CN112926150B - Continuous drilling layout method applied to geotechnical engineering investigation industry - Google Patents
Continuous drilling layout method applied to geotechnical engineering investigation industry Download PDFInfo
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Abstract
The invention provides a continuous layout method of drill holes applied to the geotechnical engineering investigation industry, which can organically integrate the contents of all files in a unified project, firstly set or call the drill hole information according to the set contents, lay the simulation drill holes in the current file, set and adjust the serial numbers of the simulation drill holes, add wildcards and carry out coordinate system proofreading so as to perfect the layout information of design holes, and finally store all newly generated information, thereby completing the layout of the drill holes. By the method, the layout of the drill holes in the drawing can be accurately and efficiently carried out, the layout mode of the drill holes can be quickly determined, the specific information of the layout of the drill holes can be obtained, the hole layout information of different files in the same project can be mutually corresponding and effectively combined, and therefore the layout and the management of the drill hole information in the project files are facilitated.
Description
Technical Field
The invention belongs to the technical field of engineering investigation, and particularly relates to a continuous layout method of drill holes applied to the geotechnical engineering investigation industry.
Background
With the rapid development of infrastructure and rail transit, the production scale of the engineering investigation industry is continuously enlarged, the engineering quantity is continuously increased, but the internal management still mostly adopts the traditional manual operation and management mode, and the requirement of business scale development cannot be met. In particular, in a survey outline planning stage, the arrangement amount of the drill holes is large, the information of the drill holes is more (including information such as hole numbers, hole depths, the sizes, angles, colors and fonts of the drill holes), the information of different drill holes is different, statistical analysis and the like are needed according to different attributes after the arrangement of the drill holes is completed, in order to simplify operation, improve the hole arrangement efficiency and reduce manual operation errors. Therefore, how to design and manage the drilling information to complete the drilling layout and statistics quickly becomes a technical problem that needs to be solved urgently by those skilled in the art.
Disclosure of Invention
In order to solve the technical problem, the invention provides a continuous drill hole arrangement method applied to the geotechnical engineering investigation industry.
The specific technical scheme of the invention is as follows:
the invention provides a continuous layout method of drill holes applied to the geotechnical engineering investigation industry, which comprises the following steps:
s1: setting or acquiring attributes and parameters of a drill hole to be laid, wherein the attributes must comprise a control exploration hole or a general exploration hole, and the parameters comprise an aperture and a hole depth;
s2: setting the position of an initial drilling hole, setting or acquiring a layout track of the drilling hole, and laying a plurality of simulated drilling holes according to the layout track;
s3: setting numbers for the simulated drill holes, adding wildcards, performing coordinate system proofreading, and determining the simulated drill holes with the wildcards as design holes and the test holes without the wildcards;
s4: and storing the parameters, the position coordinates and the marking information of the design holes in the database.
Further, in step S1, a specific method for acquiring the attributes and parameters of the borehole to be drilled is as follows:
and selecting the existing drill holes from the database, acquiring the attributes and parameters of the existing drill holes, and copying the attributes and parameters of the existing drill holes into the current file, thereby setting the drill holes to be laid.
Further, when the existing drill hole is a finished hole constructed in other files, the drill hole to be laid is set as a link point, a reference relation is established between the current file and the other files to which the existing drill hole belongs, and the link point can be deleted after the reference relation is released.
Further, in step S2, a specific method for acquiring the layout trajectory of the drill hole is as follows:
and selecting the existing drilling track from the database, acquiring the parameter information of the drilling track, copying the parameter information into a current file, and setting the drilling track at a selected position by taking the initial drilling hole as a starting point to serve as a layout track.
Further, the specific method for laying the simulated borehole is as follows:
arranging placing points at equal intervals on the layout track according to a specific number or interval, and laying the simulated drill holes on each placing point; or calling a group of existing drill holes from the database, and carrying out equal-proportion layout on the layout track.
Further, in step S3, a specific method for numbering the simulated drill holes is as follows:
sequentially setting numbers for all the simulated drill holes from the initial drill hole, and adding wildcards;
checking the numbers of all the drill holes in the project to which the current file belongs to find whether the numbers which are repeated with the simulated drill holes exist or not;
when the repeated serial numbers are found, the serial numbers of the simulated drill holes corresponding to the serial numbers are modified, and the serial numbers of all the simulated drill holes after the simulated drill holes are sequentially modified.
Further, a specific method for checking the numbers of all drill holes in the project to which the current file belongs is as follows:
obtaining available drilling hole numbers according to the number patterns, and generating an available number set;
acquiring all simulated drilling hole numbers in the current file, traversing all drilling hole numbers in the database, and extracting all drilling hole numbers in a project to which the current file belongs;
analyzing each drilling hole number, judging whether the drilling hole numbers accord with the prefix and suffix patterns of the current window, analyzing a drilling hole number set with which the prefix and the suffix both accord, and generating an available number set;
and filling the available number set according to the existing number set, and searching repeated numbers, namely the numbers of the simulated drilling holes needing to be modified.
Further, the specific method of sequentially modifying the numbers of all simulated boreholes after the modified simulated borehole is as follows:
copying the simulated drill holes to be modified and all the subsequent simulated drill holes, confirming that the entity type to be modified is the drill hole, acquiring wildcards and simulated drill hole numbers of all the simulated drill holes, and generating an available simulated drill hole number set;
and reassigning the serial numbers of the simulated drill holes to be modified, sequentially modifying the serial numbers of each simulated drill hole in the available simulated drill hole serial number set according to a preset rule, and correspondingly storing the modified serial numbers and the simulated drill holes to obtain new simulated drill hole serial numbers.
Further, in step S3, a specific method for calibrating the coordinate system of the simulated borehole is as follows:
selecting simulated drill holes to be corrected, obtaining a drill hole type list, and selecting simulated drill holes with wildcards;
reading a picture block of a drill hole with a wildcard character in advance by a background, and inserting the picture block into the current simulated drill hole to obtain a current picture layer; if the current layer is a '0' layer, using the drilling layer, otherwise, using the current layer;
setting the direction of the simulated drilling hole as a current visual angle, picking up the position of the drilling hole in the graph, and dynamically placing the drilling hole in the graph; adding a drill hole, resetting the attribute, the drill hole number, the exploration depth, the label style and the drill hole direction, and reversely rotating from the WCS north to the visual angle; and setting the drilling height, the label position information and the drilling identification line, and storing the calibrated simulation drilling coordinate and the attribute content.
Further, the method comprises the following steps:
s5: calculating mileage values of all the design holes according to the positions of the initial drilling holes and the actual positions of the rest design holes, and storing the mileage values in the database;
the specific method comprises the following steps:
selecting a path curve for reference, selecting the position of the initial drilling hole from the curve path as a reference point, and inputting a reference point mileage value, wherein the reference point mileage value cannot be smaller than 0; and selecting a design hole of which the mileage needs to be calculated, and calculating the distance between the reference point and the design hole on the path curve to obtain the mileage value of the design hole.
The invention has the following beneficial effects: the invention provides a continuous layout method of drill holes applied to the geotechnical engineering investigation industry, which can organically integrate the contents of all outline files in a unified project, firstly set or call the drill hole information according to the set contents, lay the simulation drill holes in the current file, set and adjust the serial numbers of the simulation drill holes, add wildcards and carry out coordinate system proofreading so as to perfect the layout information of design holes, and finally store all newly generated information, thereby completing the layout of the drill holes. By the method, the layout of the drill holes in the drawing can be accurately and efficiently carried out, the layout mode of the drill holes can be quickly determined, the specific information of the layout of the drill holes can be obtained, and the hole layout information of different outline files in the same project can be mutually corresponding and effectively combined, so that the layout and the management of the drill hole information in the project files are facilitated.
Drawings
FIG. 1 is a flow chart of a continuous layout method of drill holes applied to the geotechnical engineering investigation industry according to an embodiment;
FIG. 2 is a window for setting drilling attributes in a system corresponding to the continuous layout method for drilling holes applied to the geotechnical engineering investigation industry according to the embodiment;
FIG. 3 is a schematic diagram of system click layout drilling corresponding to the continuous layout method for drilling applied to geotechnical engineering investigation industry according to the embodiment;
FIG. 4 is an attribute setting window for arranging drill holes along an existing trajectory in a system corresponding to the continuous arrangement method for drill holes applied to the geotechnical engineering investigation industry according to the embodiment;
FIG. 5 is a schematic diagram illustrating a method for continuously laying drill holes according to a specific number on an original trajectory in the geotechnical engineering investigation industry according to the embodiment;
FIG. 6 is a schematic diagram illustrating a continuous arrangement method of drill holes at specific intervals on an original trajectory in the geotechnical engineering investigation industry according to the embodiment;
FIG. 7 is a window for setting a borehole marking pattern in a system corresponding to the continuous layout method for boreholes applied to the geotechnical engineering investigation industry according to the embodiment;
FIG. 8 is a schematic diagram illustrating a whole set of original design holes retrieved in the continuous layout method for drill holes applied to geotechnical engineering investigation industry according to the embodiment;
FIG. 9 is a schematic diagram of a calculation mode of drilling mileage in a system corresponding to the continuous arrangement method of drill holes applied to the geotechnical engineering investigation industry according to the embodiment.
Detailed Description
The present invention will be described in further detail with reference to the following examples and drawings.
Examples
As shown in fig. 1 to 9, the present embodiment provides a continuous layout method of drill holes applied to the geotechnical engineering investigation industry, including the following steps:
s1: the properties of the borehole to be laid, which must contain either a controlled survey hole or a generic survey hole, and parameters including the hole diameter and the hole depth, are set or obtained.
The method comprises the following steps of obtaining the drilling hole attributes and parameters in other files, wherein the obtaining step refers to directly calling the drilling hole attributes and parameters existing in other files, and the specific method comprises the following steps:
selecting the existing drill holes from the database, obtaining the attributes and parameters of the existing drill holes and copying the attributes and parameters into the current file, and setting the drill holes to be laid according to the attributes and parameters.
The borehole property must include a controlled survey hole or a generic survey hole, and if a controlled survey hole is selected, at least one other property (e.g., an earth sample hole, a water sample hole, a rock sample hole, a gas sample hole, an in situ test hole, a wave velocity test hole, a resistivity test hole, a static sounding test hole, etc.) other than the generic survey hole must be selected; parameters may include depth of investigation, aperture elevation, water level elevation, borehole diameter, rotation angle, and the like.
In the specific implementation, if the existing borehole is selected, the attributes and parameters of the borehole cannot be modified, but the borehole can be labeled according to the required pattern (the text information shown in the legend, such as the borehole number, the hole opening elevation, the exploration depth, the water level elevation and the like, and the position of each item of information).
In the implementation process, the drilling holes in other files, whether the holes are designed holes which are not constructed or finished holes which are constructed, can be directly called into the current file. It should be noted that when the referenced existing drilling holes show design holes, the drilling data of other files are directly called and added into the current file, and the reference relationship is not established between the two files, so that any drilling hole can be directly deleted; when the cited existing drill hole is a finished hole, because the existing drill hole is constructed and influences are generated on the current area, the influences generated by the existing drill hole are necessarily introduced together when the existing drill hole is used, the drill hole to be distributed needs to be set as a link point, a reference relation is established between the current file and other files to which the existing drill hole belongs, and the link point can be deleted only after the reference relation is released.
S2: setting the position of the initial drilling hole, setting or acquiring the layout track of the drilling hole, and laying a plurality of simulated drilling holes according to the layout track.
The method for acquiring the layout track comprises the following steps of:
selecting an existing drilling track from a database, acquiring parameter information of the drilling track, copying the parameter information into a current file, and setting the drilling track at a selected position by taking an initial drilling hole as a starting point to serve as a layout track.
When the drilling holes are arranged according to the arrangement track, the holes can be distributed clockwise or anticlockwise; in specific implementation, the specific method for laying the simulated borehole is as follows:
arranging placing points at equal intervals on the layout track according to a specific number or interval, and laying simulated drill holes on each placing point; or a group of existing drill holes are called from the database, and the equal proportion layout is carried out on the layout track.
Through setting the number or the spacing of the drill holes, the drill holes can be equally distributed or equidistantly distributed on a specific track, and meanwhile, the drill hole direction can also rotate along the line direction.
S3: and setting numbers for the simulated drill holes, adding wildcards, performing coordinate system proofreading, and determining the simulated drill holes with the wildcards as design holes and the test holes without the wildcards.
In some specific embodiments, in step S3, the specific method for numbering the simulated drill holes is as follows:
numbering all the simulated drilling holes in sequence from the initial drilling hole, and adding a star character as a wildcard character;
checking the numbers of all the drill holes in the project to which the current file belongs, and searching whether the numbers which are repeated with the simulated drill holes exist or not;
when the repeated serial numbers are found, the serial numbers of the simulated drill holes corresponding to the serial numbers are modified, and the serial numbers of all the simulated drill holes after the simulated drill holes are sequentially modified.
In specific implementation, the specific method for checking the numbers of all drill holes in the project to which the current file belongs is as follows:
obtaining available drilling hole numbers according to the number patterns, and generating an available number set;
acquiring all simulated drilling hole numbers in the current file, traversing all drilling hole numbers in a database, and extracting all drilling hole numbers in a project to which the current file belongs;
analyzing each drilling hole number, judging whether the drilling hole number accords with the prefix and suffix patterns of the current window, analyzing a drilling hole number set which accords with both the prefix and the suffix, and generating an available number set;
and filling the available number set according to the existing number set, and searching repeated numbers, namely the numbers of the simulated drilling holes needing to be modified.
In specific implementation, the specific method for sequentially modifying the numbers of all the simulated boreholes after the modified simulated borehole is as follows:
copying the simulated drill holes to be modified and all the subsequent simulated drill holes, confirming that the entity type to be modified is the drill hole, acquiring wildcards and simulated drill hole numbers of all the simulated drill holes, and generating an available simulated drill hole number set;
and reassigning the serial numbers of the simulated drill holes to be modified, sequentially modifying the serial numbers of each simulated drill hole in the available simulated drill hole serial number set according to a preset rule, and correspondingly storing the modified serial numbers and the simulated drill holes to obtain new simulated drill hole serial numbers.
In the specific implementation, the specific method for calibrating the coordinate system of the simulated borehole is as follows:
selecting simulated drill holes to be corrected, obtaining a drill hole type list, and selecting simulated drill holes with wildcards;
reading a picture block of a drill hole with a wildcard character in advance by a background, and inserting the picture block into the current simulated drill hole to obtain a current picture layer; if the current layer is a '0' layer, using the drilling layer, otherwise, using the current layer;
setting the direction of the simulated drilling hole as a current visual angle, picking up the position of the drilling hole in the graph, and dynamically placing the drilling hole in the graph; adding a drill hole, resetting the attribute, the drill hole number, the exploration depth, the label style and the drill hole direction, and reversely rotating from the WCS north to the visual angle; and setting the drilling height, the label position information and the drilling identification line, and storing the calibrated simulation drilling coordinate and the attribute content.
S4: and storing the parameters, the position coordinates and the marking information of the designed holes in a database.
All the information about the design holes acquired in the process needs to be stored in a database file format so as to be convenient for calling and using in the operation of other subsequent links or the creation of other related files; the data which is not stored can only be temporary data in the current file, and cannot be used subsequently.
In some specific embodiments, the method further comprises the steps of:
s5: calculating mileage values of all the design holes according to the position of the initial drilling hole and the actual positions of the other design holes, and storing the mileage values in a database;
the specific method comprises the following steps:
selecting a path curve for reference, selecting the position of an initial drilling hole from the curve path as a reference point, and inputting a reference point mileage value which cannot be smaller than 0; and selecting the design hole of which the mileage needs to be calculated, and calculating the distance between the reference point and the design hole on the path curve to obtain the mileage value of the design hole.
By the method, the layout of the drill holes in the drawing can be accurately and efficiently carried out, the layout mode of the drill holes can be quickly determined, the specific information of the layout of the drill holes can be obtained, the hole layout information of different files in the same project can be mutually corresponding and effectively combined, and therefore the layout and the management of the drill hole information in the project files are facilitated.
The above-mentioned embodiments only express several embodiments of the present invention, and the description thereof is more specific and detailed, but not construed as limiting the scope of the present invention. It should be noted that, for a person skilled in the art, several variations and modifications can be made without departing from the inventive concept, which falls within the scope of the present invention. Therefore, the protection scope of the present patent shall be subject to the appended claims.
Claims (8)
1. A continuous drill hole arrangement method applied to the geotechnical engineering investigation industry is characterized by comprising the following steps:
s1: setting or acquiring attributes and parameters of a drill hole to be laid, wherein the attributes comprise a control exploration hole or a general exploration hole, and the parameters comprise an aperture and a hole depth;
s2: setting the position of an initial drilling hole, setting or acquiring a layout track of the drilling hole, and laying a plurality of simulated drilling holes according to the layout track;
s3: setting numbers for the simulated drill holes, adding wildcards, performing coordinate system proofreading, and determining the simulated drill holes with the wildcards as design holes and the test holes without the wildcards;
s4: storing the parameters, the position coordinates and the marking information of the design holes in a database; the specific method for laying the simulated borehole is as follows:
arranging placing points at equal intervals on the layout track according to a specific number or interval, and laying the simulated drill holes on each placing point; or calling a group of existing drill holes from the database, and carrying out equal-proportion layout on the layout track.
2. The continuous layout method of boreholes applied to the geotechnical engineering investigation industry as claimed in claim 1, wherein in step S1, the concrete method for obtaining the attributes and parameters of the boreholes to be laid is as follows:
and selecting the existing drill holes from the database, acquiring the attributes and parameters of the existing drill holes, and copying the attributes and parameters of the existing drill holes into the current file, thereby setting the drill holes to be laid.
3. The continuous layout method of the drill holes applied to the geotechnical engineering investigation industry of claim 2, wherein when the existing drill holes are the result holes constructed in other files, the drill holes to be laid are set as link points, a reference relationship is established between the current file and the other files to which the existing drill holes belong, and after the reference relationship is released, the link points can be deleted.
4. The continuous layout method of drill holes applied to the geotechnical engineering investigation industry as claimed in claim 1, wherein in step S2, the specific method for obtaining the layout trajectory of the drill holes is as follows:
and selecting the existing drilling track from the database, acquiring the parameter information of the drilling track, copying the parameter information into a current file, and setting the drilling track at a selected position by taking the initial drilling hole as a starting point to serve as a layout track.
5. The method for continuously arranging drill holes applied to the geotechnical engineering investigation industry as claimed in claim 1, wherein in step S3, the specific method for numbering the simulated drill holes is as follows:
sequentially setting numbers for all the simulated drill holes from the initial drill hole, and adding wildcards;
checking the numbers of all the drill holes in the project to which the current file belongs to find whether the numbers which are repeated with the simulated drill holes exist or not;
when the repeated serial numbers are found, the serial numbers of the simulated drill holes corresponding to the serial numbers are modified, and the serial numbers of all the simulated drill holes after the simulated drill holes are sequentially modified.
6. The method for continuously arranging the drill holes applied to the geotechnical engineering investigation industry as claimed in claim 5, wherein the specific method for checking the numbers of all the drill holes in the project to which the current file belongs is as follows:
obtaining available drilling hole numbers according to the number patterns, and generating an available number set;
acquiring all simulated drilling hole numbers in the current file, traversing all drilling hole numbers in the database, and extracting all drilling hole numbers in a project to which the current file belongs; analyzing each drill hole number in the item to which the extracted current file belongs, judging whether the prefix and the suffix of each drill hole number in the item to which the extracted current file belongs conform to the prefix pattern and the suffix pattern of the current window, analyzing a drill hole number set which conforms to both the prefix and the suffix, and generating a number set;
and filling the available number set according to the existing number set, and searching repeated numbers, namely the numbers of the simulated drilling holes needing to be modified.
7. The continuous layout method of boreholes applied to the geotechnical engineering investigation industry as claimed in claim 5, wherein the specific method of sequentially modifying the numbers of all simulated boreholes after the modified simulated borehole is as follows:
copying the simulated drill holes to be modified and all the subsequent simulated drill holes, confirming that the entity type to be modified is the drill hole, acquiring wildcards and simulated drill hole numbers of all the simulated drill holes, and generating an available simulated drill hole number set;
and reassigning the serial numbers of the simulated drill holes to be modified, sequentially modifying the serial numbers of each simulated drill hole in the available simulated drill hole serial number set according to a preset rule, and correspondingly storing the modified serial numbers and the simulated drill holes to obtain new simulated drill hole serial numbers.
8. The continuous layout method of the drill holes applied to the geotechnical engineering investigation industry according to any one of claims 1 to 7, further comprising the following steps:
s5: calculating mileage values of all the design holes according to the positions of the initial drilling holes and the actual positions of the rest design holes, and storing the mileage values in the database;
the specific method comprises the following steps:
selecting a curve path for reference, selecting the position of the initial drilling hole from the curve path as a reference point, and inputting a reference point mileage value which cannot be smaller than 0;
and selecting a design hole of which the mileage needs to be calculated, and calculating the distance between the reference point and the design hole on the path curve to obtain the mileage value of the design hole.
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CN111950046A (en) * | 2020-07-03 | 2020-11-17 | 成都理工大学 | Drilling data model construction method based on BIM |
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CN109558639A (en) * | 2018-10-31 | 2019-04-02 | 天津大学 | A kind of two three-dimensional borehole design methods and system combined based on WebGL |
CN110322982A (en) * | 2019-05-24 | 2019-10-11 | 核工业北京地质研究院 | A kind of high-level waste geology treatment gun drilling method for arranging |
CN111832096A (en) * | 2020-07-17 | 2020-10-27 | 安徽德克尔电子科技有限公司 | System for coal mine drilling design and inversion |
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CN103345540A (en) * | 2013-05-27 | 2013-10-09 | 华东师范大学 | Method for stimulating and displaying geological drilling information on digital earth software platform |
CN106202156A (en) * | 2016-06-16 | 2016-12-07 | 中山大学 | The log sheet of a kind of sing on web generalized information system generates method online |
CN111950046A (en) * | 2020-07-03 | 2020-11-17 | 成都理工大学 | Drilling data model construction method based on BIM |
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