CN219872423U - Intelligent construction management system for reconstruction and expansion engineering - Google Patents

Abstract

The utility model discloses an intelligent construction management system for a reconstruction and expansion project, which comprises a personnel information acquisition module, a material information acquisition module, a mechanical information acquisition module, a project image progress information acquisition module and a central control module, wherein the personnel information acquisition module is used for acquiring personnel information; the material information acquisition module is used for acquiring the distribution condition of the incoming materials of each workshop and each construction point; the mechanical information acquisition module is used for acquiring the mechanical equipment distribution and the operation condition of each construction point; the engineering image progress information acquisition module is used for acquiring real-time engineering image progress information; the central control module is used for acquiring the construction plan of the reconstruction project according to the acquired personnel information, material distribution condition, mechanical equipment distribution and operation condition and real-time project image progress information. According to the utility model, personnel, materials and mechanical equipment resources are reasonably regulated according to the information of personnel, materials and machinery related to reconstruction and expansion engineering construction, and construction projects are effectively controlled.

Description

Intelligent construction management system for reconstruction and expansion engineering

Technical Field

The utility model relates to the technical field of engineering construction, in particular to an intelligent construction management system for reconstruction and expansion engineering.

Background

The reconstruction and expansion engineering lines are long, the variety of structures is various, the traffic interference is large, the processing of the vehicles is complex, the construction points are highly dispersed, and the difficulty of construction organization design and engineering management is large. For example, twenty kilometers per standard section of a Highway reconstruction and expansion project in Jingang, the structure relates to a newly built bridge, a newly built roadbed, a spliced wide bridge and a spliced wide roadbed comprise single-side and double-side spliced wide, an overpass is dismantled and reconstructed, a traffic protection and diversion project is carried out, an overpass project, a bridge deck and pavement project is carried out, a processing workshop relates to prefabrication Liang Changgong, a prefabrication part field, a reinforcing steel bar processing workshop, a steel structure processing workshop, an earthwork transfer field, a concrete factory, construction facilities and mechanical equipment relate to earthwork roadbed construction and transportation equipment, a pile driver, a crane, a bridge girder erection machine, a construction platform and a framework and the like, and construction points are scattered on two sides of a normally-running Highway. The number of constructors is large, the variety of materials and mechanical equipment is large, real-time engineering image progress information is difficult to collect completely in time, and challenges are brought to engineering project construction organization design implementation and daily management.

In daily management of engineering project construction organization, a traditional work material machine and image progress management mode is generally adopted, wherein constructors manage daily work material distribution and attendance management and month end collecting statistics, material materials manage in-out limit material distribution and month end inventory, mechanical equipment manage station accounts and operation logs and month end collecting statistics, engineering image progress adopts daily report, weekly report and monthly report, production regulation can supervise progress and coordinate resources and the like. The method has the advantages of low control cost, coarseness, low efficiency, untimely and inaccurate statistical information. The reconstruction and expansion engineering has the advantages of relatively simple structure, scattered working points, relatively loose working procedures, multiple types of structures, relatively scattered information, slow and easy error collection, and difficulty in real-time engineering image progress information, so that the decision maker can timely judge the image progress and the configuration of construction resources, and even the construction period is seriously lagged.

In addition, the headquarters of construction enterprises generally require project departments to report the work material machine and the project image progress management information through the return port of the information management system, so the project departments need to establish the work material machine and the image progress management account information. The accuracy of the ledger information also affects the control of construction enterprises on engineering projects, so that the project department background ledger information needs to be checked and checked with the field foreground construction information to ensure the accuracy of the information, but in the related technology, the project department background ledger information is lack of checking and correcting means with the field foreground construction information.

In the related art, the engineering project is controlled based on the building model, so that the method is more suitable for controlling intensive projects with complex structures, concentrated working points and compact working procedures, and is not very suitable for controlling comprehensive projects with relatively simple structures, scattered working points, relatively loose working procedures and multiple types of structures in reconstruction and expansion engineering.

Disclosure of Invention

The utility model aims to overcome the defects of the background technology and provide an intelligent construction management system for a reconstruction and expansion project.

In a first aspect, the present utility model provides an intelligent construction management system for a reconstruction and expansion project, including:

the personnel information acquisition module is used for acquiring personnel information;

the material information acquisition module is used for acquiring the distribution condition of incoming materials of each workshop and each construction point;

the mechanical information acquisition module is used for acquiring the mechanical equipment distribution and the operation condition of each construction point;

the engineering image progress information acquisition module is used for acquiring real-time engineering image progress information;

the central control module is in communication connection with the personnel information acquisition module, the material information acquisition module, the mechanical information acquisition module and the engineering image progress information acquisition module and is used for acquiring the construction plan of the reconstruction engineering according to the acquired personnel information, the incoming material distribution condition of each workshop and each construction point, the mechanical equipment distribution and operation condition of each construction point, the real-time engineering image progress information and the project department background management information.

In some embodiments, the personnel information collection module further comprises:

the personnel positioning information acquisition sub-module is arranged on a constructor and is used for positioning position distribution information of the constructor in workshops and construction points;

the attendance information acquisition sub-module is arranged at the inlet and outlet of each workshop and each construction point and is used for acquiring the attendance information of constructors.

In some embodiments, the personnel information acquisition module further includes a personnel information acquisition sub-module, where the personnel information acquisition sub-module is configured to acquire construction personnel work kind and work number information. In some embodiments, the material information collection module further comprises:

a first camera for identifying articles loaded on the material transport vehicle;

the first positioning information acquisition sub-module is used for acquiring positioning information of the material transport vehicle;

the NFC device is arranged at each workshop and used for inputting information of each finished product and semi-finished product material loaded on the material transport vehicle;

and the electronic tag sensor is used for identifying the vehicle number information of the material transportation vehicle.

In some embodiments, the first camera, the first positioning information acquisition sub-module, the NFC device, and the electronic tag sensor are communicatively connected to the central control module through a first wireless communicator.

In some embodiments, the mechanical information collection module further comprises:

the second camera is used for acquiring an image of the operation process of the mechanical equipment;

the second positioning information acquisition sub-module is used for acquiring the positioning information of the mechanical equipment;

the mechanical operation module is arranged on the entering construction mechanical equipment of each construction point and is used for acquiring the operation content, the operation gesture and the operation process of the mechanical equipment;

and the operation data storage sub-module is in communication connection with the second camera, the second positioning information acquisition sub-module and the mechanical operation module and is used for storing the acquired mechanical equipment operation process image, the positioning information of the mechanical equipment, the operation content, the operation gesture and the operation process of the mechanical equipment.

In some embodiments, the second camera, the second positioning information acquisition sub-module, and the machine operation module are communicatively connected to the central control module via a second wireless communicator.

In some embodiments, the system further comprises a correction module, wherein the correction module is in communication connection with the personnel information acquisition module, the material information acquisition module and the mechanical information acquisition module and is used for correcting the acquired personnel information, material information and mechanical information.

In some embodiments, the central control module further comprises:

the personnel information processing module is used for comparing the acquired personnel positioning and attendance information with the construction dispatching plan and acquiring personnel adjustment strategies;

the material information processing sub-module is used for comparing the acquired entrance material distribution condition of each workshop and each construction point with the background material entrance plan and the material ledger information of the project part to acquire material adjustment strategies of each workshop and each construction point;

the mechanical information processing sub-module is used for comparing the obtained mechanical equipment distribution and operation conditions of each construction point with the mechanical equipment operation plan to obtain mechanical equipment adjustment and operation adjustment strategies of each construction point;

and the engineering image progress processing sub-module is used for comparing the obtained implementation engineering image progress information with project part background construction organization designs and engineering image progress plans to obtain real-time engineering image progress deviation information.

In a second aspect, the utility model also provides an intelligent construction management method for the reconstruction and expansion engineering, which comprises the following steps:

acquiring personnel information;

acquiring the distribution condition of incoming materials of workshops and construction points;

acquiring the mechanical equipment distribution and the operation condition of each construction point;

acquiring real-time engineering image progress information;

and acquiring the construction plan of the reconstruction and expansion project according to the acquired personnel information, the distribution condition of the incoming materials of each workshop and each construction point, the distribution and operation condition of the mechanical equipment of each construction point and the real-time project image progress information.

Compared with the prior art, the utility model has the following advantages:

according to the intelligent construction management system for the reconstruction and expansion engineering, provided by the utility model, the personnel information acquisition module, the material information acquisition module, the mechanical information acquisition module and the engineering image progress information acquisition module are used for acquiring information on personnel, materials, machinery and image progress related to reconstruction and expansion engineering construction, acquiring construction planning of personnel, materials and machinery according to the information acquired in real time and project part background management information, reasonably regulating personnel, materials and mechanical equipment resources, and effectively controlling construction projects.

Drawings

FIG. 1 is a functional block diagram of an intelligent construction management system for a reconstruction and expansion project provided by an embodiment of the present utility model;

FIG. 2 is another functional block diagram of the intelligent construction management system for a reconstruction and expansion project provided by an embodiment of the present utility model;

fig. 3 is a flow chart of a method for managing intelligent construction of a reconstruction and expansion project according to an embodiment of the present utility model.

Detailed Description

Reference will now be made in detail to the present embodiments of the utility model, examples of which are illustrated in the accompanying drawings. While the utility model will be described in conjunction with the specific embodiments, it will be understood that they are not intended to limit the utility model to the described embodiments. On the contrary, it is intended to cover alternatives, modifications, and equivalents as may be included within the spirit and scope of the utility model as defined by the appended claims. It should be noted that the method steps described herein may be implemented by any functional block or arrangement of functions, and any functional block or arrangement of functions may be implemented as a physical entity or a logical entity, or a combination of both.

The present utility model will be described in further detail below with reference to the drawings and detailed description for the purpose of enabling those skilled in the art to understand the utility model better.

Note that: the examples to be described below are only one specific example, and not as limiting the embodiments of the present utility model necessarily to the following specific steps, values, conditions, data, sequences, etc. Those skilled in the art can, upon reading the present specification, make and use the concepts of the utility model to construct further embodiments not mentioned in the specification.

The reconstruction and expansion engineering route is long, the variety of materials is multiple, the traffic interference is large, the processing workshop is miscellaneous, the construction points are highly dispersed, and the construction organization design and management difficulty is large.

In view of the above, the utility model provides an intelligent construction management system for a reconstruction and expansion project, which aims to solve the technical problem of high construction management difficulty of the reconstruction and expansion project.

Referring to fig. 1, an embodiment of the present utility model provides an intelligent construction management system for a reconstruction and expansion project, including a personnel information acquisition module 100, a material information acquisition module 200, a machine information acquisition module 300, an engineering image progress information acquisition module 400, and a central control module 500, where the personnel information acquisition module is used to acquire personnel information; the material information acquisition module is used for acquiring the incoming material distribution condition of each workshop and each construction point; the mechanical information acquisition module is used for acquiring the mechanical equipment distribution and the operation condition of each construction point; the engineering image progress information acquisition module is used for acquiring real-time engineering image progress information; the central control module is in communication connection with the personnel information acquisition module, the material information acquisition module, the mechanical information acquisition module and the engineering image progress information acquisition module, and is used for acquiring a construction plan of a reconstruction engineering according to the acquired personnel information, the incoming field material distribution condition of each workshop and each construction point, the mechanical equipment distribution and operation condition of each construction point, the real-time engineering image progress information and project department background management information so as to adjust personnel, materials and mechanical equipment of each workshop and each construction point.

The intelligent construction management system for the reconstruction and expansion engineering provided by the utility model can be used for effectively controlling construction projects by acquiring information of personnel, materials, machinery, engineering image progress and the like related to construction of the reconstruction and expansion engineering and reasonably regulating personnel, materials and mechanical equipment resources according to project part background management information.

As described above, the project department background management information records the number of various kinds of constructors required for the construction of the reconstruction and expansion project, the image design drawing of the construction of the reconstruction and expansion project, the number of various kinds of materials required for the construction of the reconstruction and expansion project, the construction points and the construction progress plan information of the reconstruction and expansion project.

In a more specific embodiment, the project department background management information includes a construction dispatching plan, a project department background material approach plan and material ledger information, a mechanical equipment operation plan and a project department background construction organization design and engineering image progress plan.

In an embodiment, the personnel information acquisition module 100 further includes a personnel positioning information acquisition sub-module 110 and an attendance information acquisition sub-module 120, where the personnel positioning information acquisition sub-module is installed on a constructor, for example, on a constructor mobile phone or in a helmet, and is used for positioning position distribution information of the constructor in a workshop and a construction point; the attendance information acquisition sub-module is arranged at the inlet and outlet of each workshop and each construction point and is used for acquiring the attendance information of constructors.

In an embodiment, referring to fig. 2, the personnel information acquisition module 100 further includes a personnel information acquisition sub-module 130, where the personnel information acquisition sub-module is configured to acquire the construction personnel job type and job number information.

In an embodiment, the personnel positioning information obtaining sub-module and the personnel information obtaining sub-module are implemented as mobile phones, and the work types, the work number information and the positioning information of the constructors are obtained and recorded through the mobile phones.

In an embodiment, the attendance information obtaining submodule is implemented as a face-brushing attendance machine or a fingerprint attendance machine, and can also be implemented as a mobile phone, and the attendance function is implemented through a card-punching attendance program or software of the mobile phone.

In an embodiment, the personnel positioning information obtaining sub-module, the personnel information obtaining sub-module and the attendance information obtaining sub-module are in communication connection with the central control module in a wireless network manner through a wireless communication module, and the central control module is used for obtaining personnel adjustment strategies for reconstruction and expansion engineering construction according to the obtained personnel positioning information, personnel work information and personnel attendance information.

In an embodiment, the material information acquisition module further includes a first camera, a first positioning information acquisition sub-module, an NFC device, and an electronic tag sensor, where the first camera is used to identify an article loaded on a material transport vehicle; the first positioning information acquisition sub-module is used for acquiring positioning information of the material transport vehicle; the NFC device is arranged at each workshop and can be used for rapidly inputting the material information of each finished product and semi-finished product loaded on the material transport vehicle into the material data memory through NFC touch; the electronic tag sensor is arranged at the electric inlet and outlet of each construction worker and used for identifying the vehicle number information of the material transportation vehicle. Wherein, the finished products and the plate finished products comprise steel bar parts, steel structures, concrete and earthwork for main engineering and construction facilities; each workshop comprises a steel bar processing workshop, a steel structure processing workshop, a beam field, an assembly field, a concrete factory and an earthwork field; each construction point comprises a roadbed construction point, a culvert construction point, a bridge foundation construction point, a bridge superstructure construction point, a pavement construction point, a overpass dismantling construction point and a construction facility construction point.

In an embodiment, the first camera, the first positioning information acquisition sub-module, the NFC device and the electronic tag sensor are communicatively connected to the central control module through a first wireless communicator.

In an embodiment, the mechanical information acquisition module further includes a second camera, a second positioning information acquisition sub-module, a mechanical operation module, and an operation data storage sub-module, where the second camera is used to acquire an operation process image of the mechanical equipment; the second positioning information acquisition sub-module is used for acquiring positioning information of the mechanical equipment; the mechanical operation module is arranged on the entering construction mechanical equipment of each construction point and is used for acquiring the operation content, the operation gesture and the operation process of the mechanical equipment;

the operation data storage sub-module is in communication connection with the second camera, the second positioning information acquisition sub-module and the mechanical operation module and is used for storing the acquired mechanical equipment operation process image, the positioning information of the mechanical equipment, the operation content of the mechanical equipment, the operation posture and the operation data of the operation process and storing operation data information of an operation process image set, and the operation data information comprises operation data such as the type, the name, the number, the engineering position, the operation progress, the operation time and the like of the mechanical equipment.

In an embodiment, the second camera, the second positioning information obtaining sub-module and the mechanical operation module are connected with the central control module in a communication manner through a second wireless communicator, and are used for obtaining a construction mechanical equipment adjustment strategy of the reconstruction and expansion engineering according to the obtained mechanical equipment position information, operation image and operation data information so as to reasonably and efficiently utilize mechanical equipment.

In an embodiment, the engineering image progress information acquisition module further comprises an unmanned aerial vehicle, a third camera, a third positioning information acquisition sub-module and a laser altimeter, wherein the third camera is arranged at the lower part of the unmanned aerial vehicle and is used for acquiring ground structural characteristics and guiding the unmanned aerial vehicle to perform three-dimensional coordinate measurement on a ground structure; the third positioning information acquisition sub-module and the laser altimeter are arranged on a vertical shaft of the unmanned aerial vehicle and are used for acquiring three-dimensional coordinates of a ground structure through a synergistic effect.

In an embodiment, the engineering image progress information acquisition module further comprises a wireless communicator, wherein the wireless communicator is installed at the lower part of the unmanned aerial vehicle and is in communication connection with the third positioning information acquisition sub-module through a wireless communication interface, the laser altimeter is in communication connection with the third camera, and the wireless communicator is used for receiving and storing three-dimensional coordinate information measured by the wireless communicator on the ground structures and transmitting the characteristics of the ground structures and the three-dimensional coordinates of the ground structures to the central control module to obtain real-time image construction progress information of the structures.

In an embodiment, the first positioning information obtaining sub-module, the second positioning information obtaining sub-module, and the third positioning information obtaining sub-module are implemented as a beidou RTK receiver, and in other embodiments of the present utility model, may be implemented as other positioning devices, so long as positioning information can be obtained.

In an embodiment, the intelligent construction management system for the reconstruction and expansion project further comprises a correction module, wherein the correction module is in communication connection with the personnel information acquisition module, the material information acquisition module and the mechanical information acquisition module and is used for correcting the acquired personnel information, material information and mechanical information so as to avoid deviation problem of information uploading caused by poor communication information at each construction point or workshop.

In an embodiment, the central control module further comprises a personnel information processing module, a material information processing module, a mechanical information processing sub-module and an engineering image progress processing sub-module, wherein the personnel information processing module is used for comparing the acquired personnel positioning and attendance information with a construction dispatching plan and acquiring a personnel adjustment strategy; the material information processing sub-module is used for comparing the acquired entrance material distribution condition of each workshop and each construction point with background material entrance plan and material account information of the project part to acquire material adjustment strategies of each workshop and each construction point; the mechanical information processing sub-module is used for comparing the obtained mechanical equipment distribution and operation conditions of each construction point with the mechanical equipment operation plan to obtain mechanical equipment adjustment and operation adjustment strategies of each construction point; the project image progress processing sub-module is used for comparing the obtained project image progress information with project part background construction organization designs and project image progress plans to obtain real-time project image progress deviation information.

In a second aspect, please refer to fig. 3, the present utility model further provides a method for intelligent construction management of a reconstruction and expansion project, which includes the following steps:

s1, acquiring personnel information;

s2, acquiring the distribution condition of incoming materials of each workshop and each construction point;

s3, obtaining the mechanical equipment distribution and the operation condition of each construction point;

s4, acquiring real-time engineering image progress information, preferably, acquiring the engineering image progress information of the construction site in centimeter level in real time;

s5, checking and correcting the acquired personnel information, material information and mechanical information according to the acquired centimeter-level engineering image progress information, and acquiring scheduling strategies of construction planning personnel, materials and machinery of the reconstruction and expansion engineering according to the corrected personnel information, material information and mechanical information, real-time engineering image progress information and project background management information.

In an embodiment, the step of S1, obtaining personnel information, specifically includes the following steps:

s11, configuring a positioning module in a constructor mobile phone, installing a positioning APP containing constructor type and number information, classifying, identifying and positioning various constructors, and sending positioning information of the constructors on a field foreground to a central control subsystem personnel information module through a wireless network;

s12, installing face-brushing attendance machines at the entrances and exits of workshops and construction points, performing face-brushing identification attendance on constructors, and sending attendance information of the constructors at the field foreground to a personnel information module of a central control module through a wireless network;

in an embodiment, the step of S2, obtaining the distribution condition of the incoming materials of each workshop and each construction point, specifically includes the following steps:

s21, on a material transport vehicle, the first camera images identify articles loaded on the material transport vehicle, the first Beidou RTK receiver measures the position of the material transport vehicle, and the number electronic tag identifies the material transport vehicle number information;

s22, in each workshop, recording the identification information of each finished product and semi-finished product material loaded on the material transport vehicle into the material data memory of the material transport vehicle in an NFC (near field communication) one touch transmission mode; an electronic tag non-stop identification device is arranged at each construction point inlet and outlet, and the material transport vehicle number information passing through each construction point inlet and outlet and the loaded finished product and semi-finished product material information are identified;

s23, the material information module stores the image and the material transportation data information in the material data memory, and the wireless communicator is used for providing information of electronic labels for the position, the material transportation data and the serial numbers of the material transportation vehicle of the central control subsystem in the field foreground.

In an embodiment, the step S3 of obtaining the mechanical equipment distribution and the operation condition of each construction point specifically includes the following steps:

s31, installing a mechanical operation module on the field construction mechanical equipment at each construction point; the second camera records an operation process image of the mechanical equipment, the second Beidou RTK receiver measures the position of the mechanical equipment, and the mechanical operation module transmits operation contents, operation postures and operation data of an operation process of the mechanical equipment of the field foreground to the central control module mechanical information module through the second wireless communicator;

s32, the central control module collects and stores project department background engineering information including project department organization management information, constructor standing account information, material management standing account information, mechanical equipment management standing account information, construction organization design information, completed image progress statistical information and similar engineering big data information, and establishes a project department background engineering information database for being called when checking and correcting the foreground and background information.

In an embodiment, the step of S4, obtaining the real-time image progress information of the on-site foreground centimeter level, specifically includes the following steps:

s41, designing three-dimensional coordinates according to the engineering line aerial three-dimensional ground model led into the central control module and the characteristic points of the engineering line structure, and planning the unmanned aerial vehicle navigation line;

s42, the unmanned aerial vehicle sails along a planned route, the third camera observes the ground structure characteristics and feeds back to the central control module, and meanwhile, the third Beidou RTK receiver feeds back the unmanned aerial vehicle position information to the image progress information module of the central control module;

s43, the central control module controls the unmanned aerial vehicle to carry out plane patrol along the contour line of each ground structure according to the processing results of the image progress information module and the information data processing module;

s44, the third Beidou RTK receiver measures to obtain plane coordinates of the centimeter-level ground structure feature points and actual measurement heights of the top surfaces of the unmanned aerial vehicles at the ground structure feature points, and the laser altimeter measures to obtain vertical distances from the center of the centimeter-level altimeter to the ground structure feature points;

s45, the central control module calculates centimeter-level actual measurement heights of the ground structure feature points according to centimeter-level actual heights of the top surface of the unmanned aerial vehicle at the ground structure feature points measured by the third Beidou RTK receiver, the known heights from the third Beidou RTK receiver to the center of the laser altimeter and centimeter-level vertical distances from the center of the laser altimeter to the ground structure feature points measured by the laser altimeter, and centimeter-level real-time image progress information of each structure of the on-site foreground is obtained.

In an embodiment, according to the centimeter-level real-time image progress information, the foreground and background personnel information, the material information and the mechanical information are checked and corrected, and the method specifically comprises the following steps of:

s51, checking the finished product and semi-finished product material information of each workshop entering each construction point according to the material ledger information distributed to each workshop by taking the workshop as a unit and the finished product and semi-finished product material library production and stock ledger information of each workshop;

s52, according to centimeter-level real-time image progress information, checking real-time image progress information of each construction point by taking the construction point as a unit and combining mechanical equipment account information distributed to each construction point by a project department background, finished products and semi-finished product material information of each checked workshop entering each construction point and construction organization design and construction log information of each construction point;

s53, calculating the labor productivity of the finished products and the semi-finished goods and the materials of the workshops according to the production information and the personnel information of the finished products and the semi-finished goods and the materials of the workshops and the construction quota, and calculating the labor productivity of the construction points according to the checked real-time image progress information, the checked mechanical equipment information and the checked personnel information of the construction points and the construction quota.

In an embodiment, the step of obtaining the scheduling policy of the construction planners, materials and machinery of the reconstruction and expansion project according to the corrected personnel information, material information and machinery information, real-time project image progress information and project background management information specifically includes the following steps:

s54, comparing centimeter-level real-time image progress information of each construction point with image progress deviation conditions of construction organization designs, and making an image progress plan of the next step of engineering;

s55, planning the next step of constructor arrangement and distribution of constructors at each construction point of each workshop according to the next step of image progress, and combining personnel information, the labor productivity of the finished product, the semi-finished product material, and the labor productivity of the personnel and the machine at each construction point of each workshop;

s56, planning next-step material approach and mechanical equipment approach according to the next-step image progress of the project, combining the material information of the finished products and the semi-finished products of each construction point, and planning next-step material production of the finished products and the semi-finished products of each workshop by combining the next-step material approach;

s57, comprehensively analyzing the project next image progress planning, the final product and semi-finished product material production planning and the final product and semi-finished product material production planning of the next constructors in each workshop and the final constructors planning, material approach planning and mechanical equipment in-out planning of each construction point by adopting an intelligent technology according to the project department background project information database to form a preliminary project planning and pushing each decision maker and a user to review;

and S58, after the decision makers and the users review and feed back the central control module, forming engineering plans, and pushing the engineering plans to a WEB browser by the central control module so that the decision makers and the users browse and schedule engineering resources and manage and control image progress through mobile phones, computers and electronic screens.

The intelligent construction management method for the reconstruction and expansion project provided by the utility model has the following advantages:

(1) The three-dimensional coordinates of the characteristic points of each structure are directly measured by adopting an unmanned plane three-dimensional coordinate method, so that the centimeter-level real-time image progress information is quickly and accurately obtained, the real-time image progress of each structure is convenient and fast to grasp by project decision makers and users, and meanwhile, the accurate engineering quantity information can be conveniently obtained;

(2) On the basis of the traditional material machine and image progress management, the intelligent sensor information system and the traditional standing book are combined to collect engineering information, so that engineering projects are convenient to use, foreground and background account information is accurately docked, accurate real-time image progress of the engineering projects is taken as the center, engineering resource information is checked in time, engineering resources are reasonably configured, engineering plans are formulated, and the projects can be effectively controlled;

(3) The utility model adopts the sensor to automatically collect real-time information at the field foreground, and by checking and correcting with the background account information, on the basis of ensuring the reliability of the field information, the accuracy of the background information of the project department is ensured, the project department is facilitated to exchange accurate engineering information to the construction enterprise, and the effective management and control of the project department by the construction enterprise is realized.

Based on the same inventive concept, the embodiments of the present utility model also provide a computer-readable storage medium, on which a computer program is stored, which when being executed by a processor implements all or part of the method steps of the above method.

The present utility model may be implemented by implementing all or part of the above-described method flow, or by instructing the relevant hardware by a computer program, which may be stored in a computer readable storage medium, and which when executed by a processor, may implement the steps of the above-described method embodiments. Wherein the computer program comprises computer program code, which may be in the form of source code, object code, executable files or in some intermediate form, etc. The computer readable medium may include: any entity or device capable of carrying computer program code, a recording medium, a U disk, a removable hard disk, a magnetic disk, an optical disk, a computer Memory, a Read-Only Memory (ROM), a random access Memory (RAM, random Access Memory), an electrical carrier signal, a telecommunications signal, a software distribution medium, and so forth. It should be noted that the content of the computer readable medium can be appropriately increased or decreased according to the requirements of the jurisdiction's jurisdiction and the patent practice, for example, in some jurisdictions, the computer readable medium does not include electrical carrier signals and telecommunication signals according to the jurisdiction and the patent practice.

Based on the same inventive concept, the embodiment of the utility model also provides an electronic device, which comprises a memory and a processor, wherein the memory stores a computer program running on the processor, and the processor executes the computer program to realize all or part of the method steps in the method.

The processor may be a central processing unit (Central Processing Unit, CP U), but may also be other general purpose processors, digital signal processors (Digital Signal Pr ocessor, DSP), application specific integrated circuits (Application Specific Integrated Circ uit, ASIC), off-the-shelf programmable gate arrays (Field-Programmable Gate Array, FPGA) or other programmable logic devices, discrete gate or transistor logic devices, discrete hardware components, or the like. A general purpose processor may be a microprocessor or the processor may be any conventional processor or the like, the processor being a control center of the computer device, and the various interfaces and lines connecting the various parts of the overall computer device.

The memory may be used to store computer programs and/or modules, and the processor implements various functions of the computer device by running or executing the computer programs and/or modules stored in the memory, and invoking data stored in the memory. The memory may mainly include a storage program area and a storage data area, wherein the storage program area may store an operating system, an application program required for at least one function (e.g., a sound playing function, an image playing function, etc.); the storage data area may store data (e.g., audio data, video data, etc.) created according to the use of the handset. In addition, the memory may include high-speed random access memory, and may also include non-volatile memory, such as a hard disk, memory, plug-in hard disk, smart Media Card (SMC), secure Digital (SD) Card, flash Card (flash Card), at least one disk storage device, flash memory device, or other volatile solid state storage device.

It will be appreciated by those skilled in the art that embodiments of the present utility model may be provided as a method, system, server, or computer program product. Accordingly, the present utility model may take the form of an entirely hardware embodiment, an entirely software embodiment or an embodiment combining software and hardware aspects. Furthermore, the present utility model may take the form of a computer program product embodied on one or more computer-usable storage media (including, but not limited to, magnetic disk storage, optical storage, and the like) having computer-usable program code embodied therein.

The present utility model is described with reference to flowchart illustrations and/or block diagrams of methods, apparatus (systems), servers and computer program products according to embodiments of the utility model. It will be understood that each flow and/or block of the flowchart illustrations and/or block diagrams, and combinations of flows and/or blocks in the flowchart illustrations and/or block diagrams, can be implemented by computer program instructions. These computer program instructions may be provided to a processor of a general purpose computer, special purpose computer, embedded processor, or other programmable data processing apparatus to produce a machine, such that the instructions, which execute via the processor of the computer or other programmable data processing apparatus, create means for implementing the functions specified in the flowchart flow or flows and/or block diagram block or blocks.

These computer program instructions may also be stored in a computer-readable memory that can direct a computer or other programmable data processing apparatus to function in a particular manner, such that the instructions stored in the computer-readable memory produce an article of manufacture including instruction means which implement the function specified in the flowchart flow or flows and/or block diagram block or blocks.

These computer program instructions may also be loaded onto a computer or other programmable data processing apparatus to cause a series of operational steps to be performed on the computer or other programmable apparatus to produce a computer implemented process such that the instructions which execute on the computer or other programmable apparatus provide steps for implementing the functions specified in the flowchart flow or flows and/or block diagram block or blocks.

It will be apparent to those skilled in the art that various modifications and variations can be made to the present utility model without departing from the spirit or scope of the utility model. Thus, it is intended that the present utility model also include such modifications and alterations insofar as they come within the scope of the appended claims or the equivalents thereof.

Claims (7)

1. An intelligent construction management system for a reconstruction and expansion project, which is characterized by comprising:

the personnel information acquisition module is used for acquiring personnel information;

the material information acquisition module is used for acquiring the distribution condition of incoming materials of each workshop and each construction point;

the mechanical information acquisition module is used for acquiring the mechanical equipment distribution and the operation condition of each construction point;

the engineering image progress information acquisition module is used for acquiring real-time engineering image progress information;

the central control module is in communication connection with the personnel information acquisition module, the material information acquisition module, the mechanical information acquisition module and the engineering image progress information acquisition module and is used for acquiring the construction plan of the reconstruction engineering according to the acquired personnel information, the incoming material distribution condition of each workshop and each construction point, the mechanical equipment distribution and operation condition of each construction point, the real-time engineering image progress information and the project department background management information.

2. The reconstruction and expansion project intelligent construction management system according to claim 1, wherein the personnel information acquisition module further comprises:

the personnel positioning information acquisition sub-module is arranged on a constructor and is used for positioning position distribution information of the constructor in workshops and construction points;

the attendance information acquisition sub-module is arranged at the inlet and outlet of each workshop and each construction point and is used for acquiring the attendance information of constructors.

3. The intelligent construction management system for the reconstruction and expansion project according to claim 2, wherein the personnel information acquisition module further comprises a personnel information acquisition sub-module for acquiring construction personnel work kind and work number information.

4. The reconstruction and expansion project intelligent construction management system according to claim 1, wherein the material information acquisition module further comprises:

a first camera for identifying articles loaded on the material transport vehicle;

the first positioning information acquisition sub-module is used for acquiring positioning information of the material transport vehicle;

the NFC device is arranged at each workshop and used for inputting information of each finished product and semi-finished product material loaded on the material transport vehicle;

and the electronic tag sensor is used for identifying the vehicle number information of the material transportation vehicle.

5. The intelligent construction management system for the reconstruction and expansion engineering according to claim 4, wherein the first camera, the first positioning information acquisition sub-module, the NFC device and the electronic tag sensor are in communication connection with the central control module through a first wireless communicator.

6. The reconstruction and expansion project intelligent construction management system according to claim 1, wherein the machine information acquisition module further comprises:

the second camera is used for acquiring an image of the operation process of the mechanical equipment;

the second positioning information acquisition sub-module is used for acquiring the positioning information of the mechanical equipment;

the mechanical operation module is arranged on the entering construction mechanical equipment of each construction point and is used for acquiring the operation content, the operation gesture and the operation process of the mechanical equipment;

and the operation data storage sub-module is in communication connection with the second camera, the second positioning information acquisition sub-module and the mechanical operation module and is used for storing the acquired mechanical equipment operation process image, the positioning information of the mechanical equipment, the operation content, the operation gesture and the operation process of the mechanical equipment.

7. The reconstruction and expansion project intelligent construction management system according to claim 1, wherein the project image progress information acquisition module further comprises:

unmanned plane;

the third camera is arranged at the lower part of the unmanned aerial vehicle and is used for acquiring ground structural characteristics and guiding the unmanned aerial vehicle to measure three-dimensional coordinates of a ground structure;

a third positioning information acquisition sub-module;

a laser altimeter;

the third positioning information acquisition sub-module and the laser altimeter are arranged on a vertical shaft of the unmanned aerial vehicle and are used for acquiring three-dimensional coordinates of a ground structure through a synergistic effect.