CN107368247B - Method/system for managing field project, computer readable storage medium and terminal - Google Patents

Abstract

The invention provides a method, a system, a computer readable storage medium and a terminal for managing a field project, wherein the method for managing the field project comprises the following steps: storing a building model of the site project; displaying the building model; receiving a measurement instruction, and executing measurement operation associated with the building model according to the measurement instruction; or receiving a positioning instruction, and executing positioning operation associated with the building model according to the positioning instruction; or receiving an observation instruction, and executing the observation operation associated with the building model according to the observation instruction. The invention can bring the construction manager with a feeling of being personally on the scene, has better experience, improves the management efficiency of the construction manager and realizes paperless management of the construction project.

Description

Method/system for managing field project, computer readable storage medium and terminal

Technical Field

The invention belongs to the field of application management of constructional engineering, relates to a management method and a management system, and particularly relates to a field project management method and a field project management system, a computer-readable storage medium and electronic equipment.

Background

BIM (Building Information Modeling) is another important computer application technology appearing in the engineering construction industry after CAD (computer aided design) technology, and is leading to a complete revolution of unprecedented cases in the construction industry. The technology utilizes digital modeling software, improves the efficiency of project design, construction and management, and brings great added value to building enterprises adopting the technology.

At present, BIM platform is applied to improve design, rework is avoided, BIM is used for simulation, and the technology of optimizing construction scheme and the like is relatively mature. But the potential of how to use BIM on site to guide construction correctly has not been explored.

At present, site construction is carried out by site constructors according to a construction scheme compiled in advance, combined with national standard standards and the like, and then supervision is carried out and acceptance is carried out according to the national acceptance standards. A large amount of data such as drawings and standards need to be brought to the site so as to be referred at any time. The traditional construction drawing of the field project can not bring the sense of being personally on the scene for construction management personnel, and the experience sense is poor.

Therefore, how to provide a field project management method, system and electronic device to solve the defects that the traditional construction drawing of the field project cannot bring the construction manager with a feeling of being personally on the scene, the experience feeling is poor and the like in the prior art becomes a technical problem to be solved by the technical staff in the field.

Disclosure of Invention

In view of the above disadvantages of the prior art, an object of the present invention is to provide a field project management method, a field project management system, and an electronic device, which are used to solve the problem that the construction manager cannot feel personally on the scene and experience is poor due to the traditional construction drawing of the field project in the prior art.

To achieve the above and other related objects, an aspect of the present invention provides a method for managing a field project, including the steps of: storing a building model of the site project; displaying the building model; receiving a measurement instruction, and executing measurement operation associated with the building model according to the measurement instruction; or receiving a positioning instruction, and executing positioning operation associated with the building model according to the positioning instruction; or receiving an observation instruction, and executing the observation operation associated with the building model according to the observation instruction.

In an embodiment of the present invention, a process for performing a measurement operation associated with the building model according to the measurement instruction includes: the measuring instruction comprises a first instruction for measuring the distance between two points and a second instruction for measuring the distance between two objects; receiving the first instruction, searching the coordinates of the two points triggered by the user on the building model, and calculating the distance between the two points according to the coordinates of the two points; calculating the actual distance between the two points according to the proportion of the building model to the field project; or receiving the second instruction, searching two objects triggered by the user on the building model, calculating the geometric center coordinates of the two objects, and calculating the distance between the two objects according to the geometric center coordinates of the two objects; and calculating the actual distance between the two objects according to the proportion of the building model to the field project.

In an embodiment of the present invention, an implementation process of performing the positioning operation associated with the building model according to the positioning instruction includes: receiving a model positioning instruction, and acquiring the area position of the model positioning instruction on the building model; displaying the two-dimensional model and the three-dimensional model corresponding to the area position on an operation interface; the two-dimensional model and the three-dimensional model are linked to respond to the model positioning instruction; or receiving a field positioning instruction and entering a field project picture capturing mode; searching a two-dimensional model and a three-dimensional model corresponding to the captured field project picture on the building model, and displaying the two-dimensional model and the three-dimensional model corresponding to the field project picture on the operation interface; the positioning instruction comprises the model positioning instruction or/and the field positioning instruction.

In an embodiment of the present invention, the observation instruction includes a current view angle enlarging observation instruction, a moving view angle observation instruction, a gravity sensing observation instruction, a through-wall observation instruction, or/and a return initial view angle observation instruction; one implementation of performing observation operations associated with the building model in accordance with the observation instructions includes: when the current visual angle amplification observation instruction is received on the building model, acquiring the position of the current visual angle amplification observation instruction on the building model, and amplifying the position; when the mobile visual angle observation instruction is received on the building model, the mobile visual angle of the mobile visual angle observation instruction on the building model is obtained, and the position and the direction corresponding to the mobile visual angle are displayed in real time; when the gravity sensing observation instruction is received on the building model, acquiring a moving visual angle moving along with gravity on the building model through gravity sensing; receiving the through-wall observation instruction on one wall body in the building model, penetrating the wall body and displaying a three-dimensional model in the wall body; or receiving the observation instruction of returning the initial viewing angle on the building model, and switching the current viewing angle to the original preset viewing angle.

Another aspect of the present invention provides a field project management system, including: the storage module is used for storing the building model of the field project; a display module for displaying the building model; the measurement operation module is used for receiving a measurement instruction and executing measurement operation associated with the building model according to the measurement instruction; the positioning operation module is used for receiving a positioning instruction and executing positioning operation associated with the building model according to the positioning instruction; and the observation operation module is used for receiving an observation instruction and executing the observation operation associated with the building model according to the observation instruction.

In an embodiment of the present invention, the measurement command includes a first command for measuring a distance between two points and a second command for measuring a distance between two objects; the measurement operation module receives the first instruction, searches coordinates of two points triggered by a user on the building model, and calculates the distance between the two points according to the coordinates of the two points; calculating the actual distance between the two points according to the proportion of the building model to the field project; or the measurement operation module receives the second instruction, searches for two objects triggered by the user on the building model, calculates the geometric center coordinates of the two objects, and calculates the distance between the two objects according to the geometric center coordinates of the two objects; and calculating the actual distance between the two objects according to the proportion of the building model to the field project.

In an embodiment of the present invention, the positioning operation module receives a model positioning instruction, and obtains an area position where the model positioning instruction appears on the building model; displaying the two-dimensional model and the three-dimensional model corresponding to the area position on an operation interface; the two-dimensional model and the three-dimensional model are linked to respond to the model positioning instruction; or the positioning operation module receives a field positioning instruction and enters a field project picture capturing mode; searching a two-dimensional model and a three-dimensional model corresponding to the captured field project picture on the building model, and displaying the two-dimensional model and the three-dimensional model corresponding to the field project picture on the operation interface; the positioning instruction comprises the model positioning instruction or/and the field positioning instruction.

In an embodiment of the present invention, the observation instruction includes a current view angle enlarging observation instruction, a moving view angle observation instruction, a gravity sensing observation instruction, a through-wall observation instruction, or/and a return initial view angle observation instruction; when the observation operation module receives the current view angle amplification observation instruction on the building model, acquiring the position of the current view angle amplification observation instruction on the building model, and amplifying the position; when the observation operation module receives the observation instruction of the mobile visual angle on the building model, acquiring the mobile visual angle of the observation instruction of the mobile visual angle on the building model, and displaying the position and the direction corresponding to the mobile visual angle in real time; when the observation operation module receives the gravity sensing observation instruction on the building model, acquiring a moving visual angle moving along with gravity on the building model through gravity sensing; the observation operation module receives the through-wall observation instruction on one wall body in the building model, penetrates the wall body and displays a three-dimensional model in the wall body; or the observation operation module receives the observation instruction of returning the initial visual angle on the building model and switches the visual angle to the original preset visual angle.

Another aspect of the present invention also provides a computer-readable storage medium having stored thereon a computer program which, when executed by a processor, implements the method of managing a field project.

A final aspect of the present invention provides a terminal, including: a processor and a memory; the memory is used for storing computer programs, and the processor is used for executing the computer programs stored by the memory so as to enable the terminal to execute the field project management method

As described above, the field project management method, system, computer-readable storage medium, and terminal according to the present invention have the following advantageous effects:

the field project management method, the field project management system, the computer readable storage medium and the terminal can bring the construction manager with a feeling of being personally on the scene, the experience feeling is better, the management efficiency of the construction manager is improved, and paperless management of the building project is realized.

Drawings

Fig. 1 is a flowchart illustrating a method for managing a field project according to an embodiment of the present invention.

Fig. 2A is a schematic flow chart of S41 in the method for managing a field project according to the present invention.

Fig. 2B is a schematic flow chart of S42 in the method for managing a field project according to the present invention.

Fig. 2C is a schematic flow chart of S42 in the method for managing a field project according to the present invention.

Fig. 3 is a schematic structural diagram of a field project management system according to an embodiment of the present invention.

Description of the element reference numerals

3 management system of field project

31 memory module

32 lightweight module

33 display module

34 measurement operation module

35 positioning operation module

36 observation operation module

S1-S43

Detailed Description

The embodiments of the present invention are described below with reference to specific embodiments, and other advantages and effects of the present invention will be easily understood by those skilled in the art from the disclosure of the present specification. The invention is capable of other and different embodiments and of being practiced or of being carried out in various ways, and its several details are capable of modification in various respects, all without departing from the spirit and scope of the present invention. It is to be noted that the features in the following embodiments and examples may be combined with each other without conflict.

It should be noted that the drawings provided in the following embodiments are only for illustrating the basic idea of the present invention, and the components related to the present invention are only shown in the drawings rather than drawn according to the number, shape and size of the components in actual implementation, and the type, quantity and proportion of the components in actual implementation may be changed freely, and the layout of the components may be more complicated.

Example one

The embodiment provides a field project management method, which comprises the following steps:

storing a building model of the site project;

displaying the building model;

receiving a measurement instruction, and executing measurement operation associated with the building model according to the measurement instruction; or

Receiving a positioning instruction, and executing positioning operation associated with the building model according to the positioning instruction; or

And receiving an observation instruction, and executing the observation operation associated with the building model according to the observation instruction.

The management method of the field project provided by the present embodiment will be described in detail below with reference to the drawings. The field project management method provided by the embodiment is applied to electronic equipment. In practical implementation manners, the electronic device is, for example, an electronic device with a touch display screen, such as a smart phone, a tablet computer, and the like. The electronic equipment of the embodiment adopts a tablet personal computer.

Wherein the touch display screen provides both an output interface and an input interface between the device and a user. The touch display controller receives/sends electrical signals from/to the touch display. The touch screen display then displays visual output to the user. This visual output may include text, graphics, video, and any combination thereof. Some or all of the visual output may correspond to user interface objects, more details of which are described below.

Touch displays also accept user input based on tactile and/or tactile contact. The touch screen display forms a touch sensitive surface that accepts user input. The touch display screen and touch display screen controller (along with any associated modules and/or sets of instructions in memory) detect contact (and any movement or breaking of the touch) on the touch display screen and transform the detected contact into interaction with user interface objects, such as one or more soft keys, displayed on the touch display screen. In one exemplary embodiment, the point of contact between the touch display screen and the user corresponds to one or more fingers of the user. The touch display screen may use LCD (liquid crystal display) technology or LPD (light emitting polymer display) technology, but in other embodiments other display technologies may be used. Touch displays and touch display controllers can detect contact and movement or breaking thereof using any of a number of touch sensitive technologies, including but not limited to capacitive, resistive, infrared, and surface acoustic wave technologies, as well as other proximity sensor arrays, or other technologies for determining one or more points of contact with a touch display. The user may contact the touch screen display using any suitable object or accessory, such as a stylus, finger, or the like.

The contact/motion module, in conjunction with the touch screen controller, detects contact with the touch screen. The contact/motion module includes various software components for performing various operations associated with detection of contact with a touch display screen, such as determining whether contact has occurred, determining whether the contact has moved, and tracking movement on the touch display screen, and determining whether the contact has been broken (i.e., whether contact has ceased). Determining movement of the point of contact may include determining a velocity (magnitude), a velocity (magnitude and direction), and/or an acceleration (including magnitude and/or direction) of the point of contact. In some embodiments, the contact/motion module and touch display controller also detect contact on the touch panel.

Please refer to fig. 1, which is a flowchart illustrating a method for managing a field project according to an embodiment. As shown in fig. 1, the method for managing the field project specifically includes the following steps:

and S1, storing the building model of the field project. The building model is a 3D model obtained based on simulation of model files including various relevant vector building drawings for simulating the on-site building project, building information of components, component names, geometric dimensions, materials, weights, colors, three-dimensional positioning information in the building, progress information, shipping places and even construction cost information, and the like.

S2, carrying out lightweight processing on the stored building model of the site project to extract key points of the building model and form a simplified building model; and after the electronic equipment enters a field project management mode, displaying the simplified building model on the operation interface. At present, the lightweight technology is various, and representative two technologies are JT and 3 DXML. 3DXML is a lightweight technology proposed by Dassault, Microsoft, etc., and JT is a lightweight technology proposed by JT open architecture.

And S3, displaying the light-weight building model.

S41, receiving the measuring instruction, and executing the measuring operation associated with the building model according to the measuring instruction. The measuring instruction comprises a first instruction for measuring the distance between two points and a second instruction for measuring the distance between two objects. In this embodiment, a point distance module and/or an object distance module are/is disposed in a first predetermined area of the operation interface, the point distance module is configured to provide an interface for receiving the first instruction for measuring the distance between two points, and the object distance module is configured to provide an interface for providing a second instruction for measuring the distance between two objects. Please refer to fig. 2A, which shows a schematic flow chart of S31. As shown in fig. 2A, the S31 includes the following steps:

s411, receiving a first instruction for measuring the distance between two points through the point distance assembly, searching coordinates of the two points on the building model when sensing that the touch action on the building model is taken as continuous touch of the two points, calculating the distance between the two points according to the coordinates of the two points, and calculating the actual distance between the two points according to the proportion of the building model and the field project. For example, when a touch motion on the architectural model is sensed as a touch motion of continuously touching two points a and B, a predetermined measurement function associated with an icon of a distance between a point and a point means mapping the touched two points a and B on the architectural model to obtain mapping coordinates a1 and B1 mapped on the architectural model, calculating model distances of a1 and B1 using euclidean distances, and finally calculating a touch motion on the architectural model as an actual distance of continuously touching two points a and B, which is a measurement result, according to a ratio of the architectural model to a field item. Or

S412, receiving a second instruction for measuring the distance between the two objects through the object distance component, respectively searching the two objects on the building model when sensing that the touch action on the building model is taken as continuously touching the two objects, calculating the geometric center coordinates of the two objects, and calculating the distance between the two objects according to the geometric center coordinates of the two objects; and calculating the actual distance between the two objects according to the proportion of the building model to the field project. For example, touching component C1 and component D1 on the building model, finding two objects on the building model respectively, calculating the center coordinates of component C1 and the geometric center coordinates C2 and D2 of component D1, calculating the model distances of C2 and D2 by using the euclidean distance after calculating the geometric center coordinates, and finally calculating the touch action on the building model as the actual distance of continuously touching component C1 and component D1 according to the ratio of the building model to the field item, wherein the actual distance is the measurement result. Or

S42, receiving the positioning instruction, and executing the positioning operation associated with the building model according to the positioning instruction. In this embodiment, the positioning instructions include model positioning instructions and/or field positioning instructions. Please refer to fig. 2B and 2C, which are schematic flow charts of S32, respectively. As shown in fig. 2B, the S32 specifically includes the following steps:

s421, receiving a model positioning instruction, and acquiring the area position of the model positioning instruction appearing on the building model. In this embodiment, by providing a model position locating component on the architectural model, the model position locating component is used to provide an interface for receiving the model locating instruction. For example, a model positioning command is received by a model positioning component at the 2 nd floor on the building model, and the position name is acquired according to the model positioning command received at the 2 nd floor. In this embodiment, jump positioning is performed based on the floor height. For example, each floor is 3 meters high, the positioning command appears on the 2 nd floor on the building model, and then 2 times 3 bits 6 meters, and the key arrives at the 2 nd floor after the floor rises for 6 meters.

S422, displaying the two-dimensional model and the three-dimensional model corresponding to the area position on an operation interface according to the area position; and the two-dimensional model and the three-dimensional model are linked to respond to the model positioning instruction. For example, a model positioning instruction is received at the 2 nd floor, and a two-dimensional model and a three-dimensional model of the 2 nd floor are fed back on the operation interface according to the model position coordinates. In the embodiment, the two-dimensional model can be positioned to the position to be reached by the user according to the model position positioning instruction by one key. For example, a user enters a two-dimensional model of a 3-floor, an elevator landing command needing to reach the 3-floor is output on the two-dimensional model, and the user directly jumps to reach the 3-floor elevator landing through the real-time association of the three-dimensional model and the two-dimensional model.

As shown in fig. 2C, the S42 specifically includes the following steps:

and S421', receiving a field positioning instruction, and entering a field project picture capturing mode. In this embodiment, by providing a field locating component on the architectural model, the field locating component is used to provide an interface for receiving the field locating instruction.

S422', according to the captured field project picture, a two-dimensional model and a three-dimensional model corresponding to the captured field project picture are searched on the building model, and the two-dimensional model and the three-dimensional model corresponding to the field project picture are displayed on the operation interface. For example, the construction manager captures a site project picture of the 6#2F construction area at the 6#2F construction area on site, searches a three-dimensional model corresponding to the 6#2F construction area on the building model according to the site project picture of the 6#2F construction area, and feeds back the three-dimensional model of the 6#2F construction area on the operation interface, i.e., jumps into the 6#2F construction area in the building.

S43, receiving the observation instruction, and executing the observation operation related to the building model according to the observation instruction. In this embodiment, the observation instruction includes a current view angle magnification observation instruction, a moving view angle observation instruction, a gravity sensing observation instruction, a through-wall observation instruction, and a return initial view angle observation instruction. In this embodiment, the current view angle magnifying observation module, the moving view angle observation module, the gravity sensing observation module, the wall penetrating observation module, and the returning initial view angle observation module are provided on the building model to receive the current view angle magnifying observation instruction, the moving view angle observation instruction, the gravity sensing observation instruction, the wall penetrating observation instruction, and the returning initial view angle observation instruction, respectively. The S33 includes:

and when the current visual angle amplification observation instruction is received on the building model, acquiring the position of the current visual angle amplification observation instruction on the building model, and amplifying the position.

And when the mobile visual angle observation instruction is received on the building model, acquiring the mobile visual angle of the mobile visual angle observation instruction on the building model, and displaying the position and the direction corresponding to the mobile visual angle in real time.

And when the building model receives a gravity sensing observation instruction, acquiring a moving visual angle of the building model moving along with gravity through gravity sensing on the building model.

And receiving the through-wall observation instruction on one wall body in the building model, penetrating the wall body and displaying the three-dimensional model inside the wall body.

And when the building model receives and receives the observation instruction of returning to the initial visual angle, switching the current visual angle to the original preset visual angle.

The field project management method can bring the construction manager with a feeling of being personally on the scene, the experience feeling is better, the management efficiency of the construction manager is improved, and paperless management of the building project is realized.

Example two

The present embodiment provides a field project management system, including:

the storage module is used for storing the building model of the field project;

a display module for displaying the building model;

the measurement operation module is used for receiving a measurement instruction and executing measurement operation associated with the building model according to the measurement instruction;

the positioning operation module is used for receiving a positioning instruction and executing positioning operation associated with the building model according to the positioning instruction;

and the observation operation module is used for receiving an observation instruction and executing the observation operation associated with the building model according to the observation instruction.

The management system of the field project according to the present embodiment will be described in detail below with reference to the drawings. The field project management system described in this embodiment operates on an electronic device. Please refer to fig. 3, which is a schematic structural diagram of a field project management system in an embodiment. As shown in fig. 3, the field project management system 3 includes a storage module 31, a weight reduction module 32, a display module 33, a measurement operation module 34, a positioning operation module 35, and an observation operation module 36.

The storage module 31 is used for storing the building model of the field project. The building model is a 3D model obtained by simulating model files including various relevant vector building drawings for simulating the on-site building project, building information of components, component names, geometric dimensions, materials, weight, colors, three-dimensional positioning information in the building, progress information, shipping places and even construction cost information and the like.

The weight reducing module 32 connected to the storage module 31 is configured to perform weight reducing processing on the stored building model of the site project to extract key points of the building model and form a simplified building model. And the display module 36 connected with the lightweight module 32 is used for displaying the building model on the operation interface after the electronic equipment enters a field project management mode. In this embodiment, the field project management mode is entered by verifying the username and password.

And the display module 33 connected with the light weight module 32 is used for displaying the light-weighted building model on the operation interface.

The measurement operation module 34 connected to the display module 33 is used for receiving a measurement instruction, and performing a measurement operation associated with the building model according to the measurement instruction.

Specifically, the measurement operation module 34 receives a first instruction for measuring a distance between two points through the point distance component, and when a touch action on the building model is sensed as continuously touching the two points, finds coordinates of the two points on the building model, calculates the distance between the two points according to the coordinates of the two points, and calculates an actual distance between the two points according to a ratio of the building model to a field project. For example, when a touch motion on the architectural model is sensed as a touch motion of continuously touching two points a and B, a predetermined measurement function associated with an icon of a distance between a point and a point means mapping the touched two points a and B on the architectural model to obtain mapping coordinates a1 and B1 mapped on the architectural model, calculating model distances of a1 and B1 using euclidean distances, and finally calculating a touch motion on the architectural model as an actual distance of continuously touching two points a and B, which is a measurement result, according to a ratio of the architectural model to a field item. Or

The measurement operation module 34 receives a second instruction for measuring the distance between the two objects through the object distance component, respectively searches the two objects on the building model when sensing that the touch action on the building model is continuous touch of the two objects, calculates the geometric center coordinates of the two objects, and calculates the distance between the two objects according to the geometric center coordinates of the two objects; and calculating the actual distance between the two objects according to the proportion of the building model to the field project. For example, touching component C1 and component D1 on the building model, finding two objects on the building model respectively, calculating the center coordinates of component C1 and the geometric center coordinates C2 and D2 of component D1, calculating the model distances of C2 and D2 by using the euclidean distance after calculating the geometric center coordinates, and finally calculating the touch action on the building model as the actual distance of continuously touching component C1 and component D1 according to the ratio of the building model to the field item, wherein the actual distance is the measurement result.

The positioning operation module 35 connected to the display module 33 is configured to receive a positioning instruction, and perform a positioning operation associated with the building model according to the positioning instruction. In this embodiment, the positioning instruction includes a model positioning instruction and a field positioning instruction.

The positioning operation module 34 is configured to receive a model positioning instruction, and obtain a region position where the model positioning instruction appears on the building model; displaying the two-dimensional model and the three-dimensional model corresponding to the area position on an operation interface according to the area position; and the two-dimensional model and the three-dimensional model are linked to respond to the model positioning instruction. In this embodiment, by providing a model position locating component on the architectural model, the model position locating component is used to provide an interface for receiving the model locating instruction. For example, a model positioning instruction is received at the 2 nd floor, and a two-dimensional model and a three-dimensional model of the 2 nd floor are fed back on the operation interface according to the model position coordinates. In the embodiment, the two-dimensional model can be positioned to the position to be reached by the user according to the model position positioning instruction by one key. For example, a user enters a two-dimensional model of a 3-floor, an elevator landing command needing to reach the 3-floor is output on the two-dimensional model, and the user directly jumps to reach the 3-floor elevator landing through the real-time association of the three-dimensional model and the two-dimensional model.

The positioning operation module 35 is further configured to receive a field positioning instruction and enter a field project picture capturing mode; and searching a two-dimensional model and a three-dimensional model corresponding to the captured field project picture on the building model according to the captured field project picture, and displaying the two-dimensional model and the three-dimensional model corresponding to the field project picture on the operation interface. In this embodiment, by providing a field locating component on the architectural model, the field locating component is used to provide an interface for receiving the field locating instruction. For example, the construction manager captures a site project picture of the 6#2F construction area at the 6#2F construction area on site, searches a three-dimensional model corresponding to the 6#2F construction area on the building model according to the site project picture of the 6#2F construction area, and feeds back the three-dimensional model of the 6#2F construction area on the operation interface, i.e., jumps into the 6#2F construction area in the building.

The observation operation module 36 connected to the display module 33 is used for receiving the observation instruction and executing the observation operation associated with the building model according to the observation instruction. In this embodiment, the observation instruction includes a current view angle magnification observation instruction, a moving view angle observation instruction, a gravity sensing observation instruction, a through-wall observation instruction, and a return initial view angle observation instruction. In this embodiment, the current view angle magnifying observation module, the moving view angle observation module, the gravity sensing observation module, the wall penetrating observation module, and the returning initial view angle observation module are provided on the building model to receive the current view angle magnifying observation instruction, the moving view angle observation instruction, the gravity sensing observation instruction, the wall penetrating observation instruction, and the returning initial view angle observation instruction, respectively.

The observation operation module 36 is configured to, when the current view-angle magnifying observation instruction is received on the building model, obtain a position where the current view-angle magnifying observation instruction appears on the building model, and magnify the position.

The observation operation module 36 is configured to, when the mobile view observation instruction is received on the building model, obtain a mobile view of the mobile view observation instruction on the building model, and display a position and a direction corresponding to the mobile view in real time.

The observation operation module 36 is configured to obtain a moving view angle of the building model moving along with gravity through gravity sensing on the building model when receiving a gravity sensing observation instruction on the building model.

The observation operation module 36 is configured to receive the through-wall observation instruction on a wall in the building model, penetrate the wall, and display a three-dimensional model of the inside of the wall. Or

The observation operation module 36 is configured to switch the current viewing angle to the original preset viewing angle when receiving the observation instruction of returning to the initial viewing angle on the building model.

EXAMPLE III

The present embodiment provides a computer-readable storage medium on which a computer program is stored, characterized in that the program realizes the management processing method of the field item when executed by a processor. Those of ordinary skill in the art will understand that: all or part of the steps for implementing the above method embodiments may be performed by hardware associated with a computer program. The aforementioned computer program may be stored in a computer readable storage medium. When executed, the program performs steps comprising the method embodiments described above; and the aforementioned storage medium includes: various media that can store program codes, such as ROM, RAM, magnetic or optical disks.

Example four

The present embodiment provides a terminal, including: a processor, a memory, a transceiver, a communication interface, and a system bus; the memory is used for storing the computer program, the communication interface is used for communicating with other devices, the processor and the transceiver are used for running the computer program, and the terminal executes the steps of the management method of the field project.

The above-mentioned system bus may be a Peripheral Component Interconnect (PCI) bus, an Extended Industry Standard Architecture (EISA) bus, or the like. The system bus may be divided into an address bus, a data bus, a control bus, and the like. For ease of illustration, only one thick line is shown, but this does not mean that there is only one bus or one type of bus. The communication interface is used for realizing communication between the database access device and other equipment (such as a client, a read-write library and a read-only library). The memory may include a Random Access Memory (RAM), and may further include a non-volatile memory (non-volatile memory), such as at least one disk memory.

The processor may be a general-purpose processor, and includes a Central Processing Unit (CPU), a Network Processor (NP), and the like; the integrated circuit may also be a Digital Signal Processor (DSP), an Application Specific Integrated Circuit (ASIC), a Field Programmable Gate Array (FPGA) or other programmable logic device, discrete gate or transistor logic device, or discrete hardware components.

In conclusion, the field project management method, the field project management system, the computer-readable storage medium and the terminal can bring the construction manager with a feeling of being personally on the scene, have better experience, improve the management efficiency of the construction manager and realize paperless management of the building project. Therefore, the invention effectively overcomes various defects in the prior art and has high industrial utilization value.

The foregoing embodiments are merely illustrative of the principles and utilities of the present invention and are not intended to limit the invention. Any person skilled in the art can modify or change the above-mentioned embodiments without departing from the spirit and scope of the present invention. Accordingly, it is intended that all equivalent modifications or changes which can be made by those skilled in the art without departing from the spirit and technical spirit of the present invention be covered by the claims of the present invention.

Claims (4)

1. A method for managing a field project, comprising the steps of:

storing a building model of the site project; the building model is built based on a model file of a field project;

displaying the building model;

receiving a measurement instruction, and executing measurement operation associated with the building model according to the measurement instruction; wherein, one implementation process for executing the measurement operation associated with the building model according to the measurement instruction comprises the following steps:

the measuring instruction comprises a first instruction for measuring the distance between two points and a second instruction for measuring the distance between two objects;

receiving the first instruction, searching the coordinates of the two points triggered by the user on the building model, and calculating the distance between the two points according to the coordinates of the two points; calculating the actual distance between the two points according to the proportion of the building model to the field project; receiving the second instruction, searching two objects triggered by the user on the building model, calculating the geometric center coordinates of the two objects, and calculating the distance between the two objects according to the geometric center coordinates of the two objects; calculating the actual distance between the two objects according to the proportion of the building model to the field project;

receiving a positioning instruction, and executing positioning operation associated with the building model according to the positioning instruction; the positioning instruction comprises a model positioning instruction and a field positioning instruction; providing a model position location component on the architectural model, the model position location component for providing an interface for receiving the model location instructions; one implementation of performing a positioning operation associated with the building model in accordance with the positioning instructions includes: receiving a model positioning instruction, and acquiring the area position of the model positioning instruction on the building model; displaying the two-dimensional model and the three-dimensional model corresponding to the area position on an operation interface; the two-dimensional model and the three-dimensional model are linked to respond to the model positioning instruction; providing a field locating component on the building model, wherein the field locating component is used for providing an interface for receiving the field locating instruction; one implementation of performing a positioning operation associated with the building model in accordance with the positioning instructions includes: receiving a field positioning instruction, and entering a field project picture capturing mode; searching a two-dimensional model and a three-dimensional model corresponding to the captured field project picture on the building model according to the captured field project picture, and displaying the two-dimensional model and the three-dimensional model corresponding to the field project picture on the operation interface;

receiving an observation instruction, and executing observation operation associated with the building model according to the observation instruction; the observation instruction comprises a current visual angle amplification observation instruction, a moving visual angle observation instruction, a gravity sensing observation instruction, a through-wall observation instruction or/and a return initial visual angle observation instruction; one implementation of performing observation operations associated with the building model in accordance with the observation instructions includes:

when the current visual angle amplification observation instruction is received on the building model, acquiring the position of the current visual angle amplification observation instruction on the building model, and amplifying the position;

when the mobile visual angle observation instruction is received on the building model, the mobile visual angle of the mobile visual angle observation instruction on the building model is obtained, and the position and the direction corresponding to the mobile visual angle are displayed in real time;

when the gravity sensing observation instruction is received on the building model, acquiring a moving visual angle moving along with gravity on the building model through gravity sensing;

receiving the through-wall observation instruction on one wall body in the building model, penetrating the wall body and displaying a three-dimensional model in the wall body;

and receiving the observation instruction of returning the initial visual angle on the building model, and switching the current visual angle to the original preset visual angle.

2. A management system for a field project, comprising:

the storage module is used for storing the building model of the field project; the building model is built based on a model file of a field project;

a display module for displaying the building model;

the measurement operation module is used for receiving a measurement instruction and executing measurement operation associated with the building model according to the measurement instruction; the measuring instruction comprises a first instruction for measuring the distance between two points and a second instruction for measuring the distance between two objects; the measurement operation module receives the first instruction, searches coordinates of two points triggered by a user on the building model, and calculates the distance between the two points according to the coordinates of the two points; calculating the actual distance between the two points according to the proportion of the building model to the field project; or the measurement operation module receives the second instruction, searches for two objects triggered by the user on the building model, calculates the geometric center coordinates of the two objects, and calculates the distance between the two objects according to the geometric center coordinates of the two objects; calculating the actual distance between the two objects according to the proportion of the building model to the field project;

the positioning operation module is used for receiving a positioning instruction and executing positioning operation associated with the building model according to the positioning instruction; the positioning instruction comprises a model positioning instruction and a field positioning instruction; providing a model position location component on the architectural model, the model position location component for providing an interface for receiving the model location instructions; one implementation process of the positioning operation module executing the positioning operation associated with the building model according to the positioning instruction comprises the following steps: receiving a model positioning instruction, and acquiring the area position of the model positioning instruction on the building model; displaying the two-dimensional model and the three-dimensional model corresponding to the area position on an operation interface; the two-dimensional model and the three-dimensional model are linked to respond to the model positioning instruction; providing a field locating component on the building model, wherein the field locating component is used for providing an interface for receiving the field locating instruction; the positioning operation module receives a field positioning instruction and enters a field project picture capturing mode; searching a two-dimensional model and a three-dimensional model corresponding to the captured field project picture on the building model according to the captured field project picture, and displaying the two-dimensional model and the three-dimensional model corresponding to the field project picture on the operation interface;

the observation operation module is used for receiving an observation instruction and executing the observation operation associated with the building model according to the observation instruction; the observation instruction comprises a current visual angle amplification observation instruction, a moving visual angle observation instruction, a gravity sensing observation instruction, a through-wall observation instruction or/and a return initial visual angle observation instruction;

when the observation operation module receives the current view angle amplification observation instruction on the building model, acquiring the position of the current view angle amplification observation instruction on the building model, and amplifying the position;

when the observation operation module receives the observation instruction of the mobile visual angle on the building model, acquiring the mobile visual angle of the observation instruction of the mobile visual angle on the building model, and displaying the position and the direction corresponding to the mobile visual angle in real time;

when the observation operation module receives the gravity sensing observation instruction on the building model, acquiring a moving visual angle moving along with gravity on the building model through gravity sensing;

the observation operation module receives the through-wall observation instruction on one wall body in the building model, penetrates the wall body and displays a three-dimensional model in the wall body;

and the observation operation module receives the observation instruction of returning the initial visual angle on the building model and switches the visual angle to the original preset visual angle.

3. A computer-readable storage medium on which a computer program is stored, the program, when being executed by a processor, implementing the method of managing a field project of claim 1.

4. A terminal, comprising: a processor and a memory;

the memory is used for storing a computer program, and the processor is used for executing the computer program stored by the memory so as to make the terminal execute the field project management method according to claim 1.

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