KR101322243B1 - Method for buried of geomagnetic field sensor using plastic cylinder - Google Patents

Abstract

PURPOSE: A method for laying a geomagnetic field sensor using a plastic cylinder is provided to economically install a geomagnetic field sensor without the variation of temperature and humidity. CONSTITUTION: A horizontal floor is formed by digging the ground and constructing at underground floor with white cement (S110). A marble is installed at the center of the horizontal floor and the geomagnetic field sensor is arranged at the upper surface of the marble for installing the sensor (S120). A plastic cylinder pipe is fixed to the horizontal floor in the form of accommodating the marble, which is being fixed with the geomagnetic field sensor being arranged, at the center (S130). The plastic cylinder pipe is finishing processed by inserting a cylinder lid at an upper part and prevents from being twisted by laying soil at the outside of the plastic cylinder pipe (S140). [Reference numerals] (S110) Step where a horizontal floor is formed; (S120) Step where a marble is installed at the center of the horizontal floor; (S130) Step where a plastic cylinder pipe is fixed to the horizontal floor; (S140) Step where the plastic cylinder pipe is finishing processed by inserting a cylinder lid at an upper part and is kept from being twisted by laying soil at the outside of it

Description

METHOD FOR BURIED OF GEOMAGNETIC FIELD SENSOR USING PLASTIC CYLINDER}

The present invention relates to a method of embedding a global magnetic field sensor using a plastic cylinder, and more specifically, to install and install at a low cost without changing temperature and humidity by using a conventional large plastic cylinder commercially available for sewage pipes. It relates to a method of embedding the earth magnetic field sensor using a plastic cylinder.

In general, earth magnetic field sensors used in geomagnetic observation stations include fluxgates that measure the three-axis direction of the earth's magnetic field and proton sensors that measure the absolute value of the earth's magnetic field. These Earth's magnetic field sensors are severely affected by magnetic components and are sensitive to changes in temperature and humidity. Accordingly, foreign countries such as the United States have constructed separate buildings and installed earth magnetic field sensors to use them for geomagnetic observation. For example, the United States constructs a 10-meter-long building that does not contain magnetic components such as iron, and connects air conditioning facilities for constant temperature and humidity. In other words, there is a problem in that a large amount of cost is required to construct a separate air conditioning facility without using magnetic components such as reinforcing bars and nails throughout the building.

On the other hand, in Korea, it is generally installed on the ground or in the form of some 1m deep puddles. These domestic earth magnetic field sensors are vulnerable to changes in the environment in Korea, where the temperature and humidity change significantly during the day, night, and the four seasons.

1 is a diagram illustrating an example of installation of a general flux gate and a proton. (A) and (b) of FIG. 1 show an example of underground installation of a flux gate, and FIG. 1 (c) shows an example of installation of a proton outdoors. In particular, as shown in (c) of FIG. 1, the proton sensor installed in Korea is vulnerable to temperature change at night and day and temperature and humidity change at four seasons because it is installed at the outdoor ground. According to the 2011 weather report, it shows a minimum of -11.6 degrees humidity 50% in January and 83% humidity in August. In addition, the flux gate sensor installed in Korea is buried shallowly in consideration of the construction cost without considering the depth of freezing (1m underground in Seoul). That is, as shown in (a) and (b) of Figure 1, considering the 0.8m distance between the freezing depth 1m and the bottom surface should be installed at least 2m deep underground facilities, but not buried enough It is becoming. In particular, when magnetic components are observed at underground sensor installation points, they need to be buried deeper, but they are also installed at shallow points due to construction costs. Therefore, the earth magnetic field sensor installed in Korea is vulnerable to environmental changes in Korea, where the temperature and humidity change significantly during the day, night and the four seasons.

The present invention has been proposed to solve the above problems of the conventionally proposed methods, by constructing a facility for embedding the earth magnetic field sensor using a conventional large plastic cylinder commercially available for sewage pipe, changes in temperature and humidity It is an object of the present invention to provide a method of embedding the earth magnetic field sensor by using a plastic cylinder, which enables the installation and construction of the earth magnetic field sensor at low cost without using.

In addition, the present invention, even in the construction of low-cost facilities do not impair the reliability of measuring the magnetic field of the earth, in particular to be applied to effectively use in response to changes in the environment of Korea, the day and night and the four seasons change temperature and humidity Another object is to provide a method of embedding earth magnetic field sensors using plastic cylinders.

Method for embedding the earth magnetic field sensor using a plastic cylinder according to a feature of the present invention for achieving the above object,

A method of embedding a global magnetic field sensor using a plastic cylinder,

(1) digging the ground to form a horizontal bottom surface by the construction of back cement on the ground level evenly;

(2) installing a marble at a center position of the horizontal bottom surface, and placing and fixing an earth magnetic field sensor at a top sensor installation position of the marble;

(3) fixedly installing a plastic cylindrical pipe on the horizontal bottom surface in such a manner as to accommodate the marble fixed by arranging the earth magnetic field sensor; And

(4) inserting and closing the cylindrical cap on the upper portion of the plastic cylindrical pipe, and finishing the embedding, and embedding the soil to the outside of the plastic cylindrical pipe to complete the embedding to prevent the left and right warp. do.

Preferably, the plastic cylindrical pipe,

Considering a depth of freezing of 1m and a distance of 0.8m from the horizontal bottom surface, it can be composed of a plastic pipe having a cylindrical length of 3m in consideration of the underground magnetic exploration.

Preferably, the cylindrical lid is,

Styrofoam can be used as a roof filler to block external temperature and humidity, but the thickness can be 150mm.

Method for embedding the earth magnetic field sensor using a plastic cylinder according to another feature of the present invention for achieving the above object,

A method of embedding a global magnetic field sensor using a plastic cylinder,

(1) digging the ground to form a horizontal bottom surface by the construction of back cement on the ground level evenly;

(2) installing a marble at a center position of the horizontal bottom surface, and placing and fixing an earth magnetic field sensor at a top sensor installation position of the marble;

(3) fixing and installing two first and second plastic cylindrical pipes of different diameters on the horizontal bottom surface in such a manner as to accommodate the marble fixed by arranging the earth magnetic field sensor;

(4) filling a heat insulating material, which is an internal filler for blocking external temperature and humidity, into a space between the first and second plastic cylindrical pipes;

(5) forming a facility case by construction of a non-magnetic back cement outside of the first and second plastic cylindrical pipes filled with the heat insulating material as the inner filler; And

(6) Insert and fasten a cylindrical cap made of styrofoam to the upper part of the first and second plastic cylindrical pipes to block external temperature and humidity, and close the cover plate to the top, and to the outside of the facility case. It is characterized by the configuration that comprises the step of embedding the soil to complete the embedding.

Preferably, the first and second plastic cylindrical pipe,

Considering a depth of freezing of 1m and a distance of 0.8m from the horizontal bottom surface, and having a length of about 3m considering the underground magnetic exploration,

The diameter of the first plastic cylindrical pipe disposed therein is 1200 mm, the diameter of the second plastic cylindrical pipe disposed at the outer diameter of the first plastic cylindrical pipe is 1500 mm, and the first and second plastic cylindrical The insulation filled between the pipes can form a width of 140 mm.

Preferably, in step (6),

The cylindrical lid is used as a roof filling material to be inserted into the upper part of the cylinder, and the thickness is 150 mm,

The cover plate may be used as a roof covering the facility case, and may be configured to be waterproof to the entire cover plate.

Preferably, in step (6),

The soil is filled to the outside of the facility case to complete the embedding, but the upper part of the facility case is removed from the ground to prevent water from splashing or overflowing the water into the first and second plastic cylindrical pipes. It can be configured to be spaced apart by mm or more.

According to the method of embedding the earth magnetic field sensor by using the plastic cylinder proposed in the present invention, by changing the temperature and humidity by constructing a facility for embedding the earth magnetic field sensor using a conventional large plastic cylinder commercially available for sewage pipes It is possible to install and build the earth magnetic field sensor at low cost without the cost.

In addition, according to the present invention, even the construction of low-cost facilities does not impair the reliability of measuring the magnetic field of the earth, and in particular, it can be used to effectively respond to the environmental changes in Korea, the day and night and the four seasons change temperature and humidity can do.

1 shows an example of installation of a general flux gate and proton.
2 is a flow diagram illustrating a method of embedding an earth magnetic field sensor using a plastic cylinder according to an embodiment of the present invention.
3 is a view showing the configuration of the embedding process according to the method of embedding the earth magnetic field sensor using a plastic cylinder according to an embodiment of the present invention.
4 is a cross-sectional view showing the completion of embedding according to the method of embedding the earth magnetic field sensor using a plastic cylinder according to an embodiment of the present invention.
5 is a view showing a flow of a method of embedding the earth magnetic field sensor using a plastic cylinder according to another embodiment of the present invention.
6 is a view showing the configuration of the embedding process according to the method of embedding the earth magnetic field sensor using a plastic cylinder according to another embodiment of the present invention.
7 is a cross-sectional view showing completion of embedding in a method of embedding a global magnetic field sensor using a plastic cylinder according to another embodiment of the present invention.
8 is a graph showing a measurement of the temperature change of the earth magnetic field sensor embedded at a depth of 1m underground.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings, in order that those skilled in the art can easily carry out the present invention. In the following detailed description of the preferred embodiments of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear. In the drawings, like reference numerals are used throughout the drawings.

In addition, in the entire specification, when a part is referred to as being 'connected' to another part, it may be referred to as 'indirectly connected' not only with 'directly connected' . In addition, the term 'comprising' of an element means that the element may further include other elements, not to exclude other elements unless specifically stated otherwise.

2 is a view showing the flow of a method of embedding the earth magnetic field sensor using a plastic cylinder according to an embodiment of the present invention, Figure 3 is a earth magnetic field sensor using a plastic cylinder according to an embodiment of the present invention 4 is a view showing the configuration of the embedding process according to the method of embedding, Figure 4 is a view showing a cross section of the completion of the embedding according to the method of embedding the earth magnetic field sensor using a plastic cylinder according to an embodiment of the present invention. . As shown in Figure 2, the method of embedding the earth magnetic field sensor using a plastic cylinder according to an embodiment of the present invention, forming a horizontal bottom surface 110 (S110), the horizontal bottom surface 110 Installing marble 120 at the central position of the step (S120), fixing the plastic cylindrical pipe 130 to the horizontal bottom surface 110 (S130), and the cylindrical cap on the top of the plastic cylindrical pipe 130 Inserting and closing the 140 and finishing, and may be implemented to include the step (S140) to complete the embedding to prevent the left and right distortion by embedding the soil.

In step S110, a horizontal bottom surface 110 is formed by the construction of a back cement on the ground floor which is dug and leveled. Here, the horizontal bottom surface 110 is a base structure that becomes the base of the facility for embedding the earth magnetic field sensor 10.

In step S120, the marble 120 is installed at the center position of the horizontal bottom surface 110, and the earth magnetic field sensor 10 is disposed and fixed to the upper surface 121 sensor installation position of the marble 120. Here, the installation and fastening method of the marble 120 installed on the horizontal bottom surface 110 and the earth magnetic field sensor 10 fixedly installed by being disposed on the upper surface 121 of the marble 120 is widely known. As can be understood that the method is applied, unnecessary detailed description of the fixed installation method will be omitted in the present invention. However, in the present invention, it is sufficient that the marble 120 is installed on the horizontal bottom surface 110, and the earth magnetic field sensor 10 is disposed and fixedly installed at the sensor installation position of the top surface 121 of the marble 120.

In step S130, the plastic cylindrical pipe 130 is fixedly installed on the horizontal bottom surface 110 in a form of accommodating the marble 120 fixed by arranging the earth magnetic field sensor 10 at the center. Here, the plastic cylindrical pipe 130 may be composed of a plastic material pipe having a cylindrical length of 3m considering the freezing depth of 1m, 0.8m away from the horizontal bottom surface 110, considering the underground magnetic exploration. That is, the plastic cylindrical pipe 130 is a pipe in the form of plastic that can be easily obtained on the market and has a thick thickness and durability.

In step S140, the cylindrical cap 140 is inserted and fastened to the upper portion of the plastic cylindrical pipe 130, and the land is completed by embedding soil to the outside of the plastic cylindrical pipe 130 to prevent the left and right distortion. Here, the cylindrical cap 140 is composed of styrofoam in order to block the external temperature and humidity of the upper cylinder and used as a roof filler, the styrofoam thickness of the cylindrical cap 140 may be configured to 150mm.

Figure 3 (a) shows the configuration of an exploded perspective view of the embedding process according to the method of embedding the earth magnetic field sensor using the plastic cylinder according to the present invention, Figure 3 (b) uses a plastic cylinder according to the present invention Shows the assembly installation configuration of the buried process according to the method of embedding the earth magnetic field sensor. Figure 4 shows a cross-section of the configuration of the facility is completed underground buried in accordance with the method of embedding the earth magnetic field sensor using a plastic cylinder according to an embodiment of the present invention.

5 is a view showing the flow of a method of embedding the earth magnetic field sensor using a plastic cylinder according to another embodiment of the present invention, Figure 6 is a globe using a plastic cylinder according to another embodiment of the present invention 7 is a view showing the configuration of a buried process according to a method of embedding a magnetic field sensor, and FIG. 7 is a cross-sectional view showing completion of embedding according to a method of embedding an earth magnetic field sensor using a plastic cylinder according to another embodiment of the present invention. One drawing. As shown in Figure 5, the method of embedding the earth magnetic field sensor using a plastic cylinder according to another embodiment of the present invention, forming a horizontal bottom surface 210 (S210), horizontal bottom surface 210 Step of installing the marble 220 in the center position (S220), the step of fixing two first and second plastic cylindrical pipes (231, 232) having different diameters to the horizontal bottom surface (210) (S230) Filling the heat insulating material 233 into the space between the first and second plastic cylindrical pipes 231 and 232 (S240), the facility case 240 to the outside of the first and second plastic cylindrical pipes 231 and 232 Forming a step (S250), and inserting and closing the cylindrical lid 250 made of styrofoam on top of the first and second plastic cylindrical pipes (231, 232), and covers the cover plate 260 to the top. And, including the step (S260) to complete the buried soil to the outside of the facility case 240 It can be.

In step S210, a horizontal bottom surface 210 is formed by the construction of a back cement on the ground ground evenly dug out. Here, the horizontal bottom surface 210 is a base structure serving as the base of the facility for embedding the earth magnetic field sensor 10.

In step S220, the marble 220 is installed at the center position of the horizontal bottom surface 210, and the earth magnetic field sensor 10 is fixedly installed at the top surface 221 sensor installation position of the marble 220. Here, the installation and fastening method of the marble 220 installed on the horizontal bottom surface 210 and the earth magnetic field sensor 10 fixedly installed by being disposed on the upper surface 221 of the marble 220 is one embodiment described above. As it can be understood that a variety of conventional and well-known methods are the same, unnecessary details will be omitted. However, in the present invention, it is sufficient that the marble 220 is installed on the horizontal bottom surface 210 and the earth magnetic field sensor 10 is disposed and fixed at the sensor installation position of the upper surface 221 of the marble 220.

In step S230, the horizontal bottom surface 210 of the two first and second plastic cylindrical pipes (231, 232) having different diameters in the form of receiving the geomagnetic field sensor 10, the marble 220 is fixed in the center. Install in a fixed position. Here, the first and second plastic cylindrical pipes (231, 232) can be configured to have a length of about 3m considering the freezing depth of 1m, 0.8m away from the horizontal bottom surface 210, considering the underground magnetic exploration. have. More specifically, the diameter of the first plastic cylindrical pipe 231 disposed inside is 1200 mm, and the diameter of the second plastic cylindrical pipe 232 disposed at the outer diameter of the first plastic cylindrical pipe 231 is 1500 mm. It can be configured as. Accordingly, a space width of 140 mm between the first and second plastic cylindrical pipes 231 and 232 may be formed to fill the heat insulating material 233 to be described later. Since the first and second plastic cylindrical pipes 231 and 232 use large plastic cylinders currently available for sewage pipes, the earth magnetic field sensor 10 can be buried at low cost.

In step S240, the insulating material 233, which is an internal filler for blocking external temperature and humidity, is filled into the space between the first and second plastic cylindrical pipes 231 and 232. Here, the heat insulator 233 serves as a heat insulation treatment function to block the temperature change of the outside of the cylinder, and to block the humidity due to the internal / external temperature difference. That is, the heat insulating material 233 is a first plastic cylindrical pipe 231 having a diameter of 1200 mm disposed therein, and a second plastic cylinder having a diameter of 1500 mm and disposed at an outer diameter of the first plastic cylindrical pipe 231. The space width 140mm between the pipes 232 is filled.

In step S250, the facility case 240 is formed by the construction of a non-magnetic back cement to the outside of the first and second plastic cylindrical pipes 231 and 232 filled with the heat insulating material 233 as the inner filler. The facility case 240 is constructed as shown in Figure 7, thereby preventing the distortion of the cylinder due to the movement of the ground. At this time, the thickness of the outer cylinder, that is, the thickness of the second plastic cylindrical pipe 232 in consideration of the distortion or strength of the cylinder is preferably used to be 9mm or more.

In step S260, the cylindrical lid 250 made of styrofoam is inserted into and closed on top of the first and second plastic cylindrical pipes 231 and 232 to block external temperature and humidity, and the cover plate 260 is upward. Covering the), the landfill to the outside of the facility case 240 to complete the embedding. Here, the cylindrical lid 250 is used as a roof filler to be inserted into the upper cylinder, but the thickness of 150mm, the cover plate 260 is used as a roof covering the facility case 240, the cover plate 260 as a whole Use waterproofed material. In addition, the landfill is completed by filling the outside of the facility case 240, in order to prevent the inflow of water flowing into the first and second plastic cylindrical pipes (231, 232) by splashing rain or overflowing the ground. As shown in FIG. 7, the upper portion of the facility case 240 is preferably buried so as to be spaced apart from the ground by 50 mm or more.

Figure 6 (a) shows the configuration of an exploded perspective view of the embedding process according to the method of embedding the earth magnetic field sensor using a plastic cylinder according to another embodiment of the present invention, Figure 6 (b) is a The assembled installation configuration of the embedding process according to the method of embedding the earth magnetic field sensor using a plastic cylinder according to another embodiment. Figure 7 shows a cross-sectional configuration of the facility configuration is completed underground buried in accordance with the method of embedding the earth magnetic field sensor using a plastic cylinder according to another embodiment of the present invention. FIG. 8 is a graph illustrating a measurement of a temperature change of an earth magnetic field sensor embedded at a depth of 1 m underground. FIG. 8A is a result of measuring the temperature change of the earth magnetic field sensor 10 buried at a depth of 1 meter underground in the Gangneung region, and is a measurement temperature in January, and FIG. 8B is a measurement temperature in August. . That is, when the earth magnetic field sensor 10 is buried underground, it can be confirmed that there is almost no temperature change.

The present invention may be embodied in many other specific forms without departing from the spirit or essential characteristics of the invention.

110: horizontal bottom surface 120: marble
121: upper surface 130: plastic cylindrical pipe
140: cylindrical lid 210: horizontal bottom surface
220: marble 221: top surface
231: first plastic cylindrical pipe 232: second plastic cylindrical pipe
233: insulation 240: facility case
250: cylindrical lid 260: cover plate
S110: forming a horizontal bottom surface
S120: installing the marble in the center position of the horizontal floor surface
S130: step of fixing the plastic cylindrical pipe to the horizontal bottom surface
S140: Finishing by inserting and closing the cylindrical cap on the upper part of the plastic cylindrical pipe, and filling the soil to complete the embedding to prevent left and right distortion
S210: forming a horizontal bottom surface
S220: installing the marble in the center position of the horizontal floor surface
S230: fixedly installing two first and second plastic cylindrical pipes of different diameters on a horizontal bottom surface
S240: filling the insulation with a space between the first and second plastic cylindrical pipes
S250: forming a facility case out of the first and second plastic cylindrical pipes
S260: inserting and closing the cylindrical lid made of styrofoam on top of the first and second plastic cylindrical pipes, and closing the cover plate to the top, and filling the outside of the facility case to complete the embedding step

Claims (7)

A method of embedding a global magnetic field sensor using a plastic cylinder,
(1) digging the ground and forming a horizontal bottom surface 110 by construction of back cement on the ground level evenly;
(2) installing the marble 120 at the center of the horizontal bottom surface 110, and placing and fixing the earth magnetic field sensor 10 at the sensor installation position of the top surface 121 of the marble 120; ;
(3) fixing the plastic cylindrical pipe 130 to the horizontal bottom surface 110 in such a manner as to receive the marble 120 fixed by arranging the earth magnetic field sensor 10 at the center thereof; And
(4) inserting and closing the cylindrical cap 140 on the upper portion of the plastic cylindrical pipe 130, and finishing the process, and filling the soil to the outside of the plastic cylindrical pipe 130 to complete the embedding to prevent left and right distortion Method for embedding the earth magnetic field sensor using a plastic cylinder, comprising a.
The method of claim 1, wherein the plastic cylindrical pipe 130,
Earth using plastic cylinders, characterized in that consisting of a plastic pipe having a freezing depth of 1m and a distance of 0.8m from the horizontal bottom surface 110, and having a cylindrical length of 3m in consideration of underground magnetic exploration How to embed a magnetic field sensor.
The method of claim 1, wherein the cylindrical cap 140,
A method of embedding a geomagnetic field sensor using a plastic cylinder, characterized in that the styrofoam is used as a roof filler to block external temperature and humidity, but the thickness is 150 mm.
A method of embedding a global magnetic field sensor using a plastic cylinder,
(1) digging the ground and forming a horizontal bottom surface 210 by construction of back cement on the ground level evenly;
(2) installing the marble 220 at the center position of the horizontal bottom surface 210, and placing and fixing the earth magnetic field sensor 10 at the top surface 221 sensor installation position of the marble 220; ;
(3) The horizontal bottom surface 210 includes two first and second plastic cylindrical pipes 231 and 232 having different diameters in a shape of receiving the marble 220 fixed by arranging the earth magnetic field sensor 10 at the center thereof. Fixed installation);
(4) filling the insulating material 233, which is an internal filler for blocking external temperature and humidity, into a space between the first and second plastic cylindrical pipes 231 and 232;
(5) forming a facility case 240 by constructing a non-magnetic back cement to the outside of the first and second plastic cylindrical pipes 231 and 232 filled with the heat insulating material 233 as the inner filler; And
(6) Insert and fasten the cylindrical cap 250 made of styrofoam to the outside of the first and second plastic cylindrical pipes 231 and 232 to block external temperature and humidity, and cover the cover plate 260 to the top. Covering), and burying the soil to the outside of the facility case (240) to complete the embedding.
The method of claim 4, wherein the first and second plastic cylindrical pipes (231, 232),
Considering the depth of freezing 1m and the distance 0.8m from the horizontal bottom surface 210, and configured to have a length of about 3m considering the underground magnetic exploration,
The diameter of the first plastic cylindrical pipe 231 disposed inside is composed of 1200mm, the diameter of the second plastic cylindrical pipe 232 disposed at the outer diameter of the first plastic cylindrical pipe 231 is composed of 1500mm And a heat insulating material (233) filled between the first and second plastic cylindrical pipes (231, 232) forms a width of 140 mm, the method of embedding the earth magnetic field sensor using a plastic cylinder.
The method according to claim 4, wherein in step (6),
The cylindrical cap 250 is used as a roof filling material to be inserted into the upper portion of the cylinder, and the thickness is 150 mm,
The cover plate (260) is used as a roof covering the facility case 240, characterized in that the cover plate 260 is waterproof, the method of embedding the earth magnetic field sensor using a plastic cylinder.
The method according to claim 4, wherein in step (6),
Complete the embedding by embedding the soil to the outside of the facility case 240, to prevent the inflow of water flowing into the first and second plastic cylindrical pipes (231, 232) by splashing rain or overflowing water on the ground. Method of embedding the earth magnetic field sensor using a plastic cylinder, characterized in that the upper portion of the facility case 240 is spaced 50mm or more from the ground.

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