KR101424915B1 - Seismic data providing method and system for carbon capture and storage - Google Patents

Abstract

A method and a system for providing seismic exploration information for CCS are disclosed. The method for providing seismic exploration information comprises a step of uploading a file storing seismic exploration information to the seismic exploration information providing system; a step of generating a service file and an image file for providing the seismic exploration information by converting the uploaded file; a step of three-dimensionally modeling the seismic exploration information based on the generated service file; and a step of displaying the three-dimensionally modeled seismic exploration information on a three-dimensional map screen provided through a web browser.

Description

[0001] SEISMIC DATA PROVIDING METHOD AND SYSTEM FOR CARBON CAPTURE AND STORAGE [0002]

Embodiments of the present invention relate to a method and system for providing seismic exploration information for CCS for providing information explored as a seismic wave to a user for CCS (Carbon Capture and Storage).

Domestic and overseas energy markets face new conditions such as globalization, privatization, pursuit of sustainable development, rapid technological development and rising energy market in Northeast Asia.

Accordingly, the Ministry of Land, Transport and Maritime Affairs has developed a carbon capture and storage (CCS) technology to store carbon dioxide captured from large-scale sources such as power plants in marine sediments to cope with climate change and Kyoto Protocol emission reduction requirements. It is underway.

As one of the technologies relating to CCS, Korean Patent Laid-Open Publication No. 10-2012-0096692 (published on August 31, 2012) entitled " Carbon dioxide submarine underground storage system and method "includes a carbon dioxide submarine underground storage system, The hydrate formation promoter is supplied to the upper layer of the sediments and the carbon dioxide is supplied to the lower layer of the sediments through a tube extending vertically from the marine platform to the lower layer of the sedimentation layer to form a carbon dioxide hydrate cover layer in the sedimentation layer, Or the like.

In order to perform such a CCS, a site for storing carbon dioxide must be selected first. However, in order to select a site for storing carbon dioxide, it is necessary to systematically manage and efficiently visualize oceanic sediment basin survey data and analysis data therefor

Therefore, it is possible to systematically manage the contents of geological, physical logging, drilling data, exploration data and related reports, which are basic data of site selection for storage at the stage of capture, transportation and storage of CCS. There is a need for a way to be able to.

The contents of geological, physical logging, drilling data, exploration data and related reports, which are basic data of site selection for storage at the stage of collection, transportation and storage of CCS (Carbon Capture and Storage), can be systematically managed A method and system for providing seismic exploration information for a CCS is provided.

A method and system for providing seismic exploration information for CCS is provided that can effectively visualize the contents of geology, physical logging, drilling data, exploration data and related reports through a web browser.

A method of providing seismic exploration information includes receiving a file storing seismic exploration information by a seismic exploration information providing system, converting the uploaded file to generate a service file and an image file for providing seismic exploration information, Dimensional modeling of the seismic exploration information based on the generated service file, and displaying the three-dimensionally modeled seismic exploration information on a three-dimensional map screen provided through a web browser.

According to one aspect, the file storing the seismic exploration information may be a SEG-Y file in which the seismic exploration information is recorded in a trace sequential form.

According to another aspect, in the displaying step, when a file to be retrieved is selected from among the uploaded files in the three-dimensional map screen, the step of displaying the elastic wave exploration information by loading the modeled seismic exploration information on the three- Lt; / RTI >

According to another aspect, the method may further include building a database based on the generated service file and the image file after the generating step.

According to another aspect of the present invention, the image file may be divided into a plurality of image files when the area of the uploaded file is larger than a predetermined size.

According to another aspect, the method may further include providing the analysis information on the seismic exploration information in a three-dimensional manner on the three-dimensional map screen after the modeling step.

The SE information providing system includes a converting unit for converting the uploaded file to generate a service file and an image file for providing the seismic exploration information when a file storing the seismic exploration information is uploaded, A modeling unit for modeling the seismic exploration information in a three-dimensional manner, and a display unit for displaying the three-dimensionally modeled seismic exploration information on a three-dimensional map screen provided through a web browser.

By constructing a database using the service file and image file generated by converting the SEG-Y file storing the seismic exploration information, it is possible to construct a database of site selection for storage at the capture, transportation, and storage stages of CCS (Carbon Capture and Storage) The geology, physical logging, drilling data, exploration data and related reports can be systematically managed.

By displaying three-dimensionally modeled seismic information on a three-dimensional map displayed on a web browser, the contents of geology, physical logging, drilling data, exploration data and related reports can be effectively visualized.

1 is a flowchart illustrating a method for providing seismic exploration information for CCS in an embodiment of the present invention.
2 is an exemplary view showing a login screen of a seismic exploration information providing system according to an embodiment of the present invention.
FIG. 3 is an exemplary view showing a selection screen of a seismic exploration information providing system according to an embodiment of the present invention. FIG.
4 is an exemplary view showing an inquiry screen of the seismic exploration information providing system according to an embodiment of the present invention.
5 to 11 are illustrations for explaining functions provided by the seismic exploration information providing system according to an embodiment of the present invention.
12 is an exemplary diagram for explaining functions of a site menu in an embodiment of the present invention.
13 is an exemplary view showing a three-dimensional map screen in an embodiment of the present invention.
FIG. 14 is an exemplary view showing elastic wave exploration information displayed in three dimensions on a three-dimensional map screen according to an embodiment of the present invention. FIG.
15 is a block diagram illustrating a seismic exploration information providing system according to an embodiment of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a flowchart illustrating a method for providing seismic exploration information for CCS in an embodiment of the present invention.

The system for providing information on seismic exploration information according to the present invention systematically manages geological information, physics logging information, drilling information, exploration information, and related interpretation information, which are basic data of site selection for performing Carbon Capture and Storage (CCS) And a file storing the seismic exploration information is uploaded (110) in order to effectively visualize it. Here, the seismic exploration information means information that is explored through a seismic wave. The file storing the seismic exploration information may be, for example, a SEG-Y file in which the seismic exploration information is recorded in a trace sequential form.

The SEG-Y file is one of the file formats for storing geophysical data developed by the Society of Exploration Geophysicists (SEG), and consists of an EBCDIC header, a binary header, and a trace header. The EBCDIC header contains information on data acquisition, data processing parameters, etc. The binary header contains information on the sample interval, number of samples per acoustic-wave trace, and data format. The trace header includes the source / receiver position, offset, and shot number of the seismic exploration information.

Since the SEG-Y file is read only by dedicated software such as Kingdom, Geographix, and Petrel, it is managed separately from geological information, physical logging information, drilling information, and the like. Therefore, it has been difficult to integrate geological information, physical logging information, drilling information, and seismic exploration information in site selection for CCS.

Therefore, when the SEG-Y file is uploaded, the seismic wave exploration information providing system according to the present invention can convert the SEG-Y file to generate a service file and an image file for providing the seismic exploration information (120).

The trace header of the SEG-Y file stores most of the information needed for importing into dedicated software such as Kingdom, Geographix, and Petrel. Therefore, the seismic wave exploration information providing system according to the present invention can generate the service file based on the information extracted from the trace header of the SEG-Y file and generate the image file based on the image included in the SEG-Y file have. At this time, if the area of the SEG-Y file is larger than a preset size, the SE information providing system may divide the SEG-Y file into a plurality of image files (for example, a JPG file of 2048x2048 size). Thereafter, the seismic exploration information providing system can build a database based on the service file and the image file generated through the above process.

Meanwhile, the seismic exploration information providing system models the seismic exploration information in a three-dimensional manner based on the service file generated through the above-described process (130). Then, the three-dimensional modeled seismic exploration information can be displayed on a three-dimensional map screen provided through a web browser (140). For example, when a file to be searched among a plurality of SEG-Y files is selected by the user on the three-dimensional map screen, the seismic exploration information providing system loads the seismic exploration information modeled for the selected file on the three- can do.

On the other hand, the seismic exploration information providing system may provide the interpretation information of the seismic exploration information in three dimensions on the three-dimensional map screen.

FIG. 2 is an exemplary view showing a log-in screen of the seismic exploration information providing system according to an embodiment of the present invention, FIG. 3 is an exemplary view showing a selection screen of a seismic exploration information providing system, Fig. 7 is an exemplary diagram showing an inquiry screen of the system. Fig.

For example, FIG. 2 shows a login screen 210 provided when a user first accesses the seismic exploration information providing system according to the present invention. The seismic exploration information providing system may provide a login screen 210 as shown in FIG. 2 so that only a specific user can access it.

When the user logs in by inputting an ID and a password in the login area 220, the seismic exploration information providing system can provide a site selection screen as shown in FIG. For example, the seismic exploration information providing system uses a mashup function in conjunction with an electronic map to display on the electronic map a light hole location 310, a 2D SEG-Y line, a 3D zone, and a borehole location as shown in FIG. And can provide the information when the user selects the desired information. In FIG. 3, the layer button 320 provides a function of displaying a 2D SEG-Y file, a 3D SEG-Y file, and borehole information on an electronic map. At this time, each of the blocks may be modeled in three dimensions, and if selected by the user, an inquiry screen for the selected block as shown in FIG. 4 may be provided.

The inquiry screen for a block may be composed of a toolbar 410, a side menu 420 and a three-dimensional map screen 430 as shown in FIG.

The tool bar 410 may provide a function of measuring distance, area and volume, analyzing a survey section, and inquiring information of a borehole in the three-dimensional map screen 430. The side menu 420 may display a piece of information, or may provide a function of displaying layer information such as a stratum, a borehole, and the like, and a search information. The three-dimensional map screen 430 can display three-dimensionally the ground layer information, the borehole information, and the seismic exploration information.

5 to 12 are diagrams for explaining functions provided by the seismic exploration information providing system according to an embodiment of the present invention. Hereinafter, functions provided through the toolbar will be described in more detail with reference to FIGS. 5 to 12. FIG.

The toolbar's full screen, zoom in map, and zoom out buttons are used to zoom in and out of a three-dimensional map. You can use the full screen function to return the three-dimensional map to its initial state size and position. Here, the map enlarging and reducing function can be replaced by a mouse wheel.

The distance measurement button is used to measure the distance between points on a three-dimensional map. After selecting the tool, click the start point and double-click the end point to automatically measure the distance between the two points. At this time, if you click on the middle intermediate breakpoint, you can also measure the bent distance.

The area measurement button is used to measure the desired area on a three-dimensional map. Clicking each point after selecting a tool and double-clicking the end point automatically measures the area enclosed by the point.

The volume measurement button is a tool used to measure a desired volume in a three-dimensional map. When a tool is clicked and each point is clicked and the end point is double-clicked, as shown in FIG. 5, The volume of the height is automatically measured.

The section analysis button is a tool that shows a section cut based on two desired points on a three-dimensional map. When the tool is clicked on the start point and the end point is double-clicked, as shown in FIG. 6, (610) and a graph thereon are displayed. In FIG. 6, the reference cross section can be moved through the arrow button on the left side of the graph, and the graph can be enlarged to a desired size by dragging. If you click the whole view below the arrow button, the magnification of the cross-section graph can be initialized.

The information view button is a tool for displaying desired borehole information. When a user clicks a borehole 710 desired to be viewed on a three-dimensional map after clicking a tool as shown in FIG. 7, the information of the corresponding borehole And can be displayed in a pop-up form. The user can set the depth range to be viewed through the depth bar in the borehole information inquiry window displayed in a popup form. After setting the depth range and clicking the inquiry button, the user can set the depth of the borehole, Physical logging, core, cutting, and fossil data 820 can be retrieved.

The data management button is a tool that provides a function of storing files, and when clicked, a pop-up type data room as shown in FIG. 9 is opened and a file uploading and downloading can be performed through the data room. To this end, the archive includes editing functions for copying, cutting, pasting and creating folders, a folder tree function for showing the hierarchy of folders, a folder inquiry function for retrieving files and folders stored in the folder, A download function and an upload function for uploading a file. At this time, the SEG-Y file (* .sgy) can be directly inquired through the pop-up window 1010 directly as shown in FIG. 10 when the download is clicked. Or click the outer area to undo the image.

As a result of the analysis, the button is a tool that allows the analysis result of a block to be retrieved with a popup window. When the analysis result button is selected, a popup window as shown in FIG. 11 is used to display a CSS guide image, a block name, buried strata, Storage capacity, expected results, and so on.

12 is an exemplary diagram for explaining functions of a site menu in an embodiment of the present invention.

As shown in FIG. 12, the side menu may be composed of a block shortcut, layer information, and exploration information. A function of inquiring other minerals through the advertisement shortcut, a function of inquiring a report file, a function of inquiring a report image, and a function of inquiring a report table can be provided. Through the layer information, it is possible to edit such that only desired information is displayed in the exploration position, borehole and ground information displayed on the three-dimensional map screen. Through the exploration information, the SEG-Y file can be inserted in the three-dimensional map screen so that the seismic exploration information is displayed together with other information.

FIG. 13 is an exemplary view showing a three-dimensional map screen according to an embodiment of the present invention, and FIG. 14 is an exemplary view showing elastic wave exploration information displayed on a three-dimensional map on a three-dimensional map screen.

As shown in FIG. 13, a borehole, a stratum layer, ground information, and seismic exploration information can be integrated and displayed in a three-dimensional map on the three-dimensional map screen. The user can manipulate the 3D map by dragging the mouse wheel (zoom in / out), dragging the mouse (changing the camera field of view) and dragging the right mouse button and double clicking (moving the camera) Can also be operated. For example, FIG. 14 shows a case where only a ground layer and seismic exploration information 1410 are displayed on a three-dimensional map screen.

Thus, by constructing the database using the service file and the image file generated from the SEG-Y file storing the seismic exploration information, the seismic wave exploration information providing system according to the present invention can be used as a basic site for site selection for CCS, , Drilling data, exploration data and related reports can be integrated and systematically managed, and the seismic exploration information can be displayed in a three-dimensional manner through a web browser. Also, interpretation information on seismic exploration information can be provided in three dimensions .

15 is a block diagram illustrating a seismic exploration information providing system according to an embodiment of the present invention.

Referring to FIG. 15, the acoustic wave survey information providing system 1500 according to the present invention includes a converting unit 1510, a modeling unit 1520, and a display unit 1530.

When the file storing the seismic exploration information is uploaded through the web browser of the administrator, the conversion unit 1510 converts the uploaded file to generate a service file and an image file for providing the seismic exploration information. Here, the file storing the seismic exploration information may be, for example, a SEG-Y file in which the seismic exploration information is recorded in a trace sequential form. In this case, if the area of the SEG-Y file is larger than a predetermined size, the image file generated through the conversion unit 1510 can be divided and stored into a plurality of image files. The seismic exploration information providing system can construct a database based on the service file and the image file generated through the conversion unit 1510. [

The modeling unit 1520 models the borehole, the stratum layer and the ground information in a three-dimensional manner, and also models the seismic exploration information in a three-dimensional manner based on the service file and the service file generated through the conversion unit 1510.

The display unit 1530 displays the three-dimensionally modeled borehole, the layer layer and the ground information on the three-dimensional map screen, and the modeling unit 1520 displays the three-dimensional modeled seismic exploration information on a three-dimensional map screen Can be displayed. For example, when a specific SEG-Y file is selected on the three-dimensional map screen by the user, the display unit 1530 may load the service file for the file on the three-dimensional map screen so that the seismic exploration information is displayed in three dimensions. Meanwhile, the display unit 1530 may display the analysis information on the seismic exploration information in three dimensions in addition to the borehole, the layer layer, the ground information, and the seismic exploration information.

Wherein the service file for the selected file is loaded on the three-dimensional map screen when a file to be searched among the uploaded files is selected on the three-dimensional map screen.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. For example, it is to be understood that the techniques described may be performed in a different order than the described methods, and / or that components of the described systems, structures, devices, circuits, Lt; / RTI > or equivalents, even if it is replaced or replaced.

Therefore, other implementations, other embodiments, and equivalents to the claims are also within the scope of the following claims.

Claims (10)

A method of providing seismic exploration information,
A step of the seismic wave exploration information providing system uploading the file storing the seismic wave exploration information;
Converting the uploaded file to generate a service file and an image file for providing the seismic exploration information;
Constructing a database using the generated service file and image file so that at least one of geological information, physical log information, drilling information, and analysis information and the seismic exploration information are integrally provided;
Modeling the seismic exploration information in a three-dimensional manner based on the generated service file; And
And displaying the three-dimensionally modeled seismic exploration information on a three-dimensional map screen provided through a web browser,
Wherein the file storing the seismic exploration information includes:
Wherein the seismic exploration information is a SEG-Y file recorded in a trace sequential form,
Wherein the generating the service file and the image file comprises:
Extracting an image from the SEG-Y file to generate the image file, extracting a location, an offset, and a shot number of the seismic exploration information in a trace header of the SEG-Y file to generate the service file, Information delivery method. delete The method according to claim 1,
Wherein the displaying comprises:
And displaying the elastic wave exploration information modeled for the selected file by loading the elastic wave exploration information on the three dimensional map screen when the file to be inquired is selected from the uploaded files on the three dimensional map screen . delete The method according to claim 1,
The image file includes:
And if the area of the uploaded file is larger than a predetermined size, the image file is divided and stored into a plurality of image files. The method according to claim 1,
After the modeling step,
And providing analysis information on the seismic exploration information in a three-dimensional manner on the three-dimensional map screen. A converting unit for converting the uploaded file to generate a service file and an image file for providing the seismic exploration information when the file storing the seismic exploration information is uploaded;
A modeling unit for modeling the seismic wave exploration information in a three-dimensional manner based on the generated service file; And
And displaying the three-dimensionally modeled seismic exploration information on a three-dimensional map screen provided through a web browser
Lt; / RTI >
Wherein the file storing the seismic exploration information includes:
Wherein the seismic exploration information is a SEG-Y file recorded in a trace sequential form,
Wherein,
Extracts an image from the SEG-Y file to generate the image file, extracts the location, offset, and shot number of the seismic exploration information in the trace header of the SEG-Y file to generate the service file,
Wherein the database is constructed using the generated service file and the image file so that at least one of the geological information, physical log information, drilling information, and analysis information and the seismic exploration information are integrally provided. delete 8. The method of claim 7,
The display unit includes:
Wherein the service file for the selected file is loaded on the three-dimensional map screen when a file to be searched among the uploaded files is selected on the three-dimensional map screen. 8. The method of claim 7,
The image file includes:
And when the area of the uploaded file is larger than a predetermined size, the image is divided and stored into a plurality of image files.

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