CN107688908A - Study and judge the method and device of construction safety risk - Google Patents
Study and judge the method and device of construction safety risk Download PDFInfo
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Abstract
The embodiment of the present application provides a kind of method and device for studying and judging construction safety risk, wherein, method includes:Axle net is put in three-dimensional scenic, axle net is bound with BIM models, and BIM models are bound with working procedure, and BIM models include BIM models, risk source BIM models, the monitoring point BIM models of station main body;Risk source and monitoring point are obtained respectively from risk source BIM models and monitoring point BIM models, pass through the monitor value in monitoring point numbering co-related risks source and monitoring point and monitoring point;Excavation models are extracted from the three-dimensional scenic for having put axle net, and working procedure is associated with excavation models;Relation between the BIM models of excavation models and monitor value is associated with according to practice of construction progress display, to study and judge construction safety risk, practice of construction progress is associated with working procedure.The embodiment of the present invention realizes organically links together monitor value with BIM models in real time, further can be according to practice of construction progress control and positioning security risk.
Description
Technical field
The invention relates to construction safety technical field, more particularly to a kind of method for studying and judging construction safety risk and
Device.
Background technology
At present, the fast development of urbanization, the rapid growth of urban public transport is constantly stimulated.In urban public transport system
In system, subway is important part, and for the public transportation system of megalopolis, subway is increasingly becoming bone
It is dry.
And subway work is that a risk is higher, engineering of technical sophistication, due to objective complicated unfavorable geological condition, is applied
The reason for subjective unsafe acts of worker person and surrounding enviroment, technology etc., cause geological disaster and engineering accident
Situation happens occasionally, thus can seriously endanger subway work safely, cause the duration delay, increase cost consumption.
In order to improve subway work safety management level, avoid due to a series of adverse effects caused by safety problem, closely
Nian Lai, the solution of correlation is provided in the prior art, still, in the scheme provided in the prior art, live monitoring number
According to area of space building structure agent model lack organically contact in real time, cause can not with practice of construction progress control with
Positioning security risk, security risk mechanism is indefinite, causes the less efficient of risk management, and contingency occurrence probability is higher,
Construction cost is higher, and the construction safety of track traffic is difficult to ensure, economic interests are difficult to maximize.
The content of the invention
In view of this, one of technical problem that the embodiment of the present invention solves is that providing one kind studies and judges construction safety risk
Method and device, to overcome or alleviate drawbacks described above of the prior art.
The embodiment of the present application provides a kind of method for studying and judging construction safety risk, and it includes:
Axle net is put in three-dimensional scenic, the axle net is bound with the BIM models, the BIM models and construction work
Sequence is bound, and the BIM models include BIM models, risk source BIM models, the monitoring point BIM models of station main body;
Risk source and monitoring point are obtained respectively from the risk source BIM models and monitoring point BIM models, pass through the monitoring
Point numbering associates the risk source and the monitor value of the monitoring point and the monitoring point;
Extract excavation models from the three-dimensional scenic for having put the axle net, and by the working procedure with it is described
Excavation models associate;
It is associated with according to practice of construction progress display between the BIM models of the excavation models and the monitor value
Relation, to study and judge construction safety risk, the practice of construction progress is associated with the working procedure.
The embodiment of the present invention also provides a kind of device for studying and judging construction safety risk, and it includes:
Unit is put, for axle net to be put in three-dimensional scenic, the axle net is bound with the BIM models, the BIM
Model is bound with working procedure, and the BIM models include BIM models, risk source BIM models, the monitoring point BIM moulds of station main body
Type;
Associative cell, for obtaining risk source and monitoring respectively from the risk source BIM models and monitoring point BIM models
Point, the risk source and the monitor value of the monitoring point and the monitoring point are associated by monitoring point numbering;
Extraction unit, for extracting excavation models from the three-dimensional scenic for having put the axle net, and by described in
Working procedure associates with the excavation models;
Unit is studied and judged, for being associated with the BIM models and the institute of the excavation models according to practice of construction progress display
The relation between monitor value is stated, to study and judge construction safety risk, the practice of construction progress is associated with the working procedure.
In the above-mentioned technical proposal of the offer of the embodiment of the present application, by the way that axle net is put in three-dimensional scenic, the axle
Net is bound with the BIM models, and the BIM models are bound with working procedure, from the risk source BIM models and monitoring point BIM
Model obtains risk source and monitoring point respectively, and the risk source and the monitoring point and institute are associated by monitoring point numbering
The monitor value of monitoring point is stated, extracts excavation models from the three-dimensional scenic for having put the axle net, and by the construction
Process associates with the excavation models, according to practice of construction progress display be associated with the BIM models of the excavation models with
Relation between the monitor value, to study and judge construction safety risk, it is achieved thereby that monitor value is organic with BIM models in real time
Link together, further can be according to practice of construction progress control and positioning security risk so that security risk mechanism
It is more clear and definite, the efficiency of risk management is improved, reduces contingency occurrence probability, while construction cost is reduced, it ensure that rail
The construction safety of road traffic, realize the maximization of economic interests.
Brief description of the drawings
Be described in detail by way of example, and not by way of limitation with reference to the accompanying drawings hereinafter the embodiment of the present application some are specific
Embodiment.Identical reference denotes same or similar part or part in accompanying drawing.Those skilled in the art should manage
Solution, what these accompanying drawings were not necessarily drawn to scale.In accompanying drawing:
Fig. 1 is the method flow schematic diagram that construction safety risk is studied and judged in the embodiment of the present application one;
Fig. 2 is to show the subway line with coordinate value and car thereon in the embodiment of the present application two in the three-dimensional scenic
The schematic flow sheet of website;
Fig. 3 is the exemplary flow schematic diagram of step S131 in the embodiment of the present application three;
Fig. 4 is the schematic diagram of the axis net of the embodiment of the present application four;
Fig. 5 is to be put axle net in the coordinate system of three-dimensional scenic according to angular view coordinate in the embodiment of the present application five to illustrate
Figure;
Fig. 6 is the stream for the coordinate that three axle net nodes in axle net not on the same line are determined in the embodiment of the present application six
Journey schematic diagram;
Fig. 7 is the risk source numbering schematic diagram of the embodiment of the present application seven;
Fig. 8 is that source numbering schematic diagram is monitored in the embodiment of the present application eight;
Fig. 9 is the apparatus structure schematic diagram that construction safety risk is studied and judged in the embodiment of the present invention nine.
Embodiment
All advantages for reaching the above simultaneously must be not necessarily required to by implementing any technical scheme of the embodiment of the present invention.
In order that those skilled in the art more fully understand the technical scheme in the embodiment of the present invention, below in conjunction with the present invention
Accompanying drawing in embodiment, the technical scheme in the embodiment of the present invention is clearly and completely described, it is clear that described reality
It is only part of the embodiment of the embodiment of the present invention to apply example, rather than whole embodiments.Based on the implementation in the embodiment of the present invention
Example, the every other embodiment that those of ordinary skill in the art are obtained, it should all belong to the scope that the embodiment of the present invention is protected.
Specific implementation of the embodiment of the present invention is further illustrated with reference to accompanying drawing of the embodiment of the present invention.
In the above-mentioned technical proposal of the offer of the embodiment of the present application, by the way that axle net is put in three-dimensional scenic, the axle
Net is bound with the BIM models, and the BIM models are bound with working procedure, from the risk source BIM models and monitoring point BIM
Model obtains risk source and monitoring point respectively, and the risk source and the monitoring point and institute are associated by monitoring point numbering
The monitor value of monitoring point is stated, extracts excavation models from the three-dimensional scenic for having put the axle net, and by the construction
Process associates with the excavation models, according to practice of construction progress display be associated with the BIM models of the excavation models with
Relation between the monitor value, to study and judge construction safety risk, it is achieved thereby that monitor value is organic with BIM models in real time
Link together, further can be according to practice of construction progress control and positioning security risk so that security risk mechanism
It is more clear and definite, the efficiency of risk management is improved, reduces contingency occurrence probability, while construction cost is reduced, it ensure that rail
The construction safety of road traffic, realize the maximization of economic interests.
Alternatively, in one embodiment of this invention, in addition to:Show the target pair with coordinate value in three-dimensional scenic
As the step specifically may include:The line number evidence of destination object is converted into the point data of destination object, and therefrom extracts target
The coordinate value of object, the coordinate value are station point data as the position coordinates of subway line bus loading zone.
Alternatively, in one embodiment of this invention, axle net is put in three-dimensional scenic by following step:It is if described
The coordinate system of axle net is different from the coordinate system of the three-dimensional scenic, and the coordinate of unknown, the described axle net of the coordinate system of the axle net
When system and the also unknown common point of the coordinate system of the three-dimensional scenic, according to the angular view coordinate of setting, axle net is put into three-dimensional
Scene;If the coordinate system of the axle net is identical with the coordinate system of the three-dimensional scenic, according to from the axle net not with always
The coordinate of three axle net nodes on line, axle net is put in three-dimensional scenic.
Alternatively, in one embodiment of this invention, in addition to:Break Row is entered in axis intersection to the axle net, and
Network analysis is carried out to obtain the coordinate of axis joining to the netting twine interrupted, and selects not exist from all axis joinings
The coordinate of at least three nodes on same straight line.
Alternatively, in one embodiment of this invention, network analysis is carried out to obtain axis joining to the netting twine interrupted
Coordinate include:Network analysis is carried out to the axis interrupted and obtains the point data of the destination object containing axis beginning and end;
The point data of the destination object containing axis beginning and end is carried out into space with the axis being interrupted to be connected;Reject space connection
The point data that quantity is less than 2 is connected afterwards, obtains the point data of axis joining;According to the point data of axis joining, institute is obtained
There is the coordinate of axis joining;The coordinate of at least three nodes not on the same line is selected from all axis joinings.
In the following embodiments of the present invention, illustrated exemplified by studying and judging the security risk in subway work scene, therefore, mesh
Mark object is subway line,
Fig. 1 is the method flow schematic diagram that construction safety risk is studied and judged in the embodiment of the present application one;As shown in figure 1, it is wrapped
Include following steps S101-S107:
S101, three-dimensional GIS platform established based on OpenGL, three-dimensional scenic is established in three-dimensional GIS platform and in the three-dimensional
Subway line of the displaying with coordinate value and station point thereon in scene;
In the present embodiment, specifically using the satellite high definition image and DEM of subway line region as data medium, generation three
The three-dimensional slice of dimension ground scape, then issuing service is carried out to three-dimensional slice, after issuing service, obtained by three-dimensional GIS platform described in
Service, so as to show the three-dimensional scenic of subway line region in three-dimensional GIS platform and tool is shown in the three-dimensional scenic
There are coordinate value subway line and station point thereon.
In the present embodiment, the point data of subway line is converted to especially by by the line number evidence of subway line, then therefrom carry
The coordinate value of subway line and its website of getting on the bus is taken out, the coordinate value can be specifically latitude and longitude value.
Station Design axle net on S102, foundation subway line, and establish station agent structure BIM models, risk source BIM
Model, monitoring point BIM models, then by station agent structure BIM models, risk source BIM models, monitoring point BIM models with it is described
Axle net is bound;
In the present embodiment, setting, axle is online, to consider station agent structure BIM models, risk source BIM models, prison
Measuring point BIM models are in the online position of axle, can subsequently be bound.
In the present embodiment, station agent structure BIM models are such as related to the information such as the bracing members of station main body, wall.
In this implementation, risk source BIM models are such as related to the letter such as house, optical fiber, signal tower, sewage pipe, gas pipeline
Breath.
In the present embodiment, monitoring point BIM models ratio is such as relating to some monitoring points being arranged on around risk source.
In the present embodiment, station agent structure BIM models, risk source BIM models, monitoring can be specifically established based on axle net
Point BIM models, because the relative position of all BIM models and axle net is fixed all the time, in the binding between carrying out them
Relative position connection is created, accordingly even when axle net position is varied from, as long as axle net ensures the relative position with BIM models
Put, BIM models can changes with the change of axle net position.
S103, the axle net for having bound above-mentioned BIM models put in the coordinate system of the three-dimensional scenic;
In the present embodiment, if the coordinate system of the axle net is different from the coordinate system of the three-dimensional scenic, and the axle net
When the common point of the coordinate system of unknown, the described axle net of coordinate system and the coordinate system of the three-dimensional scenic is also unknown, according to setting
Angular view coordinate, axle net is put in three-dimensional scenic.
In the present embodiment, due in step s 102, due to the relative position of BIM models and axle net being had been carried out tying up
It is fixed, so, the axle net corresponding to selection during BIM models to be imported to three-dimensional GIS platform can be with automatic putting based on axle net
Good BIM models are in the online position of axle.
S104, the BIM models bound will be carried out with axle net and working procedure is bound;
In the present embodiment, BIM models are bound with working procedure, so as to establish BIM models and working procedure it
Between corresponding relation.
In the present embodiment, specifically axle net and working procedure decomposition texture (Work Breakdown Structure) are carried out
Binding, due to being provided with process title, corresponding actual time started and physical end time etc. in working procedure decomposition texture
Attribute field, the binding of BIM models and working procedure is realized, practice of construction progress, and root can be made a report in work progress
Factually border construction speed carries out the displaying of BIM models.
S105, from the risk source BIM models and monitoring point BIM models risk source and monitoring point are obtained respectively, pass through institute
State monitoring point numbering and associate the risk source and the monitor value of the monitoring point and the monitoring point;
In the present embodiment, the monitor value of monitoring point is specially this observation of monitoring point, and this observation is included but not
It is limited to horizontal displacement value, sedimentation value, the axle power value for monitoring pipeline, bracing members, earth's surface etc..
When obtaining risk source and monitoring point, risk source information and monitoring point information, risk source information ratio can be read
Such as include risk source name, risk source numbering, risk class;Monitoring point information such as includes monitoring point numbering etc., while can
To obtain the recording of each risk source information of its monitoring, the record of each monitoring point information.
Wherein, in the case of there are a variety of numberings a monitoring point (i.e. a monitoring point monitors polytype situation),
A plurality of record is generated according to the multiple monitoring points numbering read.
It is whether identical as decision condition with risk source numbering using the first three items of monitoring point numbering in association, if prison
Measuring point numbering first three items are identical with risk source numbering, then this monitoring point is to monitor the risk source, new in data of monitoring point table
The risk source that an ID number records its ownership is built, while increases one newly in risk source data table and records monitoring point associated with it,
So as to complete associating for risk source and monitoring point.The record of Monitoring Data (or referred to as monitor value) is also based on monitoring point volume
Number recorded, thus can number according to monitoring point and then risk source, monitoring point are subjected to binding with Monitoring Data and associate.
S106, extract excavation models from the three-dimensional scenic for having put the axle net, and by the working procedure
Associated with the excavation models;
In the present embodiment, specifically, according to the foundation ditch standard paragraphs cutting depth in design drawing, width etc., and put
Good axle net, with reference to the location-based service in GIS spaces, is automatically positioned in three-dimensional scenic and draws out the two dimensional range of foundation ditch, profit
It is excavation models to stretch two-dimentional foundation ditch scope with excavation of foundation pit depth value.
S107, the BIM models of the excavation models and the monitor value are associated with according to practice of construction progress display
Between relation, to study and judge construction safety risk;
Specifically, by establishing interface with working procedure work breakdown structure (WBS), working procedure is called, is carrying out practice of construction
During progress is made a report on, working procedure corresponding to selection, so as to which practice of construction progress and working procedure work breakdown structure (WBS) be carried out
Binding.With making a report on for practice of construction progress, working procedure corresponding to activation and corresponding BIM models, including station body junction
Structure BIM models, risk source model, monitoring point model, correspondingly, monitoring frequency and monitor value the entering with construction speed of monitoring point
Row is also changing, and may thereby determine that BIM models and monitors the relation between value changes, further studies and judges construction safety risk,
And it can finally navigate to corresponding construction part.
Fig. 2 is to show the subway line with coordinate value and car thereon in the embodiment of the present application two in the three-dimensional scenic
The schematic flow sheet of website;As shown in Fig. 2 it specifically comprises the following steps S111-S141:
S111, the electronic map raster data for obtaining the affiliated physical region of subway line, and the line number evidence of subway line;
In the present embodiment, it can specifically utilize waterfront economy software download and obtain the electronics of the affiliated physical region of subway line
Map raster data.Specifically, the electronic map raster data can be high moral electronic map raster data.
In the present embodiment, specifically vector quantization subway line data can be carried out using ESRI (Yi Zhirui) ARCGIS instruments,
Obtain the line number evidence of subway line;The line number is according to the line number evidence for being specifically as follows shape forms.Further, vector is being carried out
When changing processing, in each station point-rendering node of subway line, with the convenient extraction station point in subsequent step S121
Point data.
S121, the electronic map raster data to the affiliated physical region of subway line carry out vector quantization, obtain subway line
Get on the bus the point data of website;
In the present embodiment, vector quantization can be specifically carried out using ArcMap, the subway line is got on the bus the line number evidence of website
It is specifically as follows the line number evidence of shape forms.
S131, by the line number of subway line according to the point data for being converted to subway line, and therefrom obtain each on subway line
The coordinate of individual node, and from the coordinate for extracting station point and assign property value;
In the present embodiment, it can specifically pass through Feature Vertices To Points (the key element nodes in ArcMap
Turning point) by the line number of subway line according to the point data for being converted to subway line, and obtained automatically by computational geometry instrument each
The coordinate of node.
S141, the coordinate of each node on subway line imported into three-dimensional GIS platform, by the property value of station point and
The coordinate of station point is imported into three-dimensional GIS platform.
, can be first by subway line when the coordinate of each node on subway line is imported in three-dimensional GIS platform in the present embodiment
The coordinate of each node is stored in the text of .Lpip forms on road, by the way that the text is imported into three-dimensional GIS platform, so as to
The coordinate of each node on subway line is imported into three-dimensional GIS platform by final realize.
In the present embodiment, in three-dimensional GIS platform during the coordinate of the property value of importing station point and station point, Ke Yixian
The coordinate of the property value of station point and station point is stored in the text of .scrm forms, by the way that the text is imported into three
Tie up in GIS platform, the coordinate of the property value of station point and station point is imported into three-dimensional GIS platform from finally realizing.
In the present embodiment, in specific application, long distance line data import tool can be opened in three-dimensional GIS platform
Import the text of .lpip forms;The text that mark import tool imports .scrm forms is opened in three-dimensional GIS platform, in three-dimensional
In scene, all stations on this subway line are preferably marked in a manner of drawing pin and word combine.
Fig. 3 is the exemplary flow schematic diagram of step S131 in the embodiment of the present application three;It comprises the following steps S1311-
S1315:
S1311, start key element node turning point.
In the present embodiment, ArcToolbox instruments are loaded especially by ArcMap, are then opened under ArcToolbox
Data Management Tools (data organizing tool), then open the Features under Data Management Tools
(key element) instrument, Feature Vertices To Points (key element nodes are finally found from Features (key element) instrument
Turning point) instrument and double-click opening.
S1312, the subway line shape formatted datas according to input, and the output file title of definition, by subway line
All nodes switch to a little, obtain the point data on subway line in route data.
Subway line shape formatted datas in the present embodiment are specially the subway line obtained in above-mentioned steps S111
Line number evidence.
S1313, the node data attribute list according to subway line, and increased coordinate set field, obtain each section
The coordinate of point, obtain carrying the point data of coordinate on subway line.
In the present embodiment, it can specifically pass through the attribute list of opening point (node) data in ArcMap, new field Lon
(as longitude data field), Lat (as latitude data field), choose field row to click on geometry respectively and calculate, automatically obtain
The coordinate value of each node, obtain the shape form point datas of the subway line node with coordinate value, the subway line node
Shape forms point data as on subway line carry coordinate point data.
S1314, loading point (node) data and electronic map raster data with coordinate value, according to electronic map grid
Data choose the point (node) of each site location, obtain the website shape formatted datas with coordinate value.
In the present embodiment, equivalent to selecting node corresponding to website from all nodes, and then the points of website are obtained
According to i.e. website shape forms point data.
S1315, the name data field in station data attribute list and electronic map raster data, for each station
Point assigns site name, obtains the website shape form point datas with site name.
Fig. 4 is the schematic diagram of the axis net of the embodiment of the present application four;As shown in figure 4, axle net includes axis of pitch and longitudinal axis
The distance between line, axis of pitch is simultaneously non-constant, and the distance of longitudinal axis is equally also and non-constant, each horizontal horizontal line and vertical
There are the alphabetical A-F in an exclusive number, such as figure, digital 1-8 to horizontal line, carried out by above-mentioned BIM models and axle net
During binding, just when with defining BIM models in the position of axle net.
Fig. 5 is to be put axle net in the coordinate system of three-dimensional scenic according to angular view coordinate in the embodiment of the present application five to illustrate
Figure;Using camera from diverse location, the left picture points right with E of two width imaging surface E for obtaining same testee W in three-dimensional scenic is divided
Not Wei Q1 and Q2, the two picture points are testee W picture, according to the position deviation of the two picture points, establish the two pictures
Visual angle relation between point, so as to obtain the inside and outside parameter of camera, finally sets angular view coordinate.
Or in an other embodiment, camera can also be utilized to define vision and sight when watching three-dimensional scenic.Tool
Body, in three-dimension GIS scene, the parameter such as angle, height and gradient by setting camera, so as to set angular view coordinate.
In the present embodiment, angular view coordinate is specially for the setting of a wherein station.
After angular view coordinate is set, when putting, the angular view coordinate at the station is extracted, in order to confirm the general of axle net
Operation is put in putting position, the craft for reducing axle net.
In actual applications, after completing the putting of above-mentioned axle net using angular view coordinate, if the putting position of axle net and reality
The real position deviation at middle station is larger or undesirable, can be operated by coordinate moving operation and/or attitude angle into
One step carries out the correction of putting position, and coordinate moving operation is such as a laterally left side (right side) shifting, the upper (lower) shifting in longitudinal direction, horizontal rising
(decline) etc., attitude angle operation such as turn for a left side (right side) about the z axis, turned around X-axis left (right side), around Y-axis left (right side) turn etc..
In the present embodiment, if the coordinate system of the axle net is identical with the coordinate system of the three-dimensional scenic, according to from the axle
The coordinate of three axle net nodes in net not on the same line, axle net is specifically put into three-dimensional scenic and correspondingly constructed station
Construction location.
In the present embodiment, especially by entering Break Row in axis intersection to the axle net, and the netting twine to interrupting is carried out
Network analysis is to obtain the coordinate of axis joining, and selects from all axis joinings not on the same line at least
The coordinate of three nodes.
In the present embodiment, network analysis is carried out to the netting twine interrupted and specifically included with obtaining the coordinate of axis joining:It is right
The axis interrupted carries out network analysis and obtains the point data of the destination object containing axis beginning and end;Axis starting point will be contained
Space is carried out with the point data of the destination object of terminal with the axis being interrupted to be connected;Connection quantity is less than after rejecting space connection
2 point data, obtain the point data of axis joining;According to the point data of axis joining, all axis joinings are obtained
Coordinate;The coordinate of at least three nodes not on the same line is selected from all axis joinings.
Fig. 6 is the stream for the coordinate that three axle net nodes in axle net not on the same line are determined in the embodiment of the present application six
Journey schematic diagram, it comprises the following steps S113-S163:
S113, axle net interrupted in axis intersection;
In the present embodiment, by the way that axle net is interrupted in axis intersection, the line chart layer interrupted in axis intersection is obtained
ZXLines。
In the present embodiment, it can specifically utilize and open custom menu → command entry → topology successively in ArcMap softwares
→ interrupt interrupting for intersecting lens (Planarize Lines) instrument progress axis intersection.
S123, by the axis being interrupted carry out network analysis;
In the present embodiment, specifically the netting twine interrupted is entered using new network dataset (New-deployed Network data set)
Row network analysis.
Specifically, in network analysis, line chart layer ZXLines is subjected to New-deployed Network data set, so as to obtain in axle net
The point figure layer such as all crossing point of axes, beginning and end of axis ZXPoints.
S133, the point data containing axis beginning and end obtained through network analysis and the axis data progress being interrupted
Space connects;
Specifically, point figure layer ZXPoints and line chart layer ZXLines are carried out into space to be connected, made with a figure layer ZXPoints
Be target component, line chart layer ZXLines as nexus element, obtain new point figure layer after performing space connection
SpatialJoinPoints, new point figure layer increase " connection quantity " field newly automatically, and the field record has space company with each point
The number of the line connect.
It is small in field " connection quantity " field increased newly in the point data attribute list that S143, rejecting obtain after space connects
In 2 point, the point data of axis joining is obtained;
The beginning or end of as axis of the numerical value less than 2, is equal in " connection quantity " field obtained in step W3
Or the intersection point of the as axis more than 2.The point that " connection quantity " field is less than 2 is deleted, obtains the points of original axis joining
According to (figure layer) ZXJoinPoints.
S153, the point data to axis joining carry out geometry calculating, obtain the coordinate value of all axis joinings;
In the present embodiment, referring to the schematic diagram of above-mentioned axle net, joining is each axis of pitch and each longitudinal axis
Line has the point of cross reference.
S163, appoint take not in the coordinate value of collinear at least three joining;
In the present embodiment, preferably appoint and take three joinings to meet to put demand in axle net to three-dimensional scenic coordinate,
Further, these three joinings are preferably placed at the borderline joining of axle net.
Fig. 7 is the risk source numbering schematic diagram of the embodiment of the present application seven;As shown in fig. 7, its coding rule is:Station name of station
Title acronym+risk source name+three Arabic numerals of acronym.It is bright with No. 7 Xian Douge village of Beijing Metro station
Dig exemplified by foundation ditch (risk source), risk source numbering is then:DGZ (Dou Ge village title acronym)-JK (foundation ditch title lead-ins
Mother's abbreviation) -001 (in order number number this risk source).
Fig. 8 is that source numbering schematic diagram is monitored in the embodiment of the present application eight;As shown in figure 8, monitoring point numbering is:Station name of station
Title acronym++ three Arabic numerals of risk source name acronym+monitoring object title acronym+three
Position Arabic numerals.By taking a surface subsidence monitoring point in the open-cut foundation ditch of No. 7 Xian Douge village of Beijing Metro station as an example, the monitoring point
Numbering then (number numbers this wind in order for DGZ (Dou Ge village title acronym)-JK (foundation ditch title acronym) -001
Dangerous source)-DBCJ (ground settlement title acronym) -001 (in order number number this monitoring point).
Fig. 9 is the apparatus structure schematic diagram that construction safety risk is studied and judged in the embodiment of the present invention nine;As shown in figure 9, it is wrapped
Include:
Unit 901 is put, for axle net to be put in three-dimensional scenic, the axle net is bound with the BIM models, described
BIM models are bound with working procedure, and the BIM models include the BIM models, risk source BIM models, monitoring point of station main body
BIM models;
Associative cell 902, for obtaining risk source and prison respectively from the risk source BIM models and monitoring point BIM models
Measuring point, the risk source and the monitor value of the monitoring point and the monitoring point are associated by monitoring point numbering;
Extraction unit 903, for extracting excavation models from the three-dimensional scenic for having put the axle net, and by institute
Working procedure is stated to associate with the excavation models;
Study and judge unit 904, for be associated with according to practice of construction progress display the BIM models of the excavation models with
Relation between the monitor value, to study and judge construction safety risk, the practice of construction progress is associated with the working procedure.
Alternatively, in one embodiment of this invention, it is described put unit 901 be used for when the axle net coordinate system and institute
When stating the coordinate system difference of three-dimensional scenic, and the coordinate system of unknown, the described axle net of the coordinate system of the axle net and the three dimensional field
When the common point of the coordinate system of scape is also unknown, according to the angular view coordinate of setting, axle net is put in three-dimensional scenic.
Alternatively, in one embodiment of this invention, it is described put unit 901 be used for when the axle net coordinate system and institute
State three-dimensional scenic coordinate system it is identical when, according to the coordinate of three axle net nodes from the axle net not on the same line,
Axle net is put in three-dimensional scenic.
Alternatively, in one embodiment of this invention, the unit 901 of putting is used for the axle net in axis intersection
Enter Break Row, and the netting twine to interrupting carries out network analysis to obtain the coordinate of axis joining, and from all axis joinings
The coordinate of at least three nodes of middle selection not on the same line.
Alternatively, in one embodiment of this invention, the unit 901 of putting is used to carry out network point to the axis interrupted
Analysis obtains the point data of the destination object containing axis beginning and end, by the point of the destination object containing axis beginning and end
Data carry out space with the axis being interrupted and are connected, and connect the point data that quantity is less than 2 after rejecting space connection, obtain axis phase
The point data of intersection point, according to the point data of axis joining, the coordinate of all axis joinings is obtained, from all axis joinings
The coordinate of at least three nodes of middle selection not on the same line.
Device embodiment described above is only schematical, wherein the module illustrated as separating component can
To be or may not be physically separate, it can be as the part that module is shown or may not be physics mould
Block, you can with positioned at a place, or can also be distributed on multiple mixed-media network modules mixed-medias.It can be selected according to the actual needs
In some or all of module realize the purpose of this embodiment scheme.Those of ordinary skill in the art are not paying creativeness
Work in the case of, you can to understand and implement.
Through the above description of the embodiments, those skilled in the art can be understood that each embodiment can
Realized by the mode of software plus required general hardware platform, naturally it is also possible to pass through hardware.Based on such understanding, on
The part that technical scheme substantially in other words contributes to prior art is stated to embody in the form of software product, should
Computer software product can store in a computer-readable storage medium, the computer readable recording medium storing program for performing include be used for
The readable form storage of computer (such as computer) or any mechanism of transmission information.For example, machine readable media is included only
Read memory (ROM), random access memory (RAM), magnetic disk storage medium, optical storage media, flash medium, electricity, light,
Sound or the transmitting signal of other forms (for example, carrier wave, infrared signal, data signal etc.) etc., the computer software product includes
Some instructions are each to cause a computer equipment (can be personal computer, server, or network equipment etc.) execution
Method described in some parts of individual embodiment or embodiment.
It will be understood by those skilled in the art that the embodiment of the embodiment of the present invention can be provided as method, apparatus (equipment) or
Computer program product.Therefore, the embodiment of the present invention can use complete hardware embodiment, complete software embodiment or combine soft
The form of the embodiment of part and hardware aspect.Moreover, the embodiment of the present invention can use wherein includes calculating in one or more
The computer-usable storage medium of machine usable program code (includes but is not limited to magnetic disk storage, CD-ROM, optical memory
Deng) on the form of computer program product implemented.
The embodiment of the present invention is with reference to method, apparatus (equipment) according to embodiments of the present invention and computer program product
Flow chart and/or block diagram describe.It should be understood that can be by every in computer program instructions implementation process figure and/or block diagram
One flow and/or the flow in square frame and flow chart and/or block diagram and/or the combination of square frame.These computers can be provided
Processor of the programmed instruction to all-purpose computer, special-purpose computer, Embedded Processor or other programmable data processing devices
To produce a machine so that produce use by the instruction of computer or the computing device of other programmable data processing devices
In the dress for realizing the function of being specified in one flow of flow chart or multiple flows and/or one square frame of block diagram or multiple square frames
Put.
These computer program instructions, which may be alternatively stored in, can guide computer or other programmable data processing devices with spy
Determine in the computer-readable memory that mode works so that the instruction being stored in the computer-readable memory, which produces, to be included referring to
Make the manufacture of device, the command device realize in one flow of flow chart or multiple flows and/or one square frame of block diagram or
The function of being specified in multiple square frames.
These computer program instructions can be also loaded into computer or other programmable data processing devices so that counted
Series of operation steps is performed on calculation machine or other programmable devices to produce computer implemented processing, so as in computer or
The instruction performed on other programmable devices is provided for realizing in one flow of flow chart or multiple flows and/or block diagram one
The step of function of being specified in individual square frame or multiple square frames.
Finally it should be noted that:Above example is only to illustrate the technical scheme of the embodiment of the present application, rather than it is limited
System;Although the application is described in detail with reference to the foregoing embodiments, it will be understood by those within the art that:Its
The technical scheme described in foregoing embodiments can still be modified, or which part technical characteristic is equal
Replace;And these modifications or replacement, the essence of appropriate technical solution is departed from each embodiment technical scheme of the application
Spirit and scope.
Claims (12)
- A kind of 1. method for studying and judging construction safety risk, it is characterised in that including:Axle net is put in three-dimensional scenic, the axle net is bound with BIM models, and the BIM models are bound with working procedure, institute Stating BIM models includes BIM models, risk source BIM models, the monitoring point BIM models of station main body;Risk source and monitoring point are obtained respectively from the risk source BIM models and the monitoring point BIM models, pass through the monitoring Point numbering associates the risk source and the monitor value of the monitoring point and the monitoring point;Extract excavation models from the three-dimensional scenic for having put the axle net, and by the working procedure and the foundation ditch Model interaction;Pass between the BIM models of the excavation models and the monitor value is associated with according to practice of construction progress display System, to study and judge construction safety risk, the practice of construction progress is associated with the working procedure.
- 2. according to the method described in claim 1, it is characterised in that also include:Show in three-dimensional scenic with coordinate value Destination object.
- 3. according to the method for claim 2, it is characterised in that show the destination object with coordinate value in three-dimensional scenic Including:The line number evidence of destination object is converted into the point data of destination object, and therefrom extracts the coordinate value of destination object, institute State position coordinates of the coordinate value as subway line bus loading zone.
- 4. according to the method for claim 1, it is characterised in that put axle net in three-dimensional scenic by following step: If the coordinate system of the axle net is different from the coordinate system of the three-dimensional scenic, and the coordinate system of the axle net is unknown, the axle net Coordinate system and the three-dimensional scenic coordinate system common point it is also unknown when, according to the angular view coordinate of setting, axle net is put To three-dimensional scenic.
- 5. according to the method for claim 1, it is characterised in that put axle net in three-dimensional scenic by following step: If the coordinate system of the axle net is identical with the coordinate system of the three-dimensional scenic, according to from the axle net not on the same line The coordinate of three axle net nodes, axle net is put in three-dimensional scenic.
- 6. according to the method for claim 4, it is characterised in that also include:Enter Break Row in axis intersection to the axle net, and the netting twine to interrupting carries out network analysis to obtain axis joining Coordinate;The coordinate of at least three nodes not on the same line is selected from all axis joinings.
- 7. according to the method for claim 6, it is characterised in that network analysis is carried out to obtain axis phase to the netting twine interrupted The coordinate of intersection point includes:Network analysis is carried out to the axis interrupted and obtains the point data of the destination object containing axis beginning and end;The point data of the destination object containing axis beginning and end is carried out into space with the axis being interrupted to be connected;The point data that quantity is less than 2 is connected after rejecting space connection, obtains the point data of axis joining;According to the point data of axis joining, the coordinate of all axis joinings is obtained;The coordinate of at least three nodes not on the same line is selected from all axis joinings.
- A kind of 8. device for studying and judging construction safety risk, it is characterised in that including:Unit is put, for axle net to be put in three-dimensional scenic, the axle net is bound with BIM models, and the BIM models are with applying Work process is bound, and the BIM models include BIM models, risk source BIM models, the monitoring point BIM models of station main body;Associative cell, for obtaining risk source and monitoring respectively from the risk source BIM models and the monitoring point BIM models Point, the risk source and the monitor value of the monitoring point and the monitoring point are associated by monitoring point numbering;Extraction unit, for extracting excavation models from the three-dimensional scenic for having put the axle net, and by the construction Process associates with the excavation models;Unit is studied and judged, for the BIM models that the excavation models are associated with according to practice of construction progress display and the prison Relation between measured value, to study and judge construction safety risk, the practice of construction progress is associated with the working procedure.
- 9. device according to claim 8, it is characterised in that it is described put unit be used for when the axle net coordinate system and During the coordinate system difference of the three-dimensional scenic, and the coordinate system of unknown, the described axle net of the coordinate system of the axle net and the three-dimensional When the common point of the coordinate system of scene is also unknown, according to the angular view coordinate of setting, axle net is put in three-dimensional scenic.
- 10. device according to claim 8, it is characterised in that it is described put unit be used for work as the axle net coordinate system When identical with the coordinate system of the three-dimensional scenic, according to the seat of three axle net nodes from the axle net not on the same line Mark, axle net is put in three-dimensional scenic.
- 11. device according to claim 10, it is characterised in that the unit of putting is used for the axle net in axis phase Enter Break Row at friendship, and the netting twine to interrupting carries out network analysis to obtain the coordinate of axis joining, and from all axis phases The coordinate of at least three nodes not on the same line is selected in intersection point.
- 12. device according to claim 11, it is characterised in that the unit of putting is used to carry out net to the axis interrupted Network is analyzed to obtain the point data of the destination object containing axis beginning and end, by the destination object containing axis beginning and end Point data carry out space with the axis that is interrupted and be connected, connect the point data that quantity is less than 2 after rejecting space connection, obtain axle The point data of line joining, according to the point data of axis joining, the coordinate of all axis joinings is obtained, from all axis phases The coordinate of at least three nodes not on the same line is selected in intersection point.
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