the building system comprises a storage module, a building information management module and a building management module, wherein BIM construction drawings are stored in the storage module and comprise a plurality of floor standard graphs which are in one-to-one correspondence with floors, and the floor standard graphs comprise a plurality of standard structure graphs which are in one-to-one correspondence with building structures;

the drawing calling module is used for calling a first floor standard drawing corresponding to a first floor after receiving a construction starting signal aiming at the first floor;

the floor live map generating module is used for generating a first floor live map corresponding to the first floor based on the first floor standard map, the first floor live map comprises a plurality of live structure maps, the live structure maps are in one-to-one correspondence to the building structures, and each live structure map is in a hidden state initially;

the construction completion signal identification module is used for identifying a target building structure to which the construction completion signal is directed and actual measurement data corresponding to the target building structure after receiving the construction completion signal;

the live structure chart updating module is used for updating a target live structure chart corresponding to the target building structure in the first floor standard chart based on the measured data and setting the target live structure chart into a display state;

and the drawing feedback module is used for feeding back the first floor standard drawing and the first floor live drawing at the current moment after receiving a construction condition checking request aiming at the first floor.

In a third aspect, the present application provides an intelligent terminal, which adopts the following technical scheme:

an intelligent terminal comprising a memory and a processor, said memory having stored thereon a computer program which can be loaded by the processor and which performs the method according to the first aspect.

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

a computer readable storage medium comprising a computer program stored thereon which is loadable by a processor and adapted to carry out the method of the first aspect.

By adopting the technical scheme, after the computer-readable storage medium is loaded into any computer, the computer can execute the ultra-high-rise building project supervision method of the first aspect.

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

1. in the construction process, a supervision person can input a construction starting signal aiming at a first floor into an engineering supervision terminal after the construction of the first floor is about to start, so that the engineering supervision terminal can call a first floor standard drawing corresponding to the first floor, and then the engineering supervision terminal can copy and generate a new drawing, namely a first floor live drawing corresponding to the first floor, based on the extracted first floor standard drawing. Along with the construction process, every time the construction of a building structure is completed, the supervision personnel can measure and obtain measured parameters and input a construction completion signal aiming at the building structure into the engineering supervision terminal, so that the engineering supervision terminal updates the first floor standard diagram. After receiving a construction condition checking request aiming at the first floor, the project supervision terminal feeds back the first floor standard diagram and the first floor live diagram at the current moment for display. On one hand, the first floor live map can be updated by taking a single building structure as a unit, so that the supervision personnel can control the construction process in stages, the possibility of rework due to error accumulation is reduced, and on the other hand, only the live structure map corresponding to the building structure after construction is in a display state in the first floor live map, so that the supervision personnel can lock the focus of attention and grasp the construction process in time.

Drawings

FIG. 1 is a schematic flow chart diagram for embodying a method for supervising a super high-rise building project according to an embodiment of the present application;

FIG. 2 is a block diagram of a system for embodying an engineering supervision terminal in an embodiment of the present application;

fig. 3 is a block diagram of a system for embodying another project supervision terminal in the embodiment of the present application.

Description of reference numerals: 21. a storage module; 22. a drawing calling module; 23. a floor live map generation module; 24. a construction completion signal identification module; 25. a live structure chart updating module; 26. a drawing feedback module; 31. a construction quality verification module; 32. and a display mode setting module.

Detailed Description

The present application is described in further detail below with reference to figures 1-3.

The embodiment of the application discloses a super high-rise building project supervision method which can be applied to the construction process of high-rise buildings, and the execution main body is a project supervision terminal. The project supervision terminal can be intelligent processing equipment such as computers, BIM construction drawing to current construction can be input in advance in the project supervision terminal, BIM construction drawing comprises the floor standard map of a plurality of one-to-one correspondence floor, and the project supervision terminal can carry out the integral display with all floor standard maps in the BIM construction drawing according to the floor order based on user's demand, also can select based on the user, draws alone and shows arbitrary floor standard map. Each floor standard diagram comprises a plurality of standard structure diagrams which are in one-to-one correspondence to building structures, and the building structures can be floor base plates, walls, in-floor structures and the like.

The process flow shown in fig. 1 will be described in detail below with reference to specific embodiments, and the contents may be as follows:

s10: and after receiving a construction starting signal aiming at the first floor, calling a first floor standard chart corresponding to the first floor.

The first floor may be any one of all floors, specifically, a floor to be constructed currently.

In implementation, the supervision personnel can input a construction starting signal carrying the floor number of the first floor into the project supervision terminal after the construction of the first floor is about to be started, so that the project supervision terminal calls a floor standard map corresponding to the first floor, namely the first floor standard map.

S20: and generating a first floor live map corresponding to the first floor based on the first floor standard map, wherein the first floor live map comprises a plurality of live structure maps, the live structure maps correspond to the building structures one by one, and each live structure map is in a hidden state initially.

In implementation, the project supervision terminal may copy and generate a new drawing, that is, a first floor live drawing corresponding to the first floor, based on the extracted first floor standard drawing. Each standard structure diagram in the first floor standard diagram is copied to obtain a live structure diagram contained in the first floor live diagram, and each live structure diagram also corresponds to one building structure. In the initial state, each live structure diagram is in a hidden state, and when the live structure diagram of the first floor is displayed by any equipment, the live structure diagram in the hidden state cannot be directly displayed.

S30: after receiving the construction completion signal, identifying a target building structure to which the construction completion signal is directed and actual measurement data corresponding to the target building structure.

Wherein the target building structure may be any one or more of all building structures in the first floor.

In implementation, the supervision personnel can measure various parameters of the target building structure on site after completing the construction of the target building structure, so as to obtain the measured data aiming at the target building structure. And then, the supervision personnel can input the measured data into the engineering supervision terminal and input a construction completion signal carrying the measured data into the engineering supervision terminal. The construction completion signal can carry the structure number of the target building structure, so that the project supervision terminal can confirm the target building structure to which the construction completion signal aims.

S40: and updating the target live structure diagram corresponding to the target building structure in the first floor standard diagram based on the measured data, and setting the target live structure diagram into a display state.

In an implementation, the project supervision terminal may update the target live construction drawing corresponding to the target building structure in the first floor standard drawing based on the measured data corresponding to the target building structure. For example, the target live structure diagram may have a plurality of editable structure parameters, each item in the measured data may correspond to one of the structure parameters, and when a difference between any one of the measured data and the corresponding structure parameter is greater than a parameter modification threshold corresponding to the structure parameter, the project supervision terminal may modify and update the structure parameter based on the parameter in the measured data. And after finishing updating all the structural parameters, finishing updating the target live structure diagram. And then, the project supervision terminal can set the target live-action structure diagram into a display state, and when the first floor live-action diagram is displayed by any equipment, the live-action structure diagram in the display state can be directly displayed.

S50: after receiving a construction condition viewing request aiming at the first floor, feeding back the first floor standard graph and the first floor live graph at the current moment.

In implementation, in the construction process, the supervision personnel can send a construction condition checking request aiming at the first floor to the project supervision terminal at any time, so that the project supervision terminal feeds back the first floor standard diagram and the first floor live diagram at the current moment for display. On one hand, the first floor live map can be updated by taking a single building structure as a unit, so that the supervision personnel can control the construction process in stages, the possibility of rework due to error accumulation is reduced, and on the other hand, only the live structure map corresponding to the building structure after construction is in a display state in the first floor live map, so that the supervision personnel can lock the focus of attention and grasp the construction process in time.

Optionally, in another embodiment, in order to facilitate the manager to find the building structure with poor construction in time, after the step S40, the following may be further included:

and verifying the construction quality of the target building structure based on the measured data and a preset building quality judgment rule, and setting a display mode of the target live structure diagram based on a verification result.

In implementation, the project supervision terminal may compare each parameter in the measured data with the corresponding structural parameter after receiving the measured data for the target building structure, so as to determine whether a difference between each parameter and the corresponding structure is greater than a corresponding preset reasonable threshold, and mark the parameter with a yes determination result as an abnormal parameter. The project supervision terminal may distinguish and display the target live-action structure diagram after recognizing that the abnormal parameter exists in the measured data, for example, display in a distinguishing color, highlight display, and the like. The project supervision terminal can also be used for differentially displaying the target live-action structure diagram based on the number or the type of the identified abnormal parameters, and the more the number of the abnormal parameters is, the darker the color is when the abnormal parameters are displayed.

Optionally, in another embodiment, in each of the floor level maps, there is at least one building structure as a base frame structure. Wherein, the basic frame structure refers to a floor base plate or a wall body. In this case, after S30 described above, the following may be further included:

and when the target building structure is recognized to be a basic frame structure and all the basic frame structures in the first floor are constructed, obtaining a laser projection control point corresponding to the first floor based on the corresponding live structure diagrams of all the basic frame structures.

In an implementation, for the first floor, the project supervision terminal may record the updated status of each live structure diagram in the live view of the first floor. And after each construction completion signal is received, identifying whether a target building structure aimed at by the construction completion signal is a basic frame structure, and when the identification result is yes, the project supervision terminal can further identify whether live structure diagrams corresponding to all the basic frame structures in the first floor are updated, namely whether all the basic frame structures in the first floor are constructed. And when the identification result is yes, the project supervision terminal can identify the geometric center of the first floor as a laser projection control point based on the live structure diagrams corresponding to all the basic frame structures in the live structure diagram of the first floor. The laser projection control point is a position point for a manager to detect perpendicularity through a laser plumb instrument.

And converting to obtain the actual position of the laser projection control point in the first floor, and sending the actual position to a preset user terminal.

In implementation, the project supervision terminal can identify the distance between the laser projection control point and each wall body in the first floor live view, and convert the distance based on the proportional relation between the first floor live view and the actual size of the first floor, so as to obtain the actual distance between the actual laser projection control point in the first floor and each actual wall body, and further obtain the actual position of the laser projection control point in the first floor. Later, the project supervision terminal can send above-mentioned actual position for the user terminal who presets, for example smart mobile phone, panel computer etc. that appointed supervision personnel carried to it further carries out the operation that the laser plummet appearance detected the straightness that hangs down to be convenient for supervision personnel.

Optionally, in another embodiment, the method may further include the following:

and after recognizing that all the live structure graphs in the first floor live graph are completely updated, generating or updating a building live graph based on the current first floor live graph, wherein the building live graph is recorded with the floor live graphs of the currently completed construction floors according to the building sequence.

In implementation, when the project supervision terminal recognizes that all the live construction graphs in the first floor live map are updated, the project supervision terminal represents that the construction of the first floor is completely completed, at this time, the project supervision terminal can generate or update a building live map, and the floor live map of the currently completed construction floor is recorded in the building live map according to the building sequence. And if not, the project supervision terminal updates the existing building live view corresponding to the current project based on the first floor live view. And then, the supervision personnel can call and check the live map of the building, so that the current overall construction condition can be checked.

and after updating the building live map is completed, counting the accumulated construction errors of all the currently completed construction floors based on the building live map.

In some embodiments, the accumulated construction error may include one or more of an accumulated inclination, an accumulated horizontal offset, and an accumulated bad quantity. The accumulated inclination can be obtained by counting the verticality of each constructed floor, the accumulated horizontal offset is the sum of absolute values of position offsets of each constructed floor in the horizontal direction, and the accumulated bad number is the sum of the number of building structures with abnormal parameters.

In implementation, each time the update of the building live view map is completed, the project supervision terminal may count all accumulated construction errors of all currently completed construction floors based on the building live view map.

Wherein, the target accumulated construction error can be any one or more of all accumulated construction errors.

In implementation, the project supervision terminal may compare each accumulated construction error with a corresponding preset accumulated error threshold, and generate prompt information for the target accumulated construction error when the target accumulated construction error exceeds the corresponding accumulated error threshold. And then, the project supervision terminal can broadcast the prompt information through a preset prompt device and can also send the prompt information to a preset user terminal.

Based on the above method, an embodiment of the present application further discloses an engineering supervision terminal, and with reference to fig. 2, the engineering supervision terminal includes:

the building structure comprises a storage module 21, wherein BIM (building information modeling) construction drawings are stored in the storage module 21, the BIM construction drawings comprise a plurality of floor standard drawings which are in one-to-one correspondence to floors, and the floor standard drawings comprise a plurality of standard structure drawings which are in one-to-one correspondence to building structures.

And the drawing calling module 22 is used for calling a first floor standard drawing corresponding to the first floor after receiving the construction starting signal aiming at the first floor.

The floor live map generating module 23 is configured to generate a first floor live map corresponding to the first floor based on the first floor standard map, where the first floor live map includes a plurality of live structure maps, the live structure maps correspond to the building structures one-to-one, and each live structure map is in a hidden state initially.

And the construction completion signal identification module 24 is configured to identify the target building structure to which the construction completion signal is directed and the measured data corresponding to the target building structure after receiving the construction completion signal.

And the live structure chart updating module 25 is configured to update the target live structure chart corresponding to the target building structure in the first floor standard chart based on the measured data, and set the target live structure chart to be in a display state.

And the drawing feedback module 26 is configured to feed back the first floor standard drawing and the first floor live drawing at the current time after receiving the construction condition checking request for the first floor.

Optionally, with reference to fig. 3, the project supervision terminal further includes:

and the construction quality verification module 31 is configured to verify the construction quality of the target building structure based on the measured data and a preset building quality judgment rule after updating the target live structure diagram corresponding to the target building structure in the first floor standard diagram based on the measured data.

And a display mode setting module 32, configured to set a display mode of the target live structure diagram based on the verification result of the construction quality verification module 31.

Optionally, in each floor plan, there is at least one building structure as a base frame structure. The project supervision terminal further comprises a laser projection control point generating module which is used for obtaining the laser projection control point corresponding to the first floor based on the corresponding live structure diagrams of all the basic frame structures after the target building structure is recognized to be the basic frame structure and all the basic frame structures in the first floor are constructed.

And the actual position conversion module is used for converting to obtain the actual position of the laser projection control point in the first floor and sending the actual position to a preset user terminal.

Optionally, the project supervision terminal further includes a building live view processing module, configured to generate or update a building live view based on the current first floor live view after recognizing that all live view diagrams in the first floor live view are updated, where the building live view records a floor live view of a currently completed construction floor according to a building sequence.

Optionally, the engineering supervision terminal further includes:

and the accumulated construction error counting module is used for counting the accumulated construction errors of all the construction floors completed currently based on the building live map after the updating of the building live map is completed.

And the prompt information generation module is used for generating prompt information aiming at the target accumulative construction error when the target accumulative construction error exceeds a corresponding preset accumulative error threshold value.

The embodiment of the application also discloses an intelligent terminal, which comprises a memory and a processor, wherein the memory is stored with a computer program which can be loaded by the processor and can execute the super high-rise building engineering supervision method.

The embodiment of the present application further discloses a computer readable storage medium, which stores a computer program that can be loaded by a processor and execute the method for supervising the super high-rise building engineering, and the computer readable storage medium includes, for example: various media capable of storing program codes, such as a usb disk, a removable hard disk, a Read-Only Memory (ROM), a Random Access Memory (RAM), a magnetic disk, or an optical disk.

The above examples are only used to illustrate the technical solutions of the present application, and do not limit the scope of protection of the application. It is to be understood that the embodiments described are only some of the embodiments of the present application and not all of them. All other embodiments, which can be derived by a person skilled in the art from these embodiments without making any inventive step, are within the scope of the present application.

Claims

1. The super high-rise building project supervision method is characterized by being based on a project supervision terminal, BIM (building information modeling) construction drawings are stored in the project supervision terminal and comprise a plurality of floor standard drawings in one-to-one correspondence to floors, each floor standard drawing comprises a plurality of standard structure drawings in one-to-one correspondence to a building structure, and the method comprises the following steps:

updating a target live structure diagram corresponding to the target building structure in the first floor standard diagram based on the measured data, and setting the target live structure diagram to be in a display state;

2. The method for supervising super high-rise building engineering according to claim 1, further comprising, after the updating the target live construction drawing corresponding to the target building structure in the first floor standard drawing based on the measured data:

3. The method for supervising super high rise building engineering according to claim 1, wherein in each of the floor level diagrams, at least one of the building structures is a base frame structure;

when the target building structure is recognized to be a basic frame structure and all the basic frame structures in the first floor are constructed, obtaining a laser projection control point corresponding to the first floor based on the live structure diagrams corresponding to all the basic frame structures;

4. The method for supervising super high-rise building engineering according to claim 1, further comprising:

5. The method for supervising super high-rise building engineering according to claim 4, further comprising:

after updating of the building live map is completed, counting accumulated construction errors of all currently completed construction floors based on the building live map;

6. The method for supervising super high-rise building engineering according to claim 5, wherein the accumulated construction error may include one or more of an accumulated inclination, an accumulated horizontal offset, and an accumulated defective amount.

7. An engineering supervision terminal, comprising:

the building information management system comprises a storage module (21), wherein BIM construction drawings are stored in the storage module (21), each BIM construction drawing comprises a plurality of floor standard graphs which correspond to floors one by one, and each floor standard graph comprises a plurality of standard structure graphs which correspond to building structures one by one;

the drawing calling module (22) is used for calling a first floor standard drawing corresponding to a first floor after receiving a construction starting signal aiming at the first floor;

a floor live map generating module (23) for generating a first floor live map corresponding to the first floor based on the first floor standard map, wherein the first floor live map comprises a plurality of live structure maps, the live structure maps are in one-to-one correspondence with the building structures, and each live structure map is in a hidden state initially;

a construction completion signal identification module (24) for identifying a target building structure to which the construction completion signal is directed and measured data corresponding to the target building structure after receiving the construction completion signal;

a live structure chart updating module (25) for updating a target live structure chart corresponding to the target building structure in the first floor standard chart based on the measured data and setting the target live structure chart to be in a display state;

and the drawing feedback module (26) is used for feeding back the first floor standard drawing and the first floor live drawing at the current moment after receiving a construction condition viewing request aiming at the first floor.

8. An intelligent terminal, comprising a memory and a processor, the memory having stored thereon a computer program that can be loaded by the processor and that executes the method according to any one of claims 1 to 6.

9. A computer-readable storage medium, in which a computer program is stored which can be loaded by a processor and which executes the method of any one of claims 1 to 6.