KR101707676B1 - Orientation determining devices for borehole seiemic acceleration installed true north direction - Google Patents

Abstract

The present invention relates to an orientation determining device which corrects an azimuth of a borehole acceleration seismometer to match a direction of a Y-axis of the borehole acceleration seismometer underground with a true north direction indicated by a compass, comprising: a pipe-shaped casing made from steel, into which the borehole acceleration seismometer is inserted, which protects the borehole acceleration seismometer and guides the borehole acceleration seismometer to the underground to measure earthquake underground; and an azimuth control unit which penetrates the casing, which is connected to the borehole acceleration seismometer, installed in a top end unit of the casing which matches the direction of the Y-axis of the borehole acceleration seismometer with the true north direction of the compass. The present invention is able to precisely measure the azimuth of an earthquake underground by inserting the borehole acceleration seismometer into the casing and burying the casing underground; and matches the direction of the Y-axis of the borehole acceleration seismometer with the true north direction measured by the compass using the azimuth control unit.

Description

TECHNICAL FIELD [0001] The present invention relates to a closure device for installing a borehole acceleration seismometer in a true north direction.

The present invention relates to an apparatus for aligning a borehole acceleration seismograph in a true north direction, and more particularly, to a closure apparatus for installing a borehole acceleration seismograph in a true north direction in a borehole acceleration seismograph in a true north direction.

In general, an earthquake is defined as a sudden change in the earth's crust, causing the earthquake to propagate to the earth's surface. can do. The magnitude of an earthquake ranges from a very small earthquake, which is detected only by a sensitive seismometer, to a large earthquake, which causes extensive damage to a large area.

There are thousands of earthquakes that occur globally every day on earth, and most earthquakes are caused by large forces within the earth that affect the continent's movement, expansion of the sea bed, formation of mountains, and so on over a long period of time.

The magnitude of the earthquake damage has been increasing steadily. As an example of an earthquake damage, on March 11, 2011, an earthquake of magnitude 9.0 occurred in Fukushima, Japan, causing many casualties due to the tsunami. In Korea, there is no large-scale earthquake, but a magnitude 3.0 earthquake occurs twice a year.

An earthquake monitoring system for detecting such an earthquake is configured to store the sensed sensor value in a memory included in the seismic monitoring system, and the administrator can download the sensor value stored periodically using a portable memory (USB) Therefore, there is an urgent need for a method for monitoring the occurrence of an earthquake through a sensor value sensing a vibration occurring in an earthquake in real time.

On the other hand, many earthquakes have occurred recently around the Korean Peninsula, and the perception of earthquakes is changing. It is difficult to confirm when the earthquake occurs, but by analyzing the characteristics of the earthquake, it is possible to minimize the damage by predicting the range of seismic effects that can occur in Korea. For this purpose, it is important to establish a national earthquake observation network, and it is important to set up the sensors installed on the surface of the earth and the sensors installed on the ground surface correctly.

Earthquakes are natural disasters that cause unpredictable and large-scale damage. In order to understand and analyze earthquakes, which are natural disasters, it is necessary to acquire and analyze high-quality seismic observations and to utilize them in order to minimize the damage caused by earthquakes.

In order to obtain high-quality seismic observations, a seismometer should be installed in a very quiet area. However, it is not easy to establish a seismic station in a very quiet area because it is difficult to access the electricity or communication line.

The noise from the surface is usually high frequency noise, and this noise sharply decreases as it goes down to the ground. Therefore, it is possible to obtain high quality seismic observation data if a borehole type seismometer having the same performance as the surface type seismometer is installed in the borehole under the earthquake.

Borehole seismometers have the advantage of obtaining high quality seismic observations, but they can not be installed in the direction we want because they are installed underground that we can not see when installing the borehole seismometer. The seismograph for seismic observation is usually composed of three axes (X, Y, Z), and the ground type seismometer is installed by matching the horizontal components X and Y axis in the east-west and north-south directions.

This is to determine the direction of the seismic waves from the direction of the seismic wave after determining the backward azimuth of the seismic waves. In order to calculate the backward azimuth angle of the seismic waves, the Y-axis direction of the seismometer should be set to coincide with the true north direction.

However, since it is very difficult to install the borehole seismograph in line with the true north direction, the seismic observation data can be of high quality, but the backward azimuth angle can not be calculated.

To determine the backward azimuth using high-quality seismic observations, the Y-axis of the borehole seismometer should be aligned with the true north direction. If the Y-axis direction of the borehole seismograph is physically aligned with the direction of the true north, more precise backward azimuth can be calculated after acquiring high-quality seismic observations.

However, in reality, the Y-axis of the borehole seismometer can not be installed in the true north direction without any additional equipment, so an additional device is required for installation.

Korean Patent Registration No. 10-1514817 (Title: An earthquake recorder equipped with a microelectromechanical accelerometer)

The present invention has been made in order to solve the problems of the conventional art as described above, and it is an object of the present invention to provide an acceleration seismometer having a function of guiding a seismometer to the underground so as to measure an earthquake accurately according to an azimuth angle, And to provide the above-mentioned objects.

Another object of the present invention is to provide a clipping device for installing an acceleration seismometer in a true north direction, which has a function of measuring an azimuth angle of a seismograph and a true north direction on an earth surface and correcting the azimuth angle of the seismograph to match the true north direction.

In order to achieve the above-mentioned object, the present invention provides a borehole acceleration seismic system for installing a true borehole directional seawater, the borehole acceleration seismometer having an azimuth angle of the borehole acceleration seismometer, And a borehole accelerating seismometer connected to the cable, the borehole accelerating seismometer being protected by the borehole acceleration seismometer and measuring the earthquake in the borehole, ; And an azimuth angle adjusting unit installed at the upper end of the casing in a state of being connected to the borehole acceleration seismometer through the casing and correcting the Y axis direction of the borehole acceleration seismometer to the true north direction of the compass, .

The azimuth angle adjusting unit may include a rod connected to the borehole acceleration seismometer while eccentrically penetrating the casing from the center thereof and the other end exposed to the outside of the casing and controlled to move by an external force; A circular rotating plate formed at a portion thereof with a groove into which the rod is fitted corresponding to an end surface of the rod and rotating the rod while being rotated through an external force; And a direction indicating member made of a rectangular frame corresponding to an end surface of the rod and placed on the rotating plate while the rod penetrates to display an azimuth angle in the Y axis direction of the borehole acceleration seismograph on the rotating plate .

In addition, the rod may be a fork-shaped one end, coupled to the borehole acceleration seismometer and eccentrically rotating the borehole acceleration seismometer by an external force, A plurality of connecting rods penetrating the casing and detachably coupled to the other end of the direction adjusting rods to control movement of the direction adjusting rods by an external force; And a connecting member detachably connecting the connecting rods.

The connection member may include a pair of connection bars formed on the side surfaces of the connection rods and corresponding to the holes provided in the connection rods, An engaging bolt for engaging the connecting rods while passing through holes formed in the connecting rods and holes formed in the connecting rods; And a coupling nut fastened to the coupling bolt to fix the coupling rods.

The camera may further include a camera installed in a part of the azimuth angle adjusting unit to monitor the state of the borehole acceleration seismometer underground and to output the state to the outside.

The borehole acceleration seismometer according to the present invention is capable of accurately measuring the azimuth of an earthquake by inserting a borehole acceleration seismometer into the casing and buried the casing underneath.

Further, the azimuth direction of the borehole acceleration seismometer can be corrected to the true north direction on the surface of the indicator measured by the compass using the azimuth angle adjusting unit.

1 is a conceptual view of a clipping device for installation in a true north direction of a borehole acceleration seismometer according to an embodiment of the present invention;
2 is a detailed view of the azimuth angle adjusting unit;
3 is an exploded perspective view of the connecting member.
4 is a view showing a state where the azimuth angle adjusting unit is coupled to a borehole acceleration seismometer.
5 is a view showing a state in which the rotation plate and the direction indicating member are used.

The following detailed description of the invention refers to the accompanying drawings, which illustrate, by way of illustration, specific embodiments in which the invention may be practiced. These embodiments are described in sufficient detail to enable those skilled in the art to practice the invention. It should be understood that the various embodiments of the present invention are different, but need not be mutually exclusive. For example, certain features, structures, and characteristics described herein may be implemented in other embodiments without departing from the spirit and scope of the invention in connection with one embodiment. It should also be understood that the position or arrangement of individual components within each disclosed embodiment may be varied without departing from the spirit and scope of the present invention. The following detailed description is, therefore, not to be taken in a limiting sense, and the scope of the invention is to be limited only by the appended claims, along with the full scope of equivalents to which such claims are entitled. In the drawings, like reference numerals refer to the same or similar functions throughout the several views.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings, so that those skilled in the art can easily carry out the present invention.

2 is a detailed view of the azimuth angle adjusting unit, FIG. 3 is an exploded perspective view of the connecting member, FIG. 4 is an exploded perspective view of the connecting member, and FIG. FIG. 5 is a view showing a state where the rotation plate and the direction indicating member are used. FIG. 5 is a view showing a state where the azimuth angle adjusting unit is coupled to a borehole acceleration seismometer.

As shown in Figs. 1 to 5, in the closure device 10 for correcting the azimuth angle of the acceleration seismometer 30 so that the y-axis direction of the borehole acceleration seismometer 30 is coincident with the true north direction in the underground, May include a casing (100) and an azimuth angle adjusting unit (200).

Here, a seismograph is a mechanism made for the purpose of recording a seismic wave, and is composed of a sensor and a recording unit. The sensor is a device that detects the motion of the ground, and the recording unit is a device that stores the earthquake data.

The sensor has an accelerometer that adds time elements to the speedometer and the speedometer, depending on the application. We usually use speedometers for earthquake studies and use acceleration sensors for earthquake engineering.

The casing 100 is made of a steel material and includes a borehole acceleration sensor 30 and a borehole accelerating sensor 30 that protects the borehole acceleration seismometer 30, Structure.

The azimuth angle adjusting unit 200 may be installed at the upper end of the casing in a state of being connected to the borehole acceleration seismometer 30 so that the Y axis direction of the borehole acceleration seismometer 30 can be corrected to the true north direction of the compass.

The azimuth angle adjusting unit 200 may include a rod 210, a rotating plate 220, and a direction indicating member 230.

The rod 210 is connected to the acceleration seismometer 30 while eccentrically penetrating the casing 100 from the center, and the other end of the rod 210 is exposed to the outside of the casing 100, so that the movement of the rod 210 can be controlled by an external force.

In addition, the rod 210 may include a guide bar 212, a connecting rod 214, and a connecting member 216.

One end of the direction adjusting table 212 is formed in a fork shape and coupled to the borehole acceleration seismometer 30, and the acceleration seismometer 30 can be eccentrically rotated by an external force.

Specifically, the operator can control the rotational motion of the borehole acceleration seismometer 30 while the coupling protrusion formed at the distal end of the direction adjusting table 212 and the coupling hole provided at the upper portion of the borehole acceleration seismograph 30 are detachably coupled and fixed. Do.

The connecting rod 214 may be a plurality of structures that pass through the casing 100 and are detachably coupled to the other end of the direction adjuster 212 to control the movement of the direction adjuster 212 by an external force.

The connecting member 216 may detachably connect the connecting rods 214.

The connecting member 216 may again include a connecting bar 216-1, a coupling bolt 216-2 and a coupling nut 216-3.

The connection bar 216-1 may have a pair of holes formed in the connection rods 214 and connected to the connection rods 214 to connect the connection rods 214 with each other.

The coupling bolts 216-2 may join the connecting rods 214 while passing through the holes formed in the connecting bars 216-1 and the holes formed in the connecting rods 214-1.

The coupling nut 216-3 may be fastened to the coupling bolt 216-2 to fix the coupling rods 214. [

The closure device 10 of the present invention may further include a camera 300.

The camera 300 is installed in a part of the azimuth angle adjusting unit 200 and is connected to the outside by wireless or wire to monitor the state of the borehole acceleration seismometer 30 underground and output it to the outside.

A method of operating a closure device for installation in an accelerometer seismic system according to the present invention is characterized in that an operator fixes a direction adjusting table (212) on a borehole acceleration seismometer (30) 100) is buried underground, and the azimuth of the earthquake measured underground can be confirmed by guiding the borehole accelerometer 30 to the underground.

At this time, the operator can confirm the state of the borehole acceleration seismometer 30 in the basement while checking the camera 300 installed in the azimuth angle adjusting unit 200.

While the present invention has been described in connection with what is presently considered to be practical exemplary embodiments, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, And such variations and modifications are intended to fall within the scope of the appended claims.

10: closure device
30: Borehole Acceleration Seismometer
50: Cable
100: casing
200: azimuth angle control unit
210: Load
212: Direction adjuster
214: connecting rod
216:
216-1: Connection bar
216-2: Coupling Bolt
216-3: Coupling nut
220: Spindle
230: direction indicating member
300: camera

Claims (5)

1. A closure device for correcting an azimuth angle of a borehole acceleration seismometer in order to align a Y-axis direction of a borehole acceleration seismometer with a true north direction indicated by a compass,
A pipe type casing formed of a steel material and inserted into the borehole acceleration seismometer connected to the cable and guiding the borehole acceleration seismometer to the ground to measure an underground earthquake while protecting the borehole acceleration seismometer; And
And an azimuth angle adjusting unit installed at an upper end of the casing so as to penetrate the casing and connected to the borehole acceleration seismometer to correct the Y axis direction of the borehole acceleration seismometer to the true north direction of the compass,
Wherein the azimuth angle adjusting unit comprises:
A rod connected to the borehole acceleration seismometer while eccentrically penetrating the casing from the center and the other end exposed to the outside of the casing and controlled to move by an external force;
A circular rotating plate formed at a portion thereof with a groove into which the rod is fitted corresponding to an end surface of the rod and rotating the rod while being rotated through an external force; And
And a direction indicating member made of a square frame corresponding to an end surface of the rod and placed on an upper portion of the rotating plate through the rod to display an azimuth angle in the Y axis direction of the borehole acceleration seismograph on the rotating plate A closure device for the installation of a borehole acceleration seismometer in the true north direction.
delete The method according to claim 1,
The above-
A direction adjusting unit that is formed in a fork shape and coupled to the borehole acceleration seismometer and eccentrically rotates the borehole acceleration seismometer by an external force;
A plurality of connecting rods penetrating the casing and detachably coupled to the other end of the direction adjusting rods to control movement of the direction adjusting rods by an external force; And
And a connecting member for detachably connecting the connecting rods. The apparatus for mounting the borehole acceleration seismometer according to claim 1,
The method of claim 3,
The connecting member includes:
A pair of connecting bars formed on the side walls of the connecting rods to connect the connecting rods,
An engaging bolt for engaging the connecting rods while passing through holes formed in the connecting rods and holes formed in the connecting rods; And
And a coupling nut fastened to the coupling bolt to fix the coupling rods.
The method according to claim 1,
And a camera installed in a part of the azimuth angle adjusting unit for monitoring the state of the borehole acceleration seismometer in the ground and outputting it to the outside.

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