CN112651476A - Auxiliary device and method for logging drilling core - Google Patents

Abstract

The present disclosure provides a drilling core logging auxiliary device and method, comprising: the auxiliary cataloguing instrument comprises a water content measuring sensor, a penetration sensor and an image acquisition unit which are connected with the auxiliary cataloguing instrument; the moisture content measuring sensor transmits moisture content data to the auxiliary recorder, the penetration sensor transmits penetration data to the auxiliary recorder, the image acquisition unit transmits acquired image data to the auxiliary recorder, and the auxiliary recorder generates a three-dimensional electronic tag according to the image, the penetration and the moisture content data; the accuracy of distinguishing the collected data is improved, so that the accuracy and the real-time performance of data recording are improved, and the digitization, the informatization and the intellectualization of the drilling and recording process are realized.

Description

Auxiliary device and method for logging drilling core

Technical Field

The disclosure belongs to the field of informatization and intellectualization of engineering investigation and drilling processes, and particularly relates to a drilling core cataloging auxiliary device and method.

Background

In modern water conservancy, highway and other construction, local geological conditions need to be surveyed before construction. Drilling still remains the most and intuitive means for engineering geological exploration. The drilling process now remains essentially in the manual phase.

The inventor finds that after a core sample is obtained by drilling, field personnel need to respectively detect various parameters of the core condition and make corresponding storage or written records, the whole process is complicated, a large amount of labor is consumed, careless mistakes are easy to occur, and the real-time performance is lacked; manual recording, the color, the density, the state and the like are all based on experience, and the subjectivity is strong; taking rock-soil samples on site, sealing and storing the samples on site, and disturbing by volatile water to influence the precision of indoor test data; the workload is large, the method is easily influenced by human factors such as experience, the accuracy and quality of acquisition cannot be completely guaranteed, and the real-time performance is poor.

Disclosure of Invention

In order to solve the technical problem, in the detection link of the core parameters, three basic microscope cameras, a penetration intelligent sensor and a moisture content intelligent sensor detection instrument are integrated, so that the integrated operation is realized, the manual operation intensity can be greatly reduced, a wireless data transmission technology is used for transmitting data into a field auxiliary recorder in real time, the data are stored and recorded, and then the data are transmitted to a cloud server through a GPRS network by the auxiliary recorder, so that the digitization, the informatization and the intellectualization of the drilling recording process are realized.

In a first aspect, the present disclosure provides a drilling core logging aid comprising: the auxiliary cataloguing instrument comprises a water content measuring sensor, a penetration sensor and an image acquisition unit which are connected with the auxiliary cataloguing instrument; the moisture content measuring sensor transmits acquired moisture content data to the auxiliary recording instrument, the penetration sensor transmits the acquired penetration data to the auxiliary recording instrument, the image acquisition unit transmits the acquired image data to the auxiliary recording instrument, and the auxiliary recording instrument generates the three-dimensional electronic tag according to the image, the penetration and the moisture content data.

In a second aspect, the present disclosure also provides a drilling core logging assistance system comprising: a geological exploration cloud platform and a drilling core logging aid as described in the first aspect; the drilling core logging auxiliary device is connected with the geological exploration cloud platform through wireless communication, and a geological logging table is manufactured according to data of the geological exploration cloud platform.

In a third aspect, the present disclosure provides a method of using the drilling core logging aid of the first aspect, comprising:

the microscope camera transmits image data to the auxiliary recorder, the penetration intelligent sensor transmits the penetration data to the auxiliary recorder, and the moisture content intelligent sensor transmits the moisture content data to the auxiliary recorder;

after receiving the image, the penetration degree and the water content data, the auxiliary recorder generates a three-dimensional electronic tag of the sample according to the GPS, the drilling number and the drilling depth;

and storing the three-dimensional electronic tag and the sample information into an auxiliary recorder and uploading the three-dimensional electronic tag and the sample information to a cloud server.

Compared with the prior art, this disclosure possesses following beneficial effect:

1. the auxiliary logging instrument of the drilling core logging auxiliary device generates three-dimensional electronic tags with plane positions and depths of collected data such as images, penetration degrees and water contents according to a GPS, a drill hole number and a drill hole depth, the three-dimensional electronic tags are transmitted to a cloud server through a GPRS network, collected data are collected and analyzed at the cloud server, and through continuous updating and continuous learning of big data, the problems that manual logging, color, density, states and the like are all based on experience and are strong in subjectivity are solved, the distinguishing precision of the collected data is improved, the accuracy and the real-time performance of data recording are improved, and digitization, informatization and intellectualization of a drilling logging process are realized.

2. The auxiliary recording instrument is provided with android terminal equipment, has a GPS positioning function, a GPRS network communication function and a Bluetooth function, and is connected with the intelligent recording cloud system background through a WeChat public number. The system can read a sample image acquired by the microscope camera through the micro USB and can automatically store the sample image as a picture; can receive the penetration data and the moisture content data of gathering through bluetooth and penetration intelligent sensor, moisture content intelligent sensor communication, solve the field personnel and need detect each item parameter of core situation respectively to do corresponding storage or written record, whole process is loaded down with trivial details, consumes a large amount of manual works, appears careless easily, and lacks the real-time problem.

3. According to the geological exploration smart cloud platform based on the Internet of things and cloud computing, the auxiliary logging instrument is used for connecting data such as images, penetration and water content of the three-dimensional electronic tags with positions and depths with the geological exploration smart cloud platform based on the Internet of things and cloud computing, corresponding drilling and depth position synchronous supplement are carried out on corresponding standard camera systems on site, accuracy of background logging is improved, and possibility is provided for deep learning automatic logging.

Drawings

The accompanying drawings, which are incorporated in and constitute a part of this application, illustrate embodiments of the application and, together with the description, serve to explain the application and are not intended to limit the application.

FIG. 1 is a general block diagram of an auxiliary cataloging system of the present disclosure;

fig. 2 is a schematic structural diagram of an auxiliary cataloging apparatus according to the present disclosure;

in the figure, 1, an image acquisition module; 2. a moisture content acquisition module; 3. a penetration acquisition module; 4. a geological exploration smart cloud platform; 5. color; 6. sand or particle density; 7. water content; 8. a plastic state; 9. a field standard camera system; 10. a geological record table; 101. a microscope observation window; 102. a water content measuring key; 103. a density measurement key; 104. a displacement sensor; 105. a water content measuring probe; 106. a liquid crystal display screen; 107. a snapshot key; 108. and (5) switching a key.

The specific implementation mode is as follows:

the present disclosure is further described with reference to the following drawings and examples.

It should be noted that the following detailed description is exemplary and is intended to provide further explanation of the disclosure. Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this application belongs.

It is noted that the terminology used herein is for the purpose of describing particular embodiments only and is not intended to be limiting of example embodiments according to the present application. As used herein, the singular forms "a", "an" and "the" are intended to include the plural forms as well, and it should be understood that when the terms "comprises" and/or "comprising" are used in this specification, they specify the presence of stated features, steps, operations, devices, components, and/or combinations thereof, unless the context clearly indicates otherwise.

Example 1

As shown in fig. 2, a drilling core logging aid comprises: the auxiliary cataloging instrument comprises a water content measuring sensor, a penetration sensor, an image acquisition unit, a storage unit and a communication unit which are connected with the auxiliary cataloging instrument; the moisture content measuring sensor transmits the moisture content data to the auxiliary recording instrument, the penetration sensor transmits the penetration data to the auxiliary recording instrument, the image acquisition unit transmits the acquired image data to the auxiliary recording instrument, and the auxiliary recording instrument generates the three-dimensional electronic tag according to the image, the penetration and the moisture content data.

The auxiliary cataloging instrument is a terminal device provided with an android and has a GPS positioning function, a GPRS network communication function and a Bluetooth function. The auxiliary logging instrument can adopt a YHB3.7 mine geological logging instrument. The auxiliary recorder generates a three-dimensional electronic tag with a plane position and depth of data such as collected images, penetration degree and water content according to a GPS (position), a drilling number, a drilling depth and the like.

The penetration sensor adopts a hardness tester to measure, reads data of the hardness tester through equipment, and transmits the data to the auxiliary recorder through Bluetooth. The penetration sensor is connected with the hardness tester and used for collecting data measured by the hardness tester.

The auxiliary recording instrument transmits data to the cloud server through the communication unit, only stores the data to the auxiliary recording instrument if the auxiliary recording instrument is abnormally connected with the cloud server, and transmits the data to the cloud server when the communication is normal.

The image acquisition unit comprises a microscope camera, acquires image data through a self-light source and a fixed-focus serial microscope camera, transmits the data to the auxiliary recorder through a micro USB and transmits the data to the cloud server through a GPRS.

The communication unit comprises but not limited to Bluetooth, wifi and mobile data, and is transmitted to the cloud server through the GPRS network by the auxiliary logging instrument. Collected data are collected and analyzed at the cloud server side, and the judgment precision of the collected data is improved through continuous updating and continuous learning of big data, so that the accuracy and the real-time performance of data recording are improved, and the digitization, the informatization and the intellectualization of the drilling and recording process are realized.

The humidity sensor is used for acquiring humidity and transmitting data to the auxiliary recording instrument. The auxiliary on-site logging instrument collects humidity, transmits data to the auxiliary logging instrument through Bluetooth and transmits the data to the cloud server through a communication unit of the auxiliary logging instrument.

The auxiliary recording instrument is a terminal device provided with an android system, has a GPS positioning function, a GPRS network communication function and a Bluetooth function, and is connected with the intelligent recording cloud system background through a WeChat public number. The system can read a sample image acquired by the microscope camera through the micro USB and can automatically store the sample image as a picture; can receive the penetration data and the moisture content data of gathering through bluetooth and penetration intelligent sensor, moisture content intelligent sensor communication. The system can automatically generate a drilling number and manually input depth information into collected pictures, penetration degree, water content and the like according to the acquired GPS information to generate the three-dimensional electronic tag.

The density sensor is connected with the auxiliary cataloging instrument and can adopt a GMP1500 type density sensor. The displacement sensor is connected with the auxiliary recorder, and can be an absolute value displacement sensor, a linear displacement sensor or a magnetostrictive displacement sensor.

The water content measuring sensor can adopt an HA2001 soil water content sensor or a TM-100 soil water content sensor.

Example 2

A method of using a drilling core logging aid, comprising:

logging in an auxiliary catalog instrument app and entering a project management system;

opening a microscope camera, an intelligent penetration sensor and an intelligent moisture content sensor, wherein the intelligent penetration sensor and the intelligent moisture content sensor are connected with an auxiliary editing and recording instrument through Bluetooth, and the microscope camera is connected with the auxiliary editing and recording instrument through a USB;

the microscope camera, the penetration intelligent sensor and the moisture content intelligent sensor upload data to the auxiliary recorder, and the auxiliary recorder generates a three-dimensional electronic tag of the sample according to the GPS, the drilling number and the drilling depth after receiving the data;

the microscope camera transmits image data to the auxiliary recorder, the penetration intelligent sensor transmits the penetration data to the auxiliary recorder, and the moisture content intelligent sensor transmits the moisture content data to the auxiliary recorder;

after receiving the image, the penetration degree and the water content data, the auxiliary recorder generates a three-dimensional electronic tag of the sample according to the GPS, the drilling number and the drilling depth;

and storing the three-dimensional electronic tag and the sample information into an auxiliary recorder and uploading the three-dimensional electronic tag and the sample information to a cloud server.

Specifically, the penetration intelligent sensor measures by adopting a hardness tester, reads data of the hardness tester through equipment, transmits the data to the auxiliary recording instrument through Bluetooth, transmits the data to the cloud server through GPRS, only stores the data to the auxiliary recording instrument if the auxiliary recording instrument is abnormally connected with the cloud server, and transmits the data to the cloud server when waiting for normal communication.

The image acquisition module acquires image data through a self-light source and a fixed-focus serial microscope camera, transmits the data to the auxiliary recorder through a micro USB and transmits the data to the cloud server through a GPRS. The auxiliary on-site logging instrument collects humidity and transmits data to the auxiliary logging instrument through Bluetooth and the auxiliary logging instrument transmits the data to the cloud server through GPRS.

The auxiliary recording instrument is a terminal device provided with an android system, has a GPS positioning function, a GPRS network communication function and a Bluetooth function, and is connected with the intelligent recording cloud system background through a WeChat public number. The system can read a sample image acquired by the microscope camera through the micro USB and can automatically store the sample image as a picture; can receive the penetration data and the moisture content data of gathering through bluetooth and penetration intelligent sensor, moisture content intelligent sensor communication. The three-dimensional electronic tag can be generated according to the acquired GPS information, the automatic generation of the drilling number and the manual input of the depth information, such as the acquired picture, the penetration degree and the water content.

Example 3

As shown in fig. 1, a drilling core logging assistance system includes: a geological exploration cloud platform and a drilling core logging aid as described in the above embodiments.

The drilling core logging auxiliary device is connected with the geological exploration cloud platform through wireless communication, and a geological logging table is manufactured according to data of the geological exploration cloud platform. The geological exploration cloud platform is further connected with the on-site standard camera system. The method for manufacturing the geological record table according to the data of the geological exploration cloud platform comprises the following steps: and drawing a geological record table according to the color, density (sand, grains), moisture content and plastic state of the geological exploration cloud platform.

The drilling core cataloging auxiliary device reads a sample image collected by a microscope camera and can automatically store the sample image as a picture; the Bluetooth communication with the penetration intelligent sensor and the moisture content intelligent sensor can be realized, and the collected penetration data and the moisture content data can be received; the drilling core cataloguing auxiliary device is used for connecting data such as images, penetration degree and water content of the three-dimensional electronic tags with positions and depths with a geological exploration smart cloud platform based on the Internet of things and cloud computing, and corresponding drilling and depth position synchronous supplement is carried out on a corresponding standard camera system on site.

Although the present disclosure has been described with reference to specific embodiments, it should be understood that the scope of the present disclosure is not limited thereto, and those skilled in the art will appreciate that various modifications and changes can be made without departing from the spirit and scope of the present disclosure.

Claims (10)

1. A drilling core logging aid, comprising: the auxiliary cataloguing instrument comprises a water content measuring sensor, a penetration sensor and an image acquisition unit which are connected with the auxiliary cataloguing instrument; the moisture content measuring sensor transmits acquired moisture content data to the auxiliary recording instrument, the penetration sensor transmits the acquired penetration data to the auxiliary recording instrument, the image acquisition unit transmits the acquired image data to the auxiliary recording instrument, and the auxiliary recording instrument generates the three-dimensional electronic tag according to the image, the penetration and the moisture content data.

2. The drilling core logging aid of claim 1, wherein the aid logging instrument comprises a positioning unit and a communication unit; the positioning unit is used for positioning by a GPS, and the communication unit comprises GPRS network communication and Bluetooth.

3. The drilling core logging aid of claim 2, wherein the aid logger transmits data to a cloud server via a communication unit.

4. The drilling core logging aid of claim 1, wherein the penetration sensor is coupled to a hardness tester to collect data measured by the hardness tester.

5. The drilling core logging aid of claim 1, wherein the image acquisition unit comprises a microscope camera through which image data is acquired and transmitted to the aid logger.

6. The drilling core logging aid of claim 1, further comprising a humidity sensor connected to the auxiliary logger, the humidity sensor for collecting humidity and transmitting data to the auxiliary logger.

7. The drilling core logging aid of claim 1, further comprising a density sensor connected to the auxiliary logging instrument for collecting the density of sand or particles.

8. A drilling core logging assistance system, comprising: a geological exploration cloud platform and a drilling core logging aid as claimed in any one of claims 1 to 7; the drilling core logging auxiliary device is connected with the geological exploration cloud platform through wireless communication, and a geological logging table is manufactured according to data of the geological exploration cloud platform.

9. The drilling core logging assistance system of claim 8, wherein the geological logging table generated from the data of the geological exploration cloud platform is specifically: and drawing a geological record table according to the color, the sand or particle density, the water content and the plastic state of the geological exploration cloud platform.

10. Use of a drilling core logging aid according to any one of claims 1-7, comprising:

the microscope camera transmits image data to the auxiliary recorder, the penetration intelligent sensor transmits the penetration data to the auxiliary recorder, and the moisture content intelligent sensor transmits the moisture content data to the auxiliary recorder;

after receiving the image, the penetration degree and the water content data, the auxiliary recorder generates a three-dimensional electronic tag of the sample according to the GPS, the drilling number and the drilling depth;

and storing the three-dimensional electronic tag and the sample information into an auxiliary recorder and uploading the three-dimensional electronic tag and the sample information to a cloud server.

Images