阅读说明：本技术 工程勘察数据的处理方法、装置、设备及存储介质 (Method, device and equipment for processing engineering survey data and storage medium ) 是由 林健 谭玮 赵旭 连长江 李建平 陈诗艾 曾杰 颜小锋 王磊 陈志勇 程东海 于 2019-08-16 设计创作，主要内容包括：本申请提供了一种工程勘察数据的处理方法、装置、设备及存储介质,涉及工程勘察技术领域。该方法包括在对目标钻孔进行钻孔作业时,接收勘察人员的终端发送的目标钻孔的钻孔位置和目标钻孔的多个钻进深度；根据钻孔位置确定目标钻孔的临近钻孔,并获取临近钻孔的地层信息集；对于每个钻进深度,根据钻进深度从临近钻孔的地层信息集中获取临近钻孔中目标地层的地层信息；对于每个钻进深度,将临近钻孔中目标地层的地层信息发送给终端,临近钻孔中目标地层的地层信息用于触发终端根据临近钻孔中目标地层的地层信息确定目标钻孔的目标地层的地层信息。解决了现有技术中获取到的地层信息的准确性较低的技术问题。(The application provides a method, a device, equipment and a storage medium for processing engineering investigation data, and relates to the technical field of engineering investigation. The method comprises the steps of receiving the drilling position of a target drilling hole and a plurality of drilling depths of the target drilling hole sent by a terminal of an inspector when the target drilling hole is drilled; determining adjacent drill holes of the target drill hole according to the drill hole positions, and acquiring stratum information sets of the adjacent drill holes; for each drilling depth, acquiring stratum information of a target stratum in the adjacent drill hole from the stratum information of the adjacent drill hole in a centralized manner according to the drilling depth; and for each drilling depth, sending the stratum information of the target stratum in the adjacent borehole to the terminal, wherein the stratum information of the target stratum in the adjacent borehole is used for triggering the terminal to determine the stratum information of the target stratum of the target borehole according to the stratum information of the target stratum in the adjacent borehole. The technical problem that the accuracy of the stratum information acquired in the prior art is low is solved.)

1. A method of processing engineering survey data, the method comprising:

receiving a drilling position of a target borehole and a plurality of drilling depths of the target borehole transmitted by a terminal of an exploratory staff when performing a drilling operation on the target borehole, the target borehole being a hole drilled by the exploratory staff in a target area to be exploratory;

determining a near borehole of the target borehole according to the borehole position, and acquiring a stratum information set of the near borehole, wherein the stratum information set of the near borehole comprises stratum information of different stratums of the near borehole;

for each drilling depth, acquiring stratum information of a target stratum in the adjacent drilling holes from the stratum information of the adjacent drilling holes in a centralized manner according to the drilling depth, wherein the target stratum is a stratum corresponding to the drilling depth;

and for each drilling depth, sending the stratum information of the target stratum in the adjacent borehole to the terminal, wherein the stratum information of the target stratum in the adjacent borehole is used for triggering the terminal to determine the stratum information of the target stratum of the target borehole according to the stratum information of the target stratum in the adjacent borehole.

2. The method of claim 1, wherein after transmitting formation information for the target formation in the adjacent borehole to the terminal, the method further comprises:

for each drilling depth, receiving stratum information of a target stratum in the target drilling hole, which is sent by the terminal, and storing the stratum information of the target stratum in the target drilling hole into a stratum information set of the target drilling hole;

and the stratum information of the target stratum in the target borehole is obtained by the terminal according to the stratum information of the target stratum in the adjacent borehole and the standard stratum information of the target area, wherein the standard stratum information comprises a stratum order and a stratum name.

3. The method of claim 1, further comprising:

acquiring rock-soil sampling test data of rock soil in the target drilling hole and test data of an in-situ test performed at the position of the target drilling hole;

and storing the rock-soil sampling test data and the test data of the in-situ test into the stratum information set of the target borehole.

4. A method according to claim 2 or 3, characterized in that the method further comprises:

and generating a three-dimensional geological model of the target borehole according to the stratum information set of the target borehole.

5. The method of claim 2, wherein prior to receiving formation information for a target formation in the target borehole sent by the terminal, the method further comprises:

acquiring the position of the target area;

acquiring the standard stratum information of the target area according to the position of the target area;

generating a survey outline according to the standard stratum information;

and sending the survey outline to the terminal.

6. The method of claim 5, wherein the obtaining the location of the target region comprises:

acquiring a topographic plan of the target area and a drilling plan of the target area, wherein the topographic plan comprises position coordinates of ground objects in the target area, and the drilling plan comprises position coordinates of a drill hole to be drilled in the target area;

and acquiring the position of the target area according to the position coordinates included by the topographic plan or the position coordinates included by the drilling plan.

7. The method of claim 5, wherein the obtaining the standard formation information of the target area according to the position of the target area comprises:

acquiring regional standard stratum information of the target region, standard stratum information of an adjacent region to be surveyed and standard stratum information of a nearby region after survey according to the position of the target region;

and selecting one of the area standard stratum information of the target area, the standard stratum information of the adjacent area to be surveyed and the standard stratum information of the adjacent area after the survey is completed as the standard stratum information of the target area.

8. The method of claim 5, wherein after the obtaining the location of the target region, the method further comprises:

acquiring subcontractor recommendation information of the target area according to the position of the target area;

correspondingly, the generating of the survey outline according to the standard stratum information comprises:

and generating the survey outline according to the standard stratum information and the subcontractor recommendation information.

9. The method according to claim 8, wherein the obtaining of the SCE recommendation information of the target area according to the position of the target area comprises:

acquiring basic information of a plurality of subcontractors, wherein the basic information of each subcontractor comprises a resident area position of each subcontractor, historical workload of each subcontractor and a survey operation grade of each subcontractor;

screening out a plurality of first subcontractors which meet a first condition according to the position of the target area and the resident area position of each subcontractor, wherein the first condition is that the distance between the resident area position and the position of the target area is smaller than a distance threshold;

screening a plurality of second subcontractors meeting a second condition from the plurality of first subcontractors according to the historical workload of each subcontractor, wherein the second condition is that the difference value between the historical workload and the workload for surveying the target area is smaller than a difference threshold value;

and screening a plurality of third subcontractors meeting a third condition from the plurality of second subcontractors according to the survey operation grade of each subcontractor, and generating the subcontractor recommendation information according to the basic information of the third subcontractors, wherein the third condition comprises the condition that the survey operation grade is greater than a grade threshold value.

10. A method of processing engineering survey data, the method comprising:

receiving, while a drilling operation is being performed on a target borehole, a borehole position of the target borehole and a plurality of drilling depths of the target borehole, which are input by a surveying person, the target borehole being a hole drilled by the surveying person in a target area to be surveyed;

for each drilling depth, obtaining stratum information of a target stratum in a near drilling hole of the target drilling hole according to the drilling position and the drilling depth, wherein the near drilling hole is determined according to the drilling position, and the target stratum is a stratum corresponding to the drilling depth,

and for each drilling depth, determining stratum information of the target stratum of the target drilling hole according to the stratum information of the target stratum in the adjacent drilling hole.

11. The method of claim 10, wherein the deriving formation information for a target formation in an adjacent borehole of the target borehole from the borehole location and the drilling depth comprises:

sending the drilling location and the drilling depth to a server;

and receiving stratum information of a target stratum in the adjacent borehole, which is sent by the server, wherein the adjacent borehole is determined by the server according to the borehole position, the stratum information of the target stratum in the adjacent borehole is obtained by the server from the stratum information set of the adjacent borehole according to the drilling depth, and the stratum information set of the adjacent borehole comprises stratum information of different stratums of the adjacent borehole.

12. The method of claim 10, wherein the deriving formation information for a target formation in an adjacent borehole of the target borehole from the borehole location and the drilling depth comprises:

determining the near borehole from the boreholes in the target area which are surveyed according to the borehole position, and acquiring a stratum information set of the near borehole, wherein the stratum information set of the near borehole comprises stratum information of different stratums of the near borehole;

and according to the drilling depth, stratum information of the target stratum in the adjacent borehole is obtained from the stratum information of the adjacent borehole in a centralized manner.

13. The method of claim 10, wherein determining formation information for a target formation in the target borehole from formation information for a target formation in the adjacent borehole comprises:

displaying standard stratum information and stratum information of a target stratum in the adjacent borehole, wherein the standard stratum information comprises stratum orders and stratum names;

receiving a selection instruction aiming at the standard stratum information or the stratum information of the target stratum in the adjacent borehole;

determining formation information targeted by the selection instruction as formation information of a target formation in the target borehole;

and sending the stratum information of the target stratum in the target borehole to a server.

14. An apparatus for processing engineering survey data, the apparatus comprising:

the system comprises a first receiving module, a second receiving module and a third receiving module, wherein the first receiving module is used for receiving the drilling position of a target drilling hole and a plurality of drilling depths of the target drilling hole, which are sent by a terminal of a surveying staff when the target drilling hole is drilled, and the target drilling hole is a hole drilled by the surveying staff in a target area to be surveyed;

the near drilling module is used for determining a near drilling hole of the target drilling hole according to the drilling position and acquiring a stratum information set of the near drilling hole, wherein the stratum information set of the near drilling hole comprises stratum information of different stratums of the near drilling hole;

the first stratum information module is used for acquiring stratum information of a target stratum in the adjacent drilled holes in a centralized manner from the stratum information of the adjacent drilled holes according to the drilling depth, wherein the target stratum is a stratum corresponding to the drilling depth;

and the sending module is used for sending the stratum information of the target stratum in the adjacent borehole to the terminal for each drilling depth, and the stratum information of the target stratum in the adjacent borehole is used for triggering the terminal to determine the stratum information of the target stratum of the target borehole according to the stratum information of the target stratum in the adjacent borehole.

15. An apparatus for processing engineering survey data, the apparatus comprising:

a second receiving module, configured to receive, when performing a drilling operation on a target borehole, a borehole position of the target borehole and a plurality of drilling depths of the target borehole, which are input by a surveying staff, where the target borehole is a hole drilled by the surveying staff in a target area to be surveyed;

the second stratum information module is used for obtaining stratum information of a target stratum in adjacent boreholes of the target borehole according to the drilling position and the drilling depth for each drilling depth, the adjacent boreholes are determined according to the drilling position, and the target stratum is a stratum corresponding to the drilling depth;

and the target drilling hole stratum information module is used for determining the stratum information of the target stratum of the target drilling hole according to the stratum information of the target stratum in the adjacent drilling holes for each drilling depth.

16. A computer device comprising a memory and a processor, the memory storing a computer program, wherein the processor when executing the computer program implements the steps of the method of any one of claims 1 to 9; alternatively, the processor, when executing the computer program, implements the steps of the method of any of claims 10 to 13.

17. A computer-readable storage medium, on which a computer program is stored, which, when being executed by a processor, carries out the steps of the method according to any one of claims 1 to 9; alternatively, the computer program realizes the steps of the method of any one of claims 10 to 13 when executed by a processor.

Technical Field

The present application relates to the field of engineering investigation technologies, and in particular, to a method, an apparatus, a device, and a storage medium for processing engineering investigation data.

Background

The engineering investigation refers to the activities of surveying and mapping, exploring and testing the conditions of topography, geology, hydrology and the like of a target area and providing corresponding results and data in order to meet the requirements of planning, designing, constructing, operating, comprehensive treatment and the like of engineering construction. In engineering investigation, it is an important part of the investigation work to obtain the formation information of the area to be investigated, wherein the formation information includes the formation name and the formation description of each formation.

Disclosure of Invention

Accordingly, it is necessary to provide a method, an apparatus, a device and a storage medium for processing engineering survey data for solving the technical problem of low accuracy of the acquired formation information.

In a first aspect, an embodiment of the present application provides a method for processing engineering survey data, where the method includes:

when the target borehole is drilled, receiving the drilling position of the target borehole and a plurality of drilling depths of the target borehole, which are sent by a terminal of an inspector, wherein the target borehole is a hole drilled by the inspector in a target area to be inspected;

determining adjacent boreholes of the target borehole according to the positions of the boreholes, and acquiring stratum information sets of the adjacent boreholes, wherein the stratum information sets of the adjacent boreholes comprise stratum information of different stratums of the adjacent boreholes;

for each drilling depth, acquiring stratum information of a target stratum in the adjacent drilling holes from the stratum information of the adjacent drilling holes in a centralized manner according to the drilling depth, wherein the target stratum is a stratum corresponding to the drilling depth;

and for each drilling depth, sending the stratum information of the target stratum in the adjacent borehole to the terminal, wherein the stratum information of the target stratum in the adjacent borehole is used for triggering the terminal to determine the stratum information of the target stratum of the target borehole according to the stratum information of the target stratum in the adjacent borehole.

In a second aspect, an embodiment of the present application provides a method for processing engineering survey data, where the method includes:

when the target drilling hole is drilled, receiving the drilling position of the target drilling hole and a plurality of drilling depths of the target drilling hole input by an inspector, wherein the target drilling hole is a hole drilled by the inspector in a target area to be inspected;

for each drilling depth, obtaining stratum information of a target stratum in an adjacent drilling hole of the target drilling hole according to the drilling position and the drilling depth, wherein the adjacent drilling hole is determined according to the drilling position, the target stratum is a stratum corresponding to the drilling depth,

for each drilling depth, formation information for a target formation of the target borehole is determined from formation information for a target formation adjacent to the borehole.

In a third aspect, an embodiment of the present application provides an apparatus for processing engineering survey data, where the apparatus includes:

the system comprises a first receiving module, a second receiving module and a third receiving module, wherein the first receiving module is used for receiving the drilling position of a target drilling hole and a plurality of drilling depths of the target drilling hole, which are sent by a terminal of an inspector when the target drilling hole is drilled, and the target drilling hole is a hole drilled by the inspector in a target area to be inspected;

the near drilling module is used for determining near drilling of the target drilling according to the drilling position and acquiring a stratum information set of the near drilling, wherein the stratum information set of the near drilling comprises stratum information of different stratums of the near drilling;

the first stratum information module is used for acquiring stratum information of a target stratum in the adjacent drilled holes from the stratum information of the adjacent drilled holes in a centralized manner according to the drilling depth for each drilling depth, wherein the target stratum is a stratum corresponding to the drilling depth;

and the sending module is used for sending the stratum information of the target stratum in the adjacent borehole to the terminal for each drilling depth, and the stratum information of the target stratum in the adjacent borehole is used for triggering the terminal to determine the stratum information of the target stratum of the target borehole according to the stratum information of the target stratum in the adjacent borehole.

In a fourth aspect, an embodiment of the present application provides an apparatus for processing engineering survey data, where the apparatus includes:

the second receiving module is used for receiving the drilling position of the target drilling hole and a plurality of drilling depths of the target drilling hole input by the surveying staff when the target drilling hole is drilled, and the target drilling hole is a hole drilled by the surveying staff in a target area to be surveyed;

the second stratum information module is used for obtaining stratum information of a target stratum in a near borehole of the target borehole according to the drilling position and the drilling depth for each drilling depth, wherein the near borehole is determined according to the drilling position, and the target stratum is a stratum corresponding to the drilling depth;

and the target drilling hole stratum information module is used for determining the stratum information of the target stratum of the target drilling hole according to the stratum information of the target stratum close to the drilling hole for each drilling depth.

In a fifth aspect, an embodiment of the present application provides a computer device, including a memory and a processor, where the memory stores a computer program, and the processor implements the steps of the method in the first aspect when executing the computer program; alternatively, the processor implements the steps of the method of the second aspect described above when executing the computer program.

In a sixth aspect, embodiments of the present application provide a computer-readable storage medium, on which a computer program is stored, which, when executed by a processor, implements the steps of the method of the first aspect; alternatively, the computer program realizes the steps of the method of the second aspect described above when executed by a processor.

The beneficial effects brought by the technical scheme provided by the embodiment of the application at least comprise:

when a target borehole in a target area is drilled, an investigator inputs a drilling position of the target borehole and a drilling depth of the target borehole into a terminal, the terminal sends the drilling position and the drilling depth to a server, the server screens out a near borehole of the target borehole from a database according to the drilling position and obtains a stratum information set of the near borehole, and the stratum information set of the near borehole comprises stratum information of different stratums; then the server searches stratum information of a target stratum corresponding to the drilling depth from the stratum information of the adjacent drill holes in a centralized manner according to the drilling depth, and sends the stratum information of the target stratum in the adjacent drill holes to the terminal, and the terminal can determine the stratum information of the target stratum of the target drill holes from the stratum information of the target stratum in the adjacent drill holes. According to the method and the device, the stratum information of the stratum corresponding to the drilling depth of the target drilling hole is predicted through the stratum information of each stratum of the adjacent drilling hole of the target drilling hole, and the accuracy of the stratum information of the drilling hole is improved.

Drawings

FIG. 1 is a schematic diagram of an implementation environment provided by an embodiment of the present application;

FIG. 2 is a flow chart of a method for processing engineering survey data according to an embodiment of the present disclosure;

FIG. 3 is a flow chart of another method for processing engineering survey data according to an embodiment of the present disclosure;

FIG. 4 is a flow chart of another method for processing engineering survey data according to an embodiment of the present disclosure;

FIG. 5 is a flow chart of another method for processing engineering survey data according to an embodiment of the present disclosure;

FIG. 6 is a flow chart of another method for processing engineering survey data according to an embodiment of the present disclosure;

FIG. 7 is a flowchart of a method for processing engineering survey data according to an embodiment of the present disclosure;

FIG. 8 is a flow chart of another method for processing engineering survey data provided in an embodiment of the present application;

FIG. 9 is a flow chart of another method for processing engineering survey data provided in an embodiment of the present application;

FIG. 10 is a flow chart of another method for processing engineering survey data provided in an embodiment of the present application;

FIG. 11 is a flowchart of a method for processing engineering survey data according to an embodiment of the present disclosure;

FIG. 12 is a block diagram of an apparatus for processing engineering survey data according to an embodiment of the present disclosure;

FIG. 13 is a block diagram of an apparatus for processing engineering survey data according to an embodiment of the present disclosure;

fig. 14 is a block diagram of a server according to an embodiment of the present application;

fig. 15 is a block diagram of a terminal according to an embodiment of the present application.

Detailed Description

In order to make the objects, technical solutions and advantages of the present application more apparent, the present application is described in further detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the present application and are not intended to limit the present application.

It should be noted that the terms "first," "second," "third," and "fourth," etc. in the description and claims of this application and in the above-described drawings are used for distinguishing between similar elements and not necessarily for describing a particular sequential or chronological order. It is to be understood that the data so used is interchangeable under appropriate circumstances such that the embodiments of the application described herein are capable of operation in sequences other than those illustrated or described herein.

Currently, before engineering a target area, engineering investigation of the target area is an important part of the engineering construction. The engineering survey refers to activities of surveying and mapping, exploring and testing the conditions of topography, geology, hydrology and the like of a target area to meet the requirements of planning, designing, constructing, operating, comprehensive treatment and the like of engineering construction so as to obtain corresponding results and data.

The existing engineering investigation process may be: the method comprises the steps that an investigator drills holes at different positions of a target area to be investigated, core samples are obtained from the drilled holes, the core samples are observed to obtain an observation result, the investigator names and words describe different stratums in the drilled holes according to personal experience and the observation result to determine stratum names and stratum descriptions of the stratums in the drilled holes, and stratum information of the stratums is formed.

However, since formation information of a borehole is determined mainly by the personal experience of an exploratory staff and the observation results of core samples by the exploratory staff, the obtained formation information of the borehole is less accurate.

The embodiment of the application provides a method for processing engineering survey data, which can improve the accuracy of acquired stratum information. In the method for processing engineering survey data provided by the embodiment of the application, when a target borehole in a target area is drilled, a survey worker inputs the drilling position of the target borehole and the drilling depth of the target borehole into a terminal, the terminal sends the drilling position and the drilling depth to a server, the server screens out a near borehole of the target borehole from a database of the server according to the drilling position and obtains a stratum information set of the near borehole, and the stratum information set of the near borehole comprises stratum information of different stratums; then the server searches stratum information of a target stratum corresponding to the drilling depth from the stratum information of the adjacent drilling holes in a centralized manner according to the drilling depth, and sends the stratum information of the target stratum in the adjacent drilling holes to the terminal, and the terminal can determine the stratum information of the stratum corresponding to the drilling depth of the target drilling hole from the stratum information of the target stratum in the adjacent drilling holes. According to the method and the device, the stratum information of the stratum corresponding to the drilling depth of the target drilling hole is predicted through the stratum information of each stratum of the adjacent drilling hole of the target drilling hole, and the accuracy of the stratum information of the drilling hole is improved.

Next, a brief description will be given of an implementation environment related to the method for processing engineering survey data provided in the embodiment of the present application.

Referring to fig. 1, fig. 1 is a schematic diagram of an implementation environment related to a method for processing engineering survey data according to an embodiment of the present disclosure. As shown in fig. 1, the implementation environment includes a server (only one server without a web server is shown in fig. 1) and at least one terminal (only one laptop computer is shown in fig. 1), wherein the server and the terminal can communicate with each other through a wireless network.

In embodiments of the present application, a server may include a web-side of the server, a communication component, a memory, and a processor.

The web side of the server can be used for data interaction with the server. The communication component can support WIFI (Wireless Fidelity, chinese) communication, mobile data communication, LORA (Long Range, chinese) communication, Zigbee (chinese) communication, and the like, and the server can communicate with the terminal through the communication component, that is, the communication component can receive data or instructions sent by the terminal and transmit the data or instructions to the processor, and the communication component can also send the data or instructions generated by the processor to the terminal.

The memory may be configured to store data uploaded via a web server or data received from the terminal by the communication component, and further includes: the system comprises a geotechnical engineering database, a project database, a file database, an enterprise personnel database, an equipment library and a subcontracting business database, wherein the geotechnical engineering database is used for storing geotechnical data and investigation data of other investigation units. The project database is used for storing data materials of projects which are under investigation. The archive database is used for storing data information of the project which is surveyed. The enterprise personnel library is used for storing information of enterprise personnel. The equipment library is used for storing the information of the survey equipment. The subcontractor database is used for storing data information of the subcontractors who cooperate or do not cooperate.

The processor can be a CPU (Central Processing Unit, chinese) or a single chip microcomputer, and the processor can call and process the relevant data in the geotechnical engineering database, the project database, the archive database, the enterprise personnel database, the equipment database and the subcontractor database in the memory, thereby implementing the method for Processing the engineering survey data provided by the embodiment of the present application.

In the embodiment of the present application, the terminal may be a mobile phone, a tablet computer, a notebook computer, a desktop computer, a customized electronic device, a microcomputer or other devices, and the terminal may include a communication component, a processing component and a local storage.

The communication component can support WIFI communication, mobile data communication, LORA communication or Zigbee communication and the like. The processing component can execute the processing method of the engineering survey data provided by the embodiment of the application. The local memory may be used to store data and instructions entered by the survey crew, data and instructions received from the server, and data or instructions generated by the terminal after executing the instructions entered by the survey crew or executing the instructions received from the server.

Referring to fig. 2, which illustrates a method for processing engineering survey data provided by an embodiment of the present application, the method for processing engineering survey data may be applied to a server and a terminal in the implementation environment shown in fig. 1, and as shown in fig. 2, the method for processing engineering survey data may include the following steps:

step 201, when drilling the target borehole, the server receives the borehole position of the target borehole and a plurality of drilling depths of the target borehole, which are sent by the terminal of the surveyor.

Wherein a target borehole is a hole drilled by a surveying person in a target area to be surveyed. The target area may include a plurality of target boreholes, and the surveyor may simultaneously drill the plurality of target boreholes, and the plurality of target boreholes being drilled may be distinguished by the location of the boreholes.

Alternatively, the borehole location may be latitude and longitude, and the drilling depth may be expressed in elevation or altitude.

Optionally, when drilling, the surveyor may input the drilling position of the target borehole and the drilling depth of the target borehole into the terminal, and different drilling depths may correspond to different strata. The terminal may transmit the drilling position and the drilling depth of the target borehole input by the surveyor to the server, and the server receives the drilling position and the drilling depth of the target borehole.

Step 202, the server determines the near borehole of the target borehole according to the borehole position, and acquires the stratum information set of the near borehole.

The server can determine the position of the target borehole and the position of the adjacent borehole of the target borehole by using a GPS (Global Positioning System, Chinese) Positioning System and the borehole position, the formation information set of the borehole comprises the formation sequence of each formation of the borehole, the depth range corresponding to each formation and the formation information of each formation, and the formation information comprises the formation name and the formation description. Optionally, the formation information may further include geological age, plasticity, compactness, circularity, weathering degree, or geological cause of the formation.

The set of formation information adjacent the borehole includes formation information for different formations adjacent the borehole. Optionally, the set of formation information for the adjacent borehole may further include depth ranges corresponding to different formations adjacent to the borehole.

Alternatively, the adjacent borehole of the target borehole may be the closest borehole to the target borehole, or the adjacent borehole of the target borehole may be a borehole whose distance to the target borehole is less than a distance threshold. Thus, adjacent bores to the target bore may be one or more.

Alternatively, the adjacent bore of the target bore may be a final bore, wherein the final bore is: the drilling is completed by the drill hole reaching a predetermined depth and intended purpose, and the hole is called a final hole in geological drilling.

Optionally, the server is provided with a geotechnical engineering database, a project database and a file database. The server can acquire the drilling record data of other exploration units from the geotechnical engineering database, and acquire the positions of the drilled holes and the stratum information sets of the drilled holes obtained by exploration of other units from the drilling record data of other exploration units; the server can also find the positions of the drill holes and the stratum information sets of the drill holes of a plurality of projects which are in exploration from the drill hole record data of the project database; the server can also find the positions of a plurality of boreholes which are surveyed and the stratum information sets of the boreholes from the borehole inventory data of the archive.

Further, the server compares the position of the drill hole of the target drill hole with the positions of the drill holes obtained by the exploration of other exploration units, the position of the drill hole of the project under exploration and the position of the drill hole which is already explored, screens out nearby drill holes from the drill holes obtained by the exploration of other exploration units, the drill hole of the project under exploration and the drill hole which is already investigated, and acquires a stratum information set close to the drill holes.

Optionally, the geotechnical engineering database stores regional geological maps such as a regional bedrock geological map, a regional geological plan, a regional hydrogeological plan, a regional geological structure plan, a regional geological disaster distribution map, a regional geological disaster prone region partition map, a regional mineral resource distribution map, a regional groundwater resource distribution map, a regional land assessment result map, a regional topographic map and the like, and standard specifications related to geotechnical engineering. When searching the regional geological map, the user types in a geographic position, a map name or a map name partial field for searching, the server can display the map name segment from near to far according to the geographic position to the user in the order of the map pieces from full inclusion to partial inclusion. When searching the standard specification related to geotechnical engineering, a user inputs terms for searching, and the server can display related technical specification terms to the user in a sequencing mode according to the strong correlation to the weak correlation of the terms. The geotechnical engineering database can be added, deleted, checked and modified by users.

Optionally, the project database stores data of the survey project, including a new project name and a new project number, a project department establishment record, a project planning scheme, project field data, test data, field process monitoring data, a project process file, a project-related conference file, and the like. Wherein: the project department establishment record comprises the nominator, the nominator and the time of the nominator who is responsible for the project and the technology, the name of the project department, the establishment time of the project department, and the change record, the change time and the changers of the above information. The project planning scheme comprises the following records generated by the survey outline and the planning scheme flow: the personnel configuration table generated by the former configuration personnel comprises a configuration person, a configured person, configuration time, the post of the configured person, change records, change time and a change person. The data is generated by the task platform, and the data is stored in the project database after the process is finished; the engineering project requirement review process comprises the steps of generating an engineering receipt record, a customer property use control list, an engineering project requirement review record table and the like in the engineering project requirement review process; compiling a survey outline report document formed by the survey outline; the method comprises the following steps of (1) surveying an opinion book to be checked just before reconnaissance generated by the survey outline, an opinion book to be reviewed just before reconnaissance, an outline change review record sheet, an engineering issue record and the like; the file issuing registry and the return record generated in the process of environment, safety and technical return, and the like. Project field data refers to drill hole inventory data, in-situ test data, and geophysical data. The drilling borehole logging data includes borehole formation information, sampling information, borehole hydrogeological information, core photographs, hole opening final hole time, borehole coordinates, and drilling rig information. The in-situ test data comprises standard penetration test data, side pressure test data, resistivity test data and the like. The test data refers to rock and soil sampling test data of the sample. The field process monitoring data refers to high-definition videos and high-definition pictures shot by a high-definition camera in the field process.

Optionally, the file database stores survey result data. The survey process files and related data include: project planning data (survey outline and its proofreading, internal proofreading), project achievement data (survey achievement report and its proofreading, survey achievement cross-bottom file and its cross-bottom record, survey file quality inspection report, total and consultation examination paper), project achievement evaluation data (customer satisfaction questionnaire), project organization data (project department establishment notice, project responsible manual work quality final responsibility commitment book, bid file and its review quality inspection record, bid notice book, contract and its review record, etc.), project field operation implementation record data (rock core photo, drilling measurement record list and its proofreading, survey class report, survey record list, intermediate survey record list, survey field operation field environment safety inspection list, internal survey and examination list, project field operation field environment safety inspection list, internal survey and examination record list, project field operation management record list, project management report, project management record list, project management, A result report and a correction report of patrol and appraisal), and transaction data (design-related drawings and documents provided by owners, quality inspection records such as customer property use control lists, text receiving/sending records, technical safety transaction records and the like).

And step 203, for each drilling depth, the server acquires stratum information of the target stratum in the adjacent drilling hole from the stratum information set of the adjacent drilling hole according to the drilling depth.

The target stratum is a stratum corresponding to the drilling depth, and the stratum corresponding to the drilling depth in the target borehole can be called a target stratum; the formation in the adjacent hole of the target borehole corresponding to this drilling depth is also referred to as the target formation.

Optionally, when the drilling depth of the stratum is calculated, a top-down calculation principle is followed, when two adjacent strata are subjected to layer change, the depth of the bottom plate of one stratum is the depth of the top plate of the next stratum, and the difference between the two adjacent drilling depths can be regarded as the depth range in which one stratum is located.

The server can match the target depth range with the depth ranges of the stratums included in the stratum information set of the adjacent borehole, mark the stratum which is overlapped with the target depth range in the adjacent borehole as the target stratum, and acquire the stratum information of the target stratum in the adjacent borehole.

And 204, for each drilling depth, the server sends the stratum information of the target stratum in the adjacent drilling hole to the terminal, wherein the stratum information of the target stratum in the adjacent drilling hole is used for triggering the terminal to determine the stratum information of the target stratum of the target drilling hole according to the stratum information of the target stratum in the adjacent drilling hole.

As described above, the depth range in which the target formation is located is most overlapped with the target depth range corresponding to the drilling depth of the target borehole, so that the probability that the target formation is the same as the formation corresponding to the drilling depth of the target borehole is the highest, and the server transmits formation information of the target formation in the adjacent borehole to the terminal. And the stratum information triggering terminal of the target stratum in the adjacent borehole determines the stratum information of the target stratum from the stratum information of the target stratum in the adjacent borehole.

Because the adjacent boreholes can be multiple, the corresponding stratum information of the target stratum in the adjacent boreholes is multiple, the terminal receives the stratum information of the target stratum in the adjacent boreholes from the server and displays the stratum information of the target stratum in the adjacent boreholes to the surveyor.

Optionally, the process of determining the formation information of the target formation from the formation information of the target formation in the adjacent borehole by the terminal may be: and the terminal acquires a selection instruction input by the surveyor, and the selection instruction is used for selecting one of the stratum information of the target stratum in the adjacent boreholes as the stratum information of the target stratum of the target borehole.

Optionally, if the stratum information of the target stratum in the plurality of adjacent boreholes displayed by the terminal is greatly different from the observation result of the prospecting staff on the core sample, the prospecting staff may manually fill in the stratum information of the target stratum of the target borehole.

In the method for processing engineering survey data provided by the embodiment of the application, when a target borehole in a target area is drilled, a survey worker inputs the drilling position of the target borehole and the drilling depth of the target borehole to a terminal, the terminal sends the drilling position and the drilling depth to a server, the server screens out a near borehole of the target borehole according to the drilling position and obtains a stratum information set of the near borehole, and the stratum information set of the near borehole comprises stratum information of different stratums; then the server searches stratum information of a target stratum corresponding to the drilling depth from the stratum information of the adjacent drilling holes in a centralized manner according to the drilling depth, and sends the stratum information of the target stratum in the adjacent drilling holes to the terminal, and the terminal can determine the stratum information of the stratum corresponding to the drilling depth of the target drilling holes from the stratum information of the target stratum in the adjacent drilling holes. According to the stratum information prediction method and device, stratum information recommendation is conducted according to each drilling depth of the target drilling hole, and based on the principle that the target drilling hole is closer to the adjacent drilling hole in geography, and therefore the probability that the target drilling hole and the adjacent drilling hole are the same or similar in stratum corresponding to the same drilling depth is higher, the stratum information of the target drilling hole is predicted by obtaining the known stratum information of the adjacent drilling hole, and the accuracy of the predicted stratum information of the target drilling hole is higher.

In an embodiment of the present application, the method for processing engineering survey data provided in the embodiment of the present application further includes:

and for each drilling depth, the server receives the stratum information of the target stratum in the target drilling hole, which is sent by the terminal, and stores the stratum information of the target stratum in the target drilling hole into the stratum information set of the target drilling hole.

The formation information of the target formation in the target borehole may be selected from formation information of a plurality of adjacent target formations in the borehole and standard formation information of the target area. The standard stratum information includes stratum orders and stratum names of different stratums, and optionally, the standard stratum information may further include stratum description, stratum geological age, plastic state, compactness, circularity, weathering degree or geological cause and the like.

For each drilling depth, the server sends formation information of a formation adjacent to a target formation in the drill hole to the terminal, and correspondingly, for each drilling depth, the terminal also sends formation information of a formation corresponding to the drilling depth in the target drill hole to the server. The server receives and stores formation information for a target formation in a target borehole into a set of formation information for the target borehole. When the target borehole is terminated, the formation information set of the target borehole includes formation information of each formation (the drilling depth corresponds to the formation) of the target borehole.

It should be noted that, in the embodiment of the present application, when the stratum information of the target stratum in the adjacent borehole provided by the server is very different from the stratum information of the stratum judged by the surveyor in the actual target borehole according to experience and observation results, the terminal may select the stratum information of the target stratum in the target borehole from the standard stratum information of the target area.

Optionally, when the server cannot provide the formation information of the target formation in the adjacent borehole, that is, when the server does not find the adjacent borehole meeting the condition, in the embodiment of the present application, the terminal may select the formation information of the target formation in the target borehole from the standard formation information of the target area.

In an optional implementation manner, the method for processing engineering survey data provided by the embodiment of the present application further includes:

the terminal obtains a batch editing instruction input by a user, wherein the batch editing instruction is used for uniformly editing target drill holes in a target area.

The terminal can obtain standard stratum information from the survey outline according to the batch editing and recording instructions, and store the characteristic stratum information into the stratum information set of the target borehole.

The user can input the batch cataloguing instruction in a visual interface of the terminal. And the terminal acquires the batch editing instructions, acquires standard stratum information from the survey outline according to the instructions of the batch editing instructions, and stores the standard stratum information into a stratum information set of the target borehole. When a target borehole is drilled, if the stratum form presented by the core sample of the stratum corresponding to a certain drilling depth in the target borehole is the same as or substantially the same as the stratum description and/or the stratum name of a certain stratum in the standard stratum information, the user only needs to input the drilling depth in the stratum information corresponding to the stratum information set, and then the stratum information of the stratum corresponding to the drilling depth can be obtained.

Optionally, if the stratum corresponding to a certain drilling depth of the target borehole cannot be found from the standard stratum information, the user may name and describe the stratum according to personal experience and observation results of the core sample, so as to add a stratum name and a stratum description.

According to the embodiment of the application, the standard stratum information is stored in the stratum information set of the target borehole in advance, and when the target borehole is drilled, the drilling depth corresponding to each stratum in the stratum information set of the target borehole is input according to an actual drilling result, so that the drilling of the target borehole is completed. In the embodiment of the application, stratum information recommendation is not needed according to each drilling depth of the target drilling hole, but each stratum of the target drilling hole is processed in batch, and the data processing efficiency is improved.

Referring to fig. 3, which illustrates a method for processing engineering survey data provided by an embodiment of the present application, the method for processing engineering survey data may be applied to a server and a terminal in the implementation environment shown in fig. 1, and as shown in fig. 3, the method for processing engineering survey data may include the following steps:

step 301, the server obtains rock and soil sampling test data of rock and soil in the target drilling hole and test data of an in-situ test performed at the position of the target drilling hole.

The in-situ test is to test the rock-soil property at the original position or basically under the in-situ state and stress condition, and the in-situ test comprises a deformation test, a strength test and a ground stress test. Alternatively, in situ testing may be performed on a portion of the formation.

Rock-soil sampling tests are generally carried out in laboratories and are mainly used for measuring indexes representing structures and components of rock and soil, permeability indexes, deformation performance, strength indexes and the like. Optionally, the rock-soil sampling tests performed on the rock-soil samples of different strata are different in test type. For example, sandy soil, the water content of which is to be measured. Rock, on the other hand, does not require water content measurement.

The rock soil sampling test equipment and the in-situ test equipment can be directly connected with the server and directly uploaded to the server through a web end of the server.

Step 302, the server stores the rock-soil sampling test data and the test data of the in-situ test into a stratum information set of the target borehole.

And on the basis of obtaining the stratum information set of the target borehole, storing rock-soil sampling test data of each stratum corresponding to the target borehole and test data of an in-situ test into the stratum information of each stratum to form the stratum information set of the target borehole.

In an embodiment of the present application, the method for processing engineering survey data further includes:

the server generates a three-dimensional geological model of the target borehole from the set of formation information for the target borehole.

The server is provided with a BIM system, and the BIM system can automatically build a three-dimensional geological model of each drill hole in real time by utilizing the stratum information of the stratum of each drill hole on the server. When the stratum information set of the target borehole is updated, the three-dimensional geological model is automatically updated.

The stratum name, the stratum description, the rock test data and the in-situ test data of each stratum can be observed on the three-dimensional geological model.

For example: the target borehole has acquired two drilling depths and formation information for two formations from the two drilling depths, and the BIM system may then build a three-dimensional geological model of the target borehole in real time from the formation information for the two formations. When formation information is obtained for a third formation of the target borehole, the BIM system automatically updates to a three-dimensional geological model that includes the three formations.

Alternatively, the terminal may request a three-dimensional geological model of a target borehole from the service and store the acquired three-dimensional geological model in local memory.

Optionally, the server may be used to present a three-dimensional geological model. When a certain stratum model of a three-dimensional geological model of a certain target borehole is displayed, all information related to the stratum can be obtained by linking the stratum model to a project database through a stratum number.

Referring to fig. 4, a method for processing engineering survey data provided by an embodiment of the present application is shown, where the method for processing engineering survey data may be applied to a server and a terminal in the implementation environment shown in fig. 1, and as shown in fig. 4, the method for processing engineering survey data may include the following steps:

step 401, the server obtains the position of the target area.

Alternatively, the location of the target area may be expressed in terms of latitude and longitude.

Optionally, the server may receive, through the web end of the server, the latitude and longitude of the target area input by the user, so as to obtain the location of the target area.

In a possible implementation manner, the process of the server obtaining the position of the target area may include the following steps:

a1: a topographical plan view of the target area and a borehole plan view of the target area are acquired.

Prior to the surveyor surveying the target area, the geodesy and topography of the target area, the characteristics of the geodesy and the type of building planned to be constructed on the target area, such as a stadium or a residential building, need to be known in advance. The terrain plan of the target area can show the terrain and landform and terrain features of the target area, and the terrain plan can comprise position coordinates of ground objects located in the target area.

The surveyor can design the positions of the drill holes according to the topographic plan of the target area and the types of buildings planned to be constructed on the target area to obtain a drill hole plane layout diagram of the target area. The borehole floorplan may include the number of boreholes drilled within the target area, as well as the location coordinates of the individual boreholes.

A2: and acquiring the position of the target area according to the position coordinates included in the terrain plan or the position coordinates included in the drilling plan.

As described above, the terrain plan includes the location coordinates of the terrain of the target area, and the borehole plan includes the location coordinates of the respective boreholes. The position of the target area can be determined according to the position coordinates of the ground object or the position coordinates of each drill hole.

Alternatively, the position coordinates of the ground object may be expressed in latitude and longitude.

Optionally, the target area is an area where a field to be surveyed is located, and the position of the target area may be a position of a ground object or a position of a drill hole in the target area or a position of a central point of the target area.

Step 402, the server obtains standard stratum information of the target area according to the position of the target area.

The standard formation information may include a formation sequence, a formation name, and a formation description of each formation. The standard formation information may show the possible formations and the formation descriptions of the corresponding formations, and the drilling depth range corresponding to each formation is not included in the standard formation information.

In a possible implementation manner, a user can set standard stratum information of a target area by himself/herself, the set standard stratum information of the target area is uploaded to a server through a web end of the server, and the server stores the received standard stratum information of the target area input by the user in a project database.

In one possible implementation, as shown in fig. 5, the process of the server obtaining the standard formation information of the target area may include:

step 501, the server acquires the area standard stratum information of the target area, the standard stratum information of the adjacent area to be surveyed and the standard stratum information of the adjacent area after the survey is completed according to the position of the target area.

The server can obtain the regional standard stratum information of the region from the regional data of the region where the project site to be surveyed is stored in the geotechnical engineering database.

Generally, a plurality of survey projects are surveyed simultaneously, a target area corresponding to each survey project has standard stratum information corresponding to the target area, and the server can acquire the standard stratum information corresponding to other survey projects which are carrying out survey operations from the project database.

In other survey projects in which survey operations are being performed, the stratum corresponding to the survey project closer to the target area has a higher similarity to the stratum of the target area, and therefore the standard stratum information of the target area can refer to the standard stratum information corresponding to the survey project closer to the target area.

Alternatively, the server may obtain the project positions of other survey projects which are performing the survey operation, and when the distance from the project position of the other survey project which is performing the survey operation to the position of the target area is smaller than the first distance threshold, it indicates that the distance from the other survey project which is performing the survey operation to the target area is shorter, and therefore, the standard formation information of the other survey projects which are performing the survey operation and which are closer to the target area is obtained.

The server can acquire standard stratum information of the neighboring area which is already surveyed from the archive database, project data of the survey project which is already surveyed is stored in the archive database, the server can acquire project positions of a plurality of survey projects which are already surveyed from the archive database, the distance from the project position of each survey project which is already surveyed to the target area is judged, when the distance from the project position of the survey project which is already surveyed to the target area is smaller than a second distance threshold value, the project position of the survey project which is already surveyed is closer to the target area, and the standard stratum information of the target area can refer to the standard stratum information of the neighboring area which is already surveyed based on the same reason.

Step 502, the server selects one of the area standard stratum information of the target area, the standard stratum information of the adjacent area to be surveyed and the standard stratum information of the adjacent area after the survey is completed as the standard stratum information of the target area.

Optionally, the server may display the area standard stratum information of the target area, the standard stratum information of the neighboring area to be surveyed, and the standard stratum information of the neighboring area that has been surveyed to the user through a web end of the server; and the server receives a selection instruction input by the user, and takes standard stratum information selected by the user from the area standard stratum information of the target area, the standard stratum information of the adjacent area to be surveyed and the standard stratum information of the adjacent area after the survey is finished as the standard stratum information of the target area according to the selection instruction.

In the embodiment of the application, the server acquires the regional standard stratum information, the standard stratum information of the adjacent region in exploration and the standard stratum information of the adjacent region after exploration according to the position of the target region, and selects the standard stratum information of the target region from the regional standard stratum information, the standard stratum information of the adjacent region in exploration and the standard stratum information of the adjacent region after exploration, so that the function of intelligently predicting the standard stratum information of the target region is realized, and an exploration worker can roughly know the stratum possibly appearing in the target region through the standard stratum of the target region, so that drilling can be performed according to the geotechnical characteristics of different strata, and the drilling efficiency and the integrity of a core sample are improved.

And 403, generating a survey outline by the server according to the standard stratum information of the target area.

The survey project needs to compile a survey outline before entering a target area to carry out field drilling work. In an embodiment of the present application, the survey outline includes standard stratigraphic information of the target area.

Optionally, the survey outline further comprises survey personnel arrangement, survey equipment arrangement, construction period arrangement, drilling position information, drilling record requirements, drilling technical requirements, core sample taking requirements, in-situ test requirements, rock and soil sampling test requirements, survey project work schedule arrangement, survey equipment requirements and the like. And the prospecting personnel can drill holes according to the prospecting outline to obtain the core sample and record the drilled holes. The server is further provided with an enterprise personnel library and an equipment library, the arrangement of the surveyors can be that the server can obtain personnel information from the enterprise personnel library, and the users can arrange the surveyors according to the personnel information in the enterprise personnel library. The arrangement of the survey equipment can be that the server acquires information related to the survey equipment from the equipment library and displays the information to the user, and the user arranges the survey equipment according to the displayed information of the survey equipment.

Optionally, the enterprise personnel repository stores enterprise personnel information, including personnel names, post functions, personal electronic signatures, telephone numbers, electronic mailboxes, and other common communication tool information. Where the person's name, post function and telephone number are registered by the system administrator in the background. Other information is added by the user after logging in the system.

Optionally, the device library includes a device information storage function and a device in and out management function. The equipment information comprises relevant information such as delivery data (including manufacturer business licenses, instructions, certificates, invoices and the like) and instrument calibration/verification states (including verification certificates) of equipment such as a drilling machine, a geophysical prospecting device, an in-situ test instrument, an indoor rock-soil sampling test instrument and the like. The equipment library can be used for recording historical information of equipment such as loan, return, repair, verification records and the like and the current use state.

The device inventory management functions may be: the equipment library can assign a unique code to each instrument, and the code cannot be changed and cannot be repeatedly assigned to other instrument after being assigned. If the device is a drill, the drill and captain are set as a combination as a unique code. When the combination of the drilling machine and the captain is changed, a code is assigned again. When a certain item needs to use the instrument equipment, the equipment code is bound. The same instrument and equipment cannot bind two items at the same time, and each binding action can automatically release the previous binding relationship. When the instrument equipment returns, all binding relations of the equipment can be automatically unbound. The record of the use of the instrument, which has been formed before, is not affected by the unbinding action.

Optionally, after the composition of the survey outline is completed,

and step 404, the server sends the survey outline to the terminal.

The survey outline can be used for guiding a survey worker to carry out survey operation on a target area, the server sends the survey outline to the terminal, and the survey worker can see the survey outline through the terminal and carry out survey according to requirements and regulations in the survey outline.

In an alternative embodiment, as shown in fig. 6, after step 301, the method for processing engineering survey data provided in the embodiment of the present application may further include the following steps:

step 601, the server acquires subcontractor recommendation information of the target area according to the position of the target area.

In the embodiment of the application, the subcontractor is a construction party for drilling in a field environment, and subcontractor personnel drill holes in a target area to obtain a core sample. The investigators determine formation information for each formation in the borehole by observing the core samples. The integrity of the core sample determines the accuracy of the stratum information of the stratum determined by the reconnaissance personnel, so that the selection of the subcontractors with strong construction capacity plays an important role in improving the accuracy of the stratum information.

In an alternative embodiment, the process of obtaining the SCE recommendation information of the target area by the server may include the following steps:

b1: and acquiring basic information of a plurality of subcontractors.

The server is provided with a subcontractor database, the subcontractor database stores basic information of each subcontractor, and the basic information of each subcontractor comprises a resident area position of each subcontractor, historical workload of each subcontractor and a survey operation level of each subcontractor.

The resident area position indicates the position of the construction area of the subcontractor. The historical workload of the SCE may be the maximum value of the workload of the SCE in the completed survey project, and optionally, the database of the SCE further stores the workload of the SCE in each survey project. The survey operation grade of each subcontractor represents the grade of a surveyor on the construction performance of the subcontractor, and the construction performance of the subcontractor can comprise the operation performance of the subcontractor in a specific rock-soil layer, such as drilling speed, core quality (core photo) and the like.

B2: and screening out a plurality of first subcontractors meeting the first condition according to the position of the target area and the resident area position of each subcontractor.

Wherein the first condition is that a distance between the location of the resident area and the location of the target area is less than a distance threshold. And according to the first condition, the distance between each subcontractor and the target area to be surveyed can be judged.

B3: and screening a plurality of second subcontractors meeting a second condition from the plurality of first subcontractors according to the historical workload of each subcontractor.

And the second condition is that the difference value of the historical workload and the workload of the survey target area is smaller than the difference threshold value. And judging whether the subcontractor can carry out the workload of the survey target area or not according to the second condition.

B4: and screening a plurality of third subcontractors meeting a third condition from the plurality of second subcontractors according to the investigation operation grade of each subcontractor.

Wherein the third condition comprises a condition that the survey job rank is greater than a rank threshold. And judging the construction quality of the subcontractor according to the third condition.

B5: and generating subcontractor recommendation information according to the basic information of the third subcontractor.

The SCE recommendation information may include a plurality of SCEs. Optionally, the subcontractors can be sorted according to the investigation operation grades of the subcontractors, and the sorting results are displayed through a server web side.

Step 602, the server generates a survey outline according to the standard stratum information and the subcontractor recommendation information.

The surveying staff may perform the surveying operation according to the survey outline, and optionally, the surveying staff may directly select one or more subcontractors from the plurality of subcontractors in the subcontractor recommendation information to perform the surveying drilling operation or other construction tasks.

Referring to fig. 7, which illustrates a method for processing engineering survey data provided by an embodiment of the present application, the method for processing engineering survey data may be applied to a terminal in the implementation environment shown in fig. 1, and as shown in fig. 7, the method for processing engineering survey data may include the following steps:

step 701, when drilling the target borehole, the terminal receives the borehole position of the target borehole and a plurality of drilling depths of the target borehole, which are input by the surveyor.

In the process of drilling the target borehole by the subcontractor, the prospecting personnel can input the drilling position and the drilling depth of the target borehole which is being drilled into the terminal. Wherein a target borehole is a hole drilled by a surveying person in a target area to be surveyed.

And step 702, for each drilling depth, the terminal obtains stratum information of a target stratum in the adjacent drilling hole of the target drilling hole according to the drilling position and the drilling depth.

Wherein the adjacent borehole is determined according to the position of the borehole, and the target stratum is a stratum corresponding to the drilling depth.

In one possible implementation, as shown in fig. 8, the process of obtaining formation information of a target formation in an adjacent borehole of a target borehole according to the borehole position and the drilling depth may include:

step 801, the terminal sends the drilling position and the drilling depth to a server.

And step 802, when the target drilling hole is drilled, the server receives the drilling position of the target drilling hole and a plurality of drilling depths of the target drilling hole, which are sent by the terminal of the surveyor.

Step 803, the server determines the near borehole of the target borehole according to the borehole position, and acquires the stratum information set of the near borehole.

And 804, for each drilling depth, the server acquires stratum information of the target stratum in the adjacent drilling hole from the stratum information set of the adjacent drilling hole according to the drilling depth.

For each drilling depth, the server sends formation information for the formation adjacent to the target formation in the borehole to the terminal, step 805.

In step 806, the terminal receives the formation information sent by the server adjacent to the target formation in the borehole.

The near borehole is determined by the server according to the position of the borehole, and the stratum information of the target stratum in the near borehole is acquired by the server from the stratum information set of the near borehole according to the drilling depth, wherein the stratum information set of the near borehole comprises stratum information of different stratums of the near borehole.

In another possible implementation manner, in a case that the terminal cannot obtain formation information of a target formation in an adjacent borehole from the server when the network is disconnected between the terminal and the server, as shown in fig. 9, the process of obtaining the formation information of the target formation in the adjacent borehole of the target borehole according to the borehole position and the drilling depth may include:

step 901, the terminal determines a near borehole from the already surveyed boreholes in the target area according to the positions of the boreholes, and acquires a stratum information set of the near borehole.

The local memory of the terminal stores the position of the drill hole which is already surveyed in the target area and the stratum information set of the drill hole. The terminal may search the drill hole closest to the target drill hole from the local storage as the adjacent hole of the target drill hole according to the position of the target drill hole, or the terminal may search the drill hole of which the distance from the target drill hole is smaller than the distance threshold from the local storage as the adjacent hole of the target drill hole according to the position of the target drill hole.

The terminal can obtain the stratum information set of the adjacent borehole searched in the local memory, the stratum information set of the adjacent borehole comprises stratum information of different stratums of the adjacent borehole, and the stratum information can comprise stratum names and stratum descriptions, stratum geological times, plastic states, compactness, roundness, weathering degree or geological causes and the like.

And 902, the terminal acquires stratum information of the target stratum in the adjacent borehole from the stratum information set of the adjacent borehole according to the drilling depth.

The target stratum is a stratum corresponding to the drilling depth, and the stratum corresponding to the drilling depth in the target borehole can be called a target stratum; the formation in the adjacent hole of the target borehole corresponding to this drilling depth is also referred to as the target formation.

When the drilling depth of the stratum is calculated, a top-down calculation principle is observed, when two adjacent strata are subjected to layer changing, the depth of the bottom plate of one stratum is the depth of the top plate of the next stratum, and the difference value of the two adjacent drilling depths can be regarded as the depth range of one stratum, so in the embodiment of the application, a target depth range can be calculated for each drilling depth by the terminal, and the stratum corresponding to the target depth range is the stratum corresponding to the drilling depth.

The terminal can match the target depth range with the depth ranges of all the stratums included in the stratum information set of the adjacent borehole, mark the stratum which is overlapped with the target depth range in the adjacent borehole as the target stratum, and acquire the stratum information of the target stratum in the adjacent borehole.

And 703, for each drilling depth, the terminal determines stratum information of a target stratum of the target drilling hole according to stratum information of the target stratum close to the drilling hole.

In one possible implementation, as shown in fig. 10, the process of determining formation information of a target formation of a target borehole from formation information of a target formation adjacent to the borehole may include the steps of:

step 1001, the terminal displays standard stratum information and stratum information of a target stratum in an adjacent borehole.

The standard stratum information is obtained by the terminal from a survey outline, and the survey outline is sent to the terminal by the server. The terminal can display stratum information of the target stratum in the adjacent borehole, and the exploration personnel can determine the stratum information of the target stratum in the target borehole from the displayed stratum information of the target stratum in the adjacent borehole. And when the stratum information of the target stratum in the adjacent borehole displayed by the terminal has a larger difference with the actual borehole, optionally, the terminal can display the standard stratum information together with the stratum information of the target stratum in the adjacent borehole. From the standard formation information, the investigator may determine formation information for the target formation in the target borehole.

In step 1002, the terminal receives a selection instruction for standard formation information or formation information of a target formation in an adjacent borehole.

The survey crew may enter a selection command at the terminal, which receives the selection command for selecting formation information for the target formation in the target borehole from standard formation information or formation information adjacent to the target formation in the borehole.

And step 1003, the terminal determines the stratum information aimed at by the selection instruction as the stratum information of the target stratum in the target borehole.

And the terminal determines the stratum information corresponding to the selection instruction as the stratum information of the target stratum in the target borehole according to the selection instruction. The embodiment of the application does not limit the interaction process between the survey personnel and the terminal.

And step 1004, the terminal sends the stratum information of the target stratum in the target borehole to a server.

In the networked state, the terminal can send the stratum information of the target stratum in the target borehole to the server, and the server stores the stratum information of the target borehole into the stratum information set.

Referring to fig. 11, a method for processing engineering survey data provided by an embodiment of the present application is shown, and the method for processing engineering survey data can be applied to the implementation environment of fig. 1, and the method includes the following steps:

step 1101, the server acquires the position of the target area, and acquires standard stratum information and subcontractor recommendation information of the target area according to the position of the target area.

Step 1102, the server obtains a survey outline according to the standard stratum information and the subcontractor recommendation information of the target area and sends the survey outline to the terminal.

Step 1103, the terminal receives the survey outline and stores the survey outline in the local memory.

And step 1104, the terminal receives the drilling position and the drilling depth of the target drilling hole input by the survey personnel.

And 1105, the terminal sends the drilling position and the drilling depth of the target drilling hole to the server.

The server receives the drill hole location and drilling depth of the target borehole, step 1106.

Step 1107, the server determines the stratum information of the target stratum in the adjacent borehole of the target borehole according to the borehole position and the drilling depth of the target borehole, and sends the stratum information of the target stratum in the adjacent borehole to the terminal.

Step 1108, the terminal displays the stratum information and the standard stratum information of the target stratum in the adjacent borehole, and determines the stratum information of the target stratum of the target borehole according to the stratum information and the standard stratum information of the target stratum in the adjacent borehole.

And step 1109, the terminal sends the stratum information of the target stratum in the target borehole to a server.

Step 1110, the server receives the stratum information of the target stratum in the target borehole, which is sent by the terminal, and stores the stratum information of the target stratum in the target borehole into the stratum information set of the target borehole.

As described above, in the embodiment of the present application, the near borehole of the target borehole and the formation information of the target formation of the near borehole are found through the borehole position and the drilling depth of the target borehole, and the formation information of the target formation in the target borehole is determined according to the formation information of the target formation of the near borehole and the standard formation information, so that the accuracy of the obtained formation information of the target formation is improved.

Referring to fig. 12, fig. 12 is a schematic view illustrating an apparatus for processing engineering survey data according to an embodiment of the present disclosure. The apparatus for processing engineering survey data may be configured in a server as shown in fig. 1, and as shown in fig. 12, the apparatus for processing engineering survey data includes a first receiving module 1201, a near drilling module 1202, a first formation information module 1203, and a transmitting module 1204.

A first receiving module 1201, configured to receive, when performing a drilling operation on a target borehole, a borehole position of the target borehole and a plurality of drilling depths of the target borehole, which are sent by a terminal of an inspector, where the target borehole is a hole drilled by the inspector in a target area to be inspected;

the near borehole module 1202 is configured to determine a near borehole of the target borehole according to the borehole position, and acquire a formation information set of the near borehole, where the formation information set of the near borehole includes formation information of different formations of the near borehole;

a first stratum information module 1203, configured to, for each drilling depth, obtain, in a centralized manner, stratum information of a target stratum in the adjacent borehole from the stratum information of the adjacent borehole according to the drilling depth, where the target stratum is a stratum corresponding to the drilling depth;

a sending module 1204, configured to send, for each drilling depth, formation information of a target formation in the adjacent borehole to the terminal, where the formation information of the target formation in the adjacent borehole is used to trigger the terminal to determine, according to the formation information of the target formation in the adjacent borehole, formation information of the target formation in the target borehole.

In one embodiment of the present application, the apparatus further comprises: a storage module for storing the data of the data,

for each drilling depth, the storage module is used for receiving stratum information of a target stratum in a target drilling hole, which is sent by the terminal, and storing the stratum information of the target stratum in the target drilling hole into a stratum information set of the target drilling hole;

the stratum information of the target stratum in the target borehole is obtained by the terminal according to the stratum information of the target stratum in the adjacent borehole and standard stratum information of the target area, and the standard stratum information comprises a stratum order and a stratum name.

In one embodiment of the present application, the apparatus further comprises: a test data acquisition module for acquiring the test data,

the test data acquisition module is used for acquiring rock and soil sampling test data of rock and soil in the target drilling hole and test data of an in-situ test performed at the position of the target drilling hole;

and storing the rock-soil sampling test data and the test data of the in-situ test into the stratum information set of the target borehole.

In one embodiment of the present application, the apparatus further comprises: and the three-dimensional modeling module is used for generating a three-dimensional geological model of the target drilling hole according to the stratum information set of the target drilling hole.

In one embodiment of the present application, the apparatus further comprises: a survey outline generation module for

Acquiring the position of a target area; acquiring standard stratum information of the target area according to the position of the target area; generating a survey outline according to the standard stratum information; and sending the survey outline to the terminal.

In one embodiment of the present application, the apparatus further comprises: the reconnaissance outline generation module is further configured to: acquiring a topographic plan of a target area and a drilling plan layout of the target area, wherein the topographic plan comprises position coordinates of ground objects in the target area, and the drilling plan layout comprises position coordinates of drill holes to be drilled in the target area;

and acquiring the position of the target area according to the position coordinates included in the topographic plan or the position coordinates included in the drilling plan.

In one embodiment of the present application, the apparatus further comprises: the reconnaissance outline generation module is further configured to: acquiring regional standard stratum information of the target region, standard stratum information of an adjacent region to be surveyed and standard stratum information of a surveyed adjacent region according to the position of the target region;

and selecting one of the area standard stratum information of the target area, the standard stratum information of the adjacent area to be surveyed and the standard stratum information of the adjacent area after the survey is completed as the standard stratum information of the target area.

In one embodiment of the present application, the apparatus further comprises: the reconnaissance outline generation module is further configured to: acquiring subcontractor recommendation information of the target area according to the position of the target area;

correspondingly, the survey outline is generated according to the standard stratum information, and the survey outline comprises the following steps:

and generating a survey outline according to the standard stratum information and the subcontractor recommendation information.

In one embodiment of the present application, the apparatus further comprises: the reconnaissance outline generation module is further configured to: acquiring basic information of a plurality of subcontractors, wherein the basic information of each subcontractor comprises a resident area position of each subcontractor, historical workload of each subcontractor and a survey operation grade of each subcontractor;

screening out a plurality of first subcontractors which meet a first condition according to the position of the target area and the resident area position of each subcontractor, wherein the first condition is that the distance between the resident area position and the position of the target area is smaller than a distance threshold;

screening a plurality of second subcontractors meeting a second condition from the plurality of first subcontractors according to the historical workload of each subcontractor, wherein the second condition is that the difference value between the historical workload and the workload of the survey target area is smaller than a difference threshold value;

and screening a plurality of third subcontractors meeting a third condition from the plurality of second subcontractors according to the survey operation grade of each subcontractor, and generating subcontractor recommendation information according to the basic information of the third subcontractors, wherein the third condition comprises the condition that the survey operation grade is greater than a grade threshold value.

For specific limitations of the processing device for the engineering survey data, reference may be made to the above limitations on the processing method for the engineering survey data, which are not described herein again. The modules in the engineering survey data processing device can be wholly or partially implemented by software, hardware and a combination thereof. The modules may be embedded in hardware or may be independent of a processor in a computer device. Or may be stored in a memory of the computer device in a software form, so that the processor can call and execute the operations corresponding to the above modules.

Referring to fig. 13, fig. 13 is a schematic view of an apparatus for processing engineering survey data according to an embodiment of the present disclosure. The processing device of the engineering survey data may be configured in the terminal as shown in fig. 1, and as shown in fig. 13, the processing device of the engineering survey data includes a second receiving module 1301, a second formation information module 1302 and a target borehole formation information module 1303.

A second receiving module 1301, configured to receive, when performing a drilling operation on a target borehole, a drilling position of the target borehole and a plurality of drilling depths of the target borehole, which are input by a surveying staff, where the target borehole is a hole drilled by the surveying staff in a target area to be surveyed;

a second formation information module 1302, configured to, for each drilling depth, obtain, according to the drilling position and the drilling depth, formation information of a target formation in an adjacent borehole of the target borehole, where the adjacent borehole is determined according to the drilling position, and the target formation is a formation corresponding to the drilling depth;

and the target borehole stratum information module 1303 is used for determining stratum information of a target stratum of the target borehole according to stratum information of the target stratum in the adjacent borehole for each drilling depth.

In one embodiment of the present application, the second formation information module 1302 is further configured to send the borehole location and drilling depth to a server;

and receiving stratum information of a target stratum in the adjacent borehole sent by the server, wherein the adjacent borehole is determined by the server according to the position of the borehole, the stratum information of the target stratum in the adjacent borehole is obtained by the server from the stratum information set of the adjacent borehole according to the drilling depth, and the stratum information set of the adjacent borehole comprises stratum information of different stratums of the adjacent borehole.

In an embodiment of the present application, the second formation information module 1302 is further configured to determine a near borehole from the boreholes in the target area that have been surveyed according to the borehole position, and obtain a formation information set of the near borehole, where the formation information set of the near borehole includes formation information of different formations of the near borehole;

and acquiring stratum information of the target stratum in the adjacent borehole from the stratum information set of the adjacent borehole according to the drilling depth.

In an embodiment of the present application, the target borehole formation information module 1303 is further configured to display standard formation information and formation information of a target formation in an adjacent borehole, where the standard formation information includes a formation order and a formation name;

receiving a selection instruction aiming at standard stratum information or stratum information of a target stratum in an adjacent borehole;

determining the stratum information aimed at by the selection instruction as the stratum information of a target stratum in a target borehole;

and sending the stratum information of the target stratum in the target borehole to a server.

For specific limitations of the processing device for the engineering survey data, reference may be made to the above limitations on the processing method for the engineering survey data, which are not described herein again. The modules in the engineering survey data processing device can be wholly or partially implemented by software, hardware and a combination thereof. The modules may be embedded in hardware or may be independent of a processor in a computer device. Or may be stored in a memory of the computer device in a software form, so that the processor can call and execute the operations corresponding to the above modules.

In one embodiment of the present application, a server is provided, the internal structure of which may be as shown in fig. 14, the server comprising a processor, a memory, a network interface connected through a system bus. Wherein the processor of the server is configured to provide computing and control capabilities. The memory of the server comprises a nonvolatile storage medium and an internal memory. The non-volatile storage medium stores an operating system and a computer program. The internal memory provides an environment for the operation of an operating system and computer programs in the non-volatile storage medium. The network interface of the server is used for communicating with external network equipment through network connection. The computer program, when executed by a processor, performs the steps of a method of processing engineering survey data.

Those skilled in the art will appreciate that the architecture shown in fig. 14 is merely a block diagram of some of the structures associated with the disclosed aspects and is not intended to limit the computing devices to which the disclosed aspects apply, as particular computing devices may include more or less components than those shown, or may combine certain components, or have a different arrangement of components.

In one embodiment of the present application, there is provided a terminal, an internal structure of which may be as shown in fig. 15, the terminal including a processor, a memory, a network interface, a display screen, and an input device connected through a system bus. Wherein the processor of the terminal is configured to provide computing and control capabilities. The memory of the terminal comprises a nonvolatile storage medium and an internal memory. The non-volatile storage medium stores an operating system and a computer program. The internal memory provides an environment for the operation of an operating system and computer programs in the non-volatile storage medium. The network interface of the terminal is used for connecting and communicating with an external terminal through a network. The computer program, when executed by a processor, performs the steps of a method of processing engineering survey data. The terminal can comprise a liquid crystal display screen or an electronic ink display screen, and the input device of the terminal can be a touch layer covered on the display screen, a key, a track ball or a touch pad arranged on a terminal shell, an external keyboard, a touch pad or a mouse and the like.

Those skilled in the art will appreciate that the architecture shown in fig. 15 is merely a block diagram of some of the structures associated with the disclosed aspects and is not intended to limit the computing devices to which the disclosed aspects apply, as particular computing devices may include more or less components than those shown, or may combine certain components, or have a different arrangement of components.

In one embodiment of the present application, there is provided a computer device comprising a memory and a processor, the memory storing a computer program, the processor implementing the following steps when executing the computer program:

when the target borehole is drilled, receiving the drilling position of the target borehole and a plurality of drilling depths of the target borehole, which are sent by a terminal of an inspector, wherein the target borehole is a hole drilled by the inspector in a target area to be inspected; determining adjacent boreholes of the target borehole according to the positions of the boreholes, and acquiring stratum information sets of the adjacent boreholes, wherein the stratum information sets of the adjacent boreholes comprise stratum information of different stratums of the adjacent boreholes; for each drilling depth, acquiring stratum information of a target stratum in the adjacent drilling holes from the stratum information of the adjacent drilling holes in a centralized manner according to the drilling depth, wherein the target stratum is a stratum corresponding to the drilling depth; and for each drilling depth, sending the stratum information of the target stratum in the adjacent borehole to the terminal, wherein the stratum information of the target stratum in the adjacent borehole is used for triggering the terminal to determine the stratum information of the target stratum of the target borehole according to the stratum information of the target stratum in the adjacent borehole.

In one embodiment, the processor, when executing the computer program, performs the steps of: for each drilling depth, receiving stratum information of a target stratum in a target drilling hole, which is sent by a terminal, and storing the stratum information of the target stratum in the target drilling hole into a stratum information set of the target drilling hole; the stratum information of the target stratum in the target borehole is obtained by the terminal according to the stratum information of the target stratum in the adjacent borehole and standard stratum information of the target area, and the standard stratum information comprises a stratum order and a stratum name.

In one embodiment, the processor, when executing the computer program, performs the steps of: acquiring rock-soil sampling test data of rock soil in a target drilling hole and test data of an in-situ test performed on the position of the target drilling hole; and storing the rock-soil sampling test data and the test data of the in-situ test into the stratum information set of the target borehole.

In one embodiment, the processor, when executing the computer program, performs the steps of: a three-dimensional geological model of the target borehole is generated from the set of formation information for the target borehole.

In one embodiment, the processor, when executing the computer program, performs the steps of: acquiring the position of a target area; acquiring standard stratum information of the target area according to the position of the target area; generating a survey outline according to the standard stratum information; and sending the survey outline to the terminal.

In one embodiment, the processor, when executing the computer program, performs the steps of: acquiring a topographic plan of a target area and a drilling plan layout of the target area, wherein the topographic plan comprises position coordinates of ground objects in the target area, and the drilling plan layout comprises position coordinates of drill holes to be drilled in the target area; and acquiring the position of the target area according to the position coordinates included in the topographic plan or the position coordinates included in the drilling plan.

In one embodiment, the processor, when executing the computer program, performs the steps of: acquiring regional standard stratum information of the target region, standard stratum information of an adjacent region to be surveyed and standard stratum information of a surveyed adjacent region according to the position of the target region; and selecting one of the area standard stratum information of the target area, the standard stratum information of the adjacent area to be surveyed and the standard stratum information of the adjacent area after the survey is completed as the standard stratum information of the target area.

In one embodiment, the processor, when executing the computer program, performs the steps of: acquiring subcontractor recommendation information of the target area according to the position of the target area; correspondingly, the survey outline is generated according to the standard stratum information, and the survey outline comprises the following steps: and generating a survey outline according to the standard stratum information and the subcontractor recommendation information.

In one embodiment, the processor, when executing the computer program, performs the steps of: acquiring basic information of a plurality of subcontractors, wherein the basic information of each subcontractor comprises a resident area position of each subcontractor, historical workload of each subcontractor and a survey operation grade of each subcontractor; screening out a plurality of first subcontractors which meet a first condition according to the position of the target area and the resident area position of each subcontractor, wherein the first condition is that the distance between the resident area position and the position of the target area is smaller than a distance threshold; screening a plurality of second subcontractors meeting a second condition from the plurality of first subcontractors according to the historical workload of each subcontractor, wherein the second condition is that the difference value between the historical workload and the workload of the survey target area is smaller than a difference threshold value; and screening a plurality of third subcontractors meeting a third condition from the plurality of second subcontractors according to the survey operation grade of each subcontractor, and generating subcontractor recommendation information according to the basic information of the third subcontractors, wherein the third condition comprises the condition that the survey operation grade is greater than a grade threshold value.

In one embodiment, the processor, when executing the computer program, performs the steps of: when the target drilling hole is drilled, receiving the drilling position of the target drilling hole and a plurality of drilling depths of the target drilling hole input by an inspector, wherein the target drilling hole is a hole drilled by the inspector in a target area to be inspected; and for each drilling depth, obtaining stratum information of a target stratum in an adjacent drilling hole of the target drilling hole according to the drilling position and the drilling depth, wherein the adjacent drilling hole is determined according to the drilling position, the target stratum is a stratum corresponding to the drilling depth, and for each drilling depth, the stratum information of the target stratum of the target drilling hole is determined according to the stratum information of the target stratum in the adjacent drilling hole.

In one embodiment, the processor, when executing the computer program, performs the steps of: sending the drilling position and the drilling depth to a server; and receiving stratum information of a target stratum in the adjacent borehole sent by the server, wherein the adjacent borehole is determined by the server according to the position of the borehole, the stratum information of the target stratum in the adjacent borehole is obtained by the server from the stratum information set of the adjacent borehole according to the drilling depth, and the stratum information set of the adjacent borehole comprises stratum information of different stratums of the adjacent borehole.

In one embodiment, the processor, when executing the computer program, performs the steps of: determining a near borehole from the investigated boreholes in the target area according to the position of the borehole, and acquiring a stratum information set of the near borehole, wherein the stratum information set of the near borehole comprises stratum information of different stratums of the near borehole; and acquiring stratum information of the target stratum in the adjacent borehole from the stratum information set of the adjacent borehole according to the drilling depth.

In one embodiment, the processor, when executing the computer program, performs the steps of: displaying standard stratum information and stratum information of a target stratum in an adjacent borehole, wherein the standard stratum information comprises stratum sequence and stratum name; receiving a selection instruction aiming at standard stratum information or stratum information of a target stratum in an adjacent borehole; determining the stratum information aimed at by the selection instruction as the stratum information of a target stratum in a target borehole; and sending the stratum information of the target stratum in the target borehole to a server.

The implementation principle and technical effect of the computer device provided by the above embodiment are similar to those of the above method embodiment, and are not described herein again.

In an embodiment of the application, a computer-readable storage medium is provided, on which a computer program is stored, which computer program, when being executed by a processor, carries out the steps of:

when the target borehole is drilled, receiving the drilling position of the target borehole and a plurality of drilling depths of the target borehole, which are sent by a terminal of an inspector, wherein the target borehole is a hole drilled by the inspector in a target area to be inspected; determining adjacent boreholes of the target borehole according to the positions of the boreholes, and acquiring stratum information sets of the adjacent boreholes, wherein the stratum information sets of the adjacent boreholes comprise stratum information of different stratums of the adjacent boreholes; for each drilling depth, acquiring stratum information of a target stratum in the adjacent drilling holes from the stratum information of the adjacent drilling holes in a centralized manner according to the drilling depth, wherein the target stratum is a stratum corresponding to the drilling depth; and for each drilling depth, sending the stratum information of the target stratum in the adjacent borehole to the terminal, wherein the stratum information of the target stratum in the adjacent borehole is used for triggering the terminal to determine the stratum information of the target stratum of the target borehole according to the stratum information of the target stratum in the adjacent borehole.

In one embodiment, the computer program when executed by the processor implements the steps of: for each drilling depth, receiving stratum information of a target stratum in a target drilling hole, which is sent by a terminal, and storing the stratum information of the target stratum in the target drilling hole into a stratum information set of the target drilling hole; the stratum information of the target stratum in the target borehole is obtained by the terminal according to the stratum information of the target stratum in the adjacent borehole and standard stratum information of the target area, and the standard stratum information comprises a stratum order and a stratum name.

In one embodiment, the computer program when executed by the processor implements the steps of: acquiring rock-soil sampling test data of rock soil in a target drilling hole and test data of an in-situ test performed on the position of the target drilling hole; and storing the rock-soil sampling test data and the test data of the in-situ test into the stratum information set of the target borehole.

In one embodiment, the computer program when executed by the processor implements the steps of: a three-dimensional geological model of the target borehole is generated from the set of formation information for the target borehole.

In one embodiment, the computer program when executed by the processor implements the steps of: acquiring the position of a target area; acquiring standard stratum information of the target area according to the position of the target area; generating a survey outline according to the standard stratum information; and sending the survey outline to the terminal.

In one embodiment, the computer program when executed by the processor implements the steps of: acquiring a topographic plan of a target area and a drilling plan layout of the target area, wherein the topographic plan comprises position coordinates of ground objects in the target area, and the drilling plan layout comprises position coordinates of drill holes to be drilled in the target area; and acquiring the position of the target area according to the position coordinates included in the topographic plan or the position coordinates included in the drilling plan.

In one embodiment, the computer program when executed by the processor implements the steps of: acquiring regional standard stratum information of the target region, standard stratum information of an adjacent region to be surveyed and standard stratum information of a surveyed adjacent region according to the position of the target region; and selecting one of the area standard stratum information of the target area, the standard stratum information of the adjacent area to be surveyed and the standard stratum information of the adjacent area after the survey is completed as the standard stratum information of the target area.

In one embodiment, the computer program when executed by the processor implements the steps of: acquiring subcontractor recommendation information of the target area according to the position of the target area; correspondingly, the survey outline is generated according to the standard stratum information, and the survey outline comprises the following steps: and generating a survey outline according to the standard stratum information and the subcontractor recommendation information.

In one embodiment, the computer program when executed by the processor implements the steps of: acquiring basic information of a plurality of subcontractors, wherein the basic information of each subcontractor comprises a resident area position of each subcontractor, historical workload of each subcontractor and a survey operation grade of each subcontractor; screening out a plurality of first subcontractors which meet a first condition according to the position of the target area and the resident area position of each subcontractor, wherein the first condition is that the distance between the resident area position and the position of the target area is smaller than a distance threshold; screening a plurality of second subcontractors meeting a second condition from the plurality of first subcontractors according to the historical workload of each subcontractor, wherein the second condition is that the difference value between the historical workload and the workload of the survey target area is smaller than a difference threshold value; and screening a plurality of third subcontractors meeting a third condition from the plurality of second subcontractors according to the survey operation grade of each subcontractor, and generating subcontractor recommendation information according to the basic information of the third subcontractors, wherein the third condition comprises the condition that the survey operation grade is greater than a grade threshold value.

In one embodiment, the computer program when executed by the processor implements the steps of: when the target drilling hole is drilled, receiving the drilling position of the target drilling hole and a plurality of drilling depths of the target drilling hole input by an inspector, wherein the target drilling hole is a hole drilled by the inspector in a target area to be inspected; and for each drilling depth, obtaining stratum information of a target stratum in an adjacent drilling hole of the target drilling hole according to the drilling position and the drilling depth, wherein the adjacent drilling hole is determined according to the drilling position, the target stratum is a stratum corresponding to the drilling depth, and for each drilling depth, the stratum information of the target stratum of the target drilling hole is determined according to the stratum information of the target stratum in the adjacent drilling hole.

In one embodiment, the computer program when executed by the processor implements the steps of: sending the drilling position and the drilling depth to a server; and receiving stratum information of a target stratum in the adjacent borehole sent by the server, wherein the adjacent borehole is determined by the server according to the position of the borehole, the stratum information of the target stratum in the adjacent borehole is obtained by the server from the stratum information set of the adjacent borehole according to the drilling depth, and the stratum information set of the adjacent borehole comprises stratum information of different stratums of the adjacent borehole.

In one embodiment, the computer program when executed by the processor implements the steps of: determining a near borehole from the investigated boreholes in the target area according to the position of the borehole, and acquiring a stratum information set of the near borehole, wherein the stratum information set of the near borehole comprises stratum information of different stratums of the near borehole; and acquiring stratum information of the target stratum in the adjacent borehole from the stratum information set of the adjacent borehole according to the drilling depth.

In one embodiment, the computer program when executed by the processor implements the steps of: displaying standard stratum information and stratum information of a target stratum in an adjacent borehole, wherein the standard stratum information comprises stratum sequence and stratum name; receiving a selection instruction aiming at standard stratum information or stratum information of a target stratum in an adjacent borehole; determining the stratum information aimed at by the selection instruction as the stratum information of a target stratum in a target borehole; and sending the stratum information of the target stratum in the target borehole to a server.

The implementation principle and technical effect of the computer-readable storage medium provided by the above embodiments are similar to those of the above method embodiments, and are not described herein again.

It will be understood by those skilled in the art that all or part of the processes of the methods of the embodiments described above can be implemented by hardware instructions of a computer program, which can be stored in a non-volatile computer-readable storage medium, and when executed, can include the processes of the embodiments of the methods described above. Any reference to memory, storage, database, or other medium used in the embodiments provided herein may include non-volatile and/or volatile memory, among others. Non-volatile memory can include read-only memory (ROM), Programmable ROM (PROM), Electrically Programmable ROM (EPROM), Electrically Erasable Programmable ROM (EEPROM), or flash memory. Volatile memory can include Random Access Memory (RAM) or external cache memory. By way of illustration and not limitation, RAM is available in a variety of forms such as Static RAM (SRAM), Dynamic RAM (DRAM), Synchronous DRAM (SDRAM), Double Data Rate SDRAM (DDRSDRAM), Enhanced SDRAM (ESDRAM), Synchronous Link DRAM (SLDRAM), Rambus Direct RAM (RDRAM), direct bus dynamic RAM (DRDRAM), and memory bus dynamic RAM (RDRAM).

The technical features of the above embodiments can be arbitrarily combined, and for the sake of brevity, all possible combinations of the technical features in the above embodiments are not described, but should be considered as the scope of the present specification as long as there is no contradiction between the combinations of the technical features.

The above-mentioned embodiments only express several embodiments of the present application, and the description thereof is more specific and detailed, but not construed as limiting the scope of the present application. It should be noted that, for a person skilled in the art, several variations and modifications can be made without departing from the concept of the present application, which falls within the scope of protection of the present application. Therefore, the protection scope of the present patent shall be subject to the appended claims.