CN114742526A - Standard design process based exploration full-process informatization method and system - Google Patents
Standard design process based exploration full-process informatization method and system Download PDFInfo
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Abstract
The invention discloses an information method and system for surveying the whole process based on a standardized design process, which determines the formats of various standardized data; determining a geotechnical engineering survey database and establishing a survey standardized process; acquiring field in-situ test data and/or geotechnical experiment data according to a survey standardized flow, wherein all data adopt corresponding standardized data formats; an outcome output standard comprising line engineering data and an outcome output standard comprising non-line engineering data is determined based on the acquired data in combination with a geotechnical engineering survey database. In the process of electric geotechnical engineering investigation, the investigation flow, data acquisition and result output lack a unified criterion, and certain obstacles are caused to communication among industries, data multiplexing, result sharing and the like.
Description
Technical Field
The invention relates to a standardized design flow-based reconnaissance full-flow informatization method, and belongs to the field of combination of electric geotechnics and computer technologies.
Background
The quality management requires three steps to achieve 'prevention in advance, process control and result inspection', through requirement investigation and analysis, the process control is an important link for improving the informatization and quality level of the survey, in the traditional survey operation mode of the electric geotechnical engineering, the professional habits and evaluation criteria of each design house and each owner (prospecting) are different, and under the environment of open industry and marketization competition, the requirements cannot be paralleled with the increasing technical and quality requirements of the owners. By taking reference to industrial product assembly line work, other industry informatization applications and cloud large object moving technology development, manual intervention needs to be replaced by more standardized processes.
At present, some electric geotechnical engineering survey flow informatization software exists, but due to the lack of unified standards, the informatization software developed by different units is difficult to be used universally, and the popularization is lacked.
The data formats acquired in the electric geotechnical engineering investigation process are various, errors easily occur in conversion among different formats, the error rate in the data transcription process needs to be reduced by an information acquisition standardization means, and simultaneously, geotechnical test data in any format is compatible, so that the high standard requirements of authenticity, integrity and normalization of original data are met.
Disclosure of Invention
In order to solve the problem of standardization of all links in the process of electric geotechnical engineering investigation, the invention aims to provide an investigation full-process informatization method based on a standardized design process, and solves the problems of inconsistent and non-universal investigation process, data acquisition and result output caused by lack of unified standards in the existing electric geotechnical engineering investigation. The information degree and the quality level of the survey can be effectively improved, and therefore standardized management of the electric geotechnical engineering survey process is achieved.
In order to achieve the above object, the present invention adopts the following technical solutions:
an information method of reconnaissance whole process based on standardized design process,
determining each standardized data format;
determining a geotechnical engineering survey database and establishing a survey standardized process;
acquiring field in-situ test data and/or geotechnical experiment data according to a survey standardized flow, wherein all data adopt corresponding standardized data formats; an outcome output standard comprising line engineering data and an outcome output standard comprising non-line engineering data is determined based on the acquired data in combination with a geotechnical engineering survey database.
And further, establishing a professional knowledge base, wherein the professional knowledge base is used for storing the structural information and the attribute information of the set parameters, and the structural information and the attribute information are used for reference when acquiring field data and/or geotechnical laboratory data.
And further, the professional knowledge base specifically comprises a rock-soil description standard attribute table, an exploration point attribute data structure relation graph, an exploration point attribute data structure table and a standard layer attribute data structure relation graph.
Further, the achievement output standard of the line engineering data comprises tower numbers, exploration hole numbers, soil layer burial depths, naming, compactness, lithologic description, geotechnical design parameters, underground water levels and structural fields of topographic description.
Further, the achievement output standard of the non-line engineering data comprises automatic drawing and intelligent inspection of an exploration point plane arrangement diagram, an engineering geological section diagram, a static sounding comprehensive diagram and a geological histogram.
Further, the method further comprises formulating a computer book output criteria, the computer book output criteria comprising: the method comprises the following steps of designing a professional calculation model for various professional data hierarchical statistics, bearing capacity calculation, site category calculation, single-pile limit bearing capacity calculation, liquefaction judgment, super-consolidation ratio calculation, deformation modulus, water and soil corrosivity evaluation, e-p comprehensive curve and foundation soil character evaluation.
Further, the method also comprises the step of carrying out approval and finished product filing operation on the results output according to the result output standard.
In a second aspect, the present invention further provides a survey full-process informatization system based on the standardized design process, including:
the survey process standardization module, the information acquisition standardization module and the result output standardization module are connected with the survey process standardization module;
the survey process standardization module is used for determining a geotechnical engineering survey database and establishing a survey standardization process;
the information acquisition standardization module is used for standardizing data formats;
the result output standardization module is used for acquiring field work in-situ test data and/or geotechnical experiment data according to a survey standardization process, wherein all data adopt corresponding standardization data formats; an outcome output standard comprising line engineering data and an outcome output standard comprising non-line engineering data is determined based on the acquired data in combination with a geotechnical engineering survey database.
Further, the information acquisition standardization module is further used for establishing a professional knowledge base, the professional knowledge base is used for storing the structural information and the attribute information of the set parameters, and the structural information and the attribute information are used for reference when field data and/or geotechnical laboratory data are obtained.
The invention has the following beneficial technical effects: in the process of electric geotechnical engineering investigation, the investigation flow, data acquisition and result output lack a unified criterion, and certain obstacles are caused to communication among industries, data multiplexing, result sharing and the like. The invention forms a set of standardized system for the exploration process of the electric geotechnical engineering by designing the standardization of the exploration process, the standardization of information acquisition and the standardization of result output, brings all traditional exploration work into the standardized system for management, and thereby improves the standardization degree in the industry.
Drawings
FIG. 1 is a survey data flow diagram of an embodiment of the invention;
FIG. 2 is a structural relationship diagram of survey point attribute data for an embodiment of the invention;
FIG. 3 is a diagram of a standard layer attribute data structure relationship according to an embodiment of the present invention;
FIG. 4 is a schematic diagram of an in-situ test data collection window design according to an embodiment of the present invention;
FIG. 5 is a schematic view of a geotechnical test data collection window design according to an embodiment of the present invention;
FIG. 6 is a schematic diagram of a 220kV achievement table template and below;
FIG. 7 is a schematic diagram of a 500kV achievement table template and above;
FIG. 8 is a graphical illustration of normalized output of a plane icon in accordance with an embodiment of the present invention;
FIG. 9 is a schematic diagram of normalized output of a cross-sectional view of an embodiment of the present invention;
FIG. 10 is a diagram illustrating a diagram normalization check according to an embodiment of the present invention;
FIG. 11 is a schematic diagram of a computer book category table according to an embodiment of the present invention;
FIG. 12 is a computer book template definition representation of an embodiment of the present invention.
Detailed Description
The invention is further described below with reference to the accompanying drawings. The following examples are only for illustrating the technical solutions of the present invention more clearly, and the protection scope of the present invention is not limited thereby.
The invention aims to solve the technical problem that in the process of electric geotechnical engineering investigation, the investigation flow, data acquisition and result output lack a uniform criterion, and certain obstacles are caused to communication among industries, data reuse, result sharing and the like.
In the embodiment, three standardization systems of survey flow standardization, information acquisition standardization and result output standardization are designed for the electric geotechnical engineering survey standardization. The survey process standardization comprises the steps of establishing a survey informatization system architecture of the whole process, establishing a professional informatization system oriented to the whole process integration, and designing a functional module based on the survey process standardization, namely developing a survey informatization system based on the standardized process;
the information acquisition standardization comprises the steps of establishing a standard professional knowledge base of lithology description, the standardized acquisition of in-situ test data and the standardized acquisition of geotechnical test data, so that a data acquisition standard with a uniform format is established;
the result output standardization comprises the output of a line engineering geological result table, the standardized output and inspection of a finished drawing product and the standardized output of a calculation book, and the unified standardized management is carried out on the investigation result.
The overall architecture of survey flow normalization can be summarized as a "three-step" scheme: the method comprises the steps of firstly, establishing a professional database and optimizing a business process, establishing a reasonable and comprehensive geotechnical engineering survey database, secondly, electronically acquiring data, developing an intelligent acquisition terminal-based field data acquisition system aiming at the input information requirement and the field operation requirement of auxiliary design software, replacing the traditional paper record, thirdly, developing and applying stock data, taking the geotechnical engineering survey database as a basic data source, and realizing the integration and accumulation of geotechnical engineering survey results through a geographic information platform; a professional informatization system framework needs to be constructed from multiple aspects such as a standardization system, a business process system, a professional algorithm system, a feedback optimization system, a talent culture system and the like, standardization and informatization are used as double drives and mutual fusion, and a key information technology is used as a support to serve the whole process of exploration business; the integrated information management of the whole process of surveying such as surveying planning, cost budget, field acquisition, internal data processing, finished product submission, quality evaluation and the like is realized, the support capability of knowledge management and a professional data dictionary is provided, and the standardization of surveying data flow is represented by a diagram 1. FIG. 1 illustrates a standardized business process for first determining a corresponding survey overall process for a survey based on business type, including obtaining survey hole type, coordinates, and planned hole depth based on survey planning; surfacing aggregation, connectivity, and planning workload;
acquiring field data according to a survey standard process, wherein the field data comprises the actual type, coordinates and planned hole depth of a survey hole; cpt data, date, etc.; drilling records, in-situ test data in the hole and sampling conditions are also included; the embodiment also comprises the steps of obtaining geotechnical experiment data which comprise 1, physical and mechanical indexes of the soil sample; 2. an experimental curve; 3. special experimental indexes.
Based on the acquired data and the geotechnical engineering survey database, the achievement output standard comprising the line engineering data and the achievement output standard comprising the non-line engineering data are determined, and the method specifically comprises the following steps: determining a standard soil layer; layering in a single hole; recording field record data; importing CPT test data and geotechnical experiment data; determining soil layer membership of in-hole in-situ test data and geotechnical test data according to the depth of a soil layer, carrying out mathematical statistics, generating a calculation book and the like; drawing various figures.
Optionally, the specific embodiment further includes a professional knowledge base for making information acquisition standardization, where the professional knowledge base is used to store the structural information and the attribute information of the set parameters, and the structural information and the attribute information are used for reference when acquiring field data and/or geotechnical laboratory data. The specific example of the professional knowledge base comprises a rock and soil description standard attribute table, an exploration point attribute data structure relation diagram, an exploration point attribute data structure table and a standard layer attribute data structure relation diagram, as shown in fig. 2, fig. 3, table 1 and table 2.
Table 1 is a table of rock and soil description standard attributes according to an embodiment of the present invention; the method comprises the rock and soil categories and the rock and soil attributes corresponding to the rock and soil categories.
Table 2 is a table of survey point attribute data structures for embodiments of the invention;
FIG. 2 is a survey point attribute data structure relationship diagram of an embodiment of the invention, FIG. 2 showing: the survey points comprise survey point codes, survey point numbers, vertical coordinates, horizontal coordinates, hole opening elevations, hole depths, exploratory well depths, start-up dates, completion dates, horizontal proportions, vertical proportions, remarks and reference marks; the method is related to the type of an exploration point, the classification of the exploration point, outsourcing units, static exploration holes, side pressure tests, cross plate data and the like, static exploration holes are related to the water level below the static exploration holes and hole pressure static exploration, and underground water level is related to the single bridge static state and the like.
In-situ test data is collected through OTG communication, data collected by an in-situ test instrument is imported to a collection end for application, the collection end is analyzed and arranged to form a test curve, a planned task can be adjusted on site in time conveniently, and meanwhile the data can be uploaded to an interior processing end through data interaction communication, as shown in figure 4, the static probing type (single bridge, double bridge or hole pressure/multiple bridge) is set, and whether the side wall unit is required to be converted into megapascals or not is included; the sampling interval, the file type, the file position, and the data file name contain prefix characters and the like.
FIG. 3 is a diagram of a standard layer attribute data structure relationship according to an embodiment of the present invention; including standard layer coding, standard layer number, reference top depth, geotechnical description, recommended bearing capacity value, empirical shear wave velocity value, estimation coefficient, estimation index and the like.
Geotechnical test data acquisition process is simple, efficient, all has the function of customizable import to multiple geotechnical test data format, as shown in fig. 5, can add or remove through testing the project, can greatly improve work efficiency, effectively reduceed the artificial error among the data transmission process, ensure the accurate transmission of first hand data.
In the achievement output standardization, the line engineering data acquisition and achievement data structuring degree is high and can be divided into the following categories: pole tower number (tower leg number), exploration hole number, soil layer burial depth, name setting, state (compactness), lithology description, geotechnical design parameter, underground water level, terrain description and the like, wherein structured data are input through information collection standardization, a standardized result table is output, and fig. 6 and 7 respectively represent result table templates under different voltage projects;
the finished drawing products comprise automatic drawing and intelligent inspection of drawings such as an exploration point plane arrangement diagram, an engineering geological profile, a static sounding comprehensive diagram, a geological histogram and the like, the drawing efficiency is high, manual intervention is less, standardized output of plane diagram and profile diagram results is shown in figures 8 and 9, and standardized inspection of the drawings is shown in figure 10; the calculation book realizes the design of professional calculation models such as various professional data hierarchical statistics, bearing capacity calculation, site category calculation, single-pile limit bearing capacity calculation, liquefaction judgment, super-consolidation ratio calculation, deformation modulus, water and soil corrosivity evaluation, e-p comprehensive curves, foundation soil property evaluation and the like, the standardized generation of various calculation books is completed according to the current practical standard and national standard unified calculation models strictly, the professional verification efficiency is greatly improved, and as shown in fig. 11 and 12, a calculation book classification table and a calculation book template definition table are respectively represented.
The invention forms a set of standardized system for the exploration process of the electric geotechnical engineering by designing the standardization of the exploration process, the standardization of information acquisition and the standardization of result output, brings all traditional exploration work into the standardized system for management, and thereby improves the standardization degree in the industry.
As will be appreciated by one skilled in the art, embodiments of the present application may be provided as a method, system, or computer program product. Accordingly, the present application may take the form of an entirely hardware embodiment, an entirely software embodiment or an embodiment combining software and hardware aspects. Furthermore, the present application may take the form of a computer program product embodied on one or more computer-usable storage media (including, but not limited to, disk storage, CD-ROM, optical storage, and the like) having computer-usable program code embodied therein.
The above description is only a preferred embodiment of the present invention, and it should be noted that, for those skilled in the art, several modifications and variations can be made without departing from the technical principle of the present invention, and these modifications and variations should also be regarded as the protection scope of the present invention.
Claims (9)
1. The reconnaissance full-process informatization method based on the standardized design process is characterized by comprising the following steps of:
determining each standardized data format;
determining a geotechnical engineering survey database and establishing a survey standardized process;
acquiring field in-situ test data and/or geotechnical experiment data according to a survey standardized flow, wherein all data adopt corresponding standardized data formats; an outcome output standard comprising the line engineering data and an outcome output standard for the non-line engineering data are determined based on the acquired data in combination with a geotechnical engineering survey database.
2. A method as claimed in claim 1, further comprising establishing a professional knowledge base for storing the structural information and attribute information of the setting parameters, wherein the structural information and attribute information are used for reference when acquiring field data and/or geotechnical laboratory data.
3. A method as claimed in claim 2, wherein the expert knowledge base includes a geotechnical description standard attribute table, an exploration point attribute data structure relationship chart, an exploration point attribute data structure chart, and a standard layer attribute data structure relationship chart.
4. The standardized design process-based exploration full-process informatization method according to claim 1, characterized in that the achievement output standards of line engineering data comprise tower numbers, exploration hole numbers, soil layer burial depth, naming, compactness, lithology description, geotechnical design parameters, groundwater level, and structured fields of terrain description.
5. A standardized design flow based investigation full flow informatization method according to claim 1, characterized in that the achievement output criteria of the non-line engineering data include automatic drawing and intelligent inspection of exploration point planform, engineering geological profile, static penetration synthesis and geological histogram.
6. A method for standardized design flow based investigation full flow informatization according to claim 1, further comprising formulating a computer book output standard, wherein the computer book output standard comprises: the method comprises the following steps of designing a professional calculation model for various professional data hierarchical statistics, bearing capacity calculation, site category calculation, single-pile limit bearing capacity calculation, liquefaction judgment, super-consolidation ratio calculation, deformation modulus, water and soil corrosivity evaluation, e-p comprehensive curve and foundation soil character evaluation.
7. The standardized design process based investigation full process informatization method of claim 1, characterized in that the method further comprises approval and product filing operations of the result output according to the result output standard.
8. Reconnaissance full flow informatization system based on standardized design flow is characterized by comprising:
the survey process standardization module, the information acquisition standardization module and the result output standardization module are connected with the survey process standardization module;
the survey process standardization module is used for determining a geotechnical engineering survey database and establishing a survey standardization process;
the information acquisition standardization module is used for standardizing data formats;
the result output standardization module is used for acquiring field in-situ test data and/or geotechnical experiment data according to a survey standardization process, wherein all data adopt corresponding standardization data formats; an outcome output standard comprising line engineering data and an outcome output standard comprising non-line engineering data is determined based on the acquired data in combination with a geotechnical engineering survey database.
9. A survey full-process informatization system based on standardized design processes according to claim 8, wherein the information acquisition standardization module is further configured to establish a professional knowledge base, the professional knowledge base is configured to store structural information and attribute information of set parameters, and the structural information and the attribute information are used for reference when acquiring field data and/or geotechnical laboratory data.
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