KR101627558B1 - Frame for measuring p-wave velocity of marine sediment - Google Patents

Abstract

The present invention provides a frame for measuring the sound wave propagation velocity of marine sediments. The frame for measuring the sound wave propagation velocity of the marine sediment according to the present invention performs the measurement of the sound wave transmission rate through the insertion plate inserted into the sediment by the falling operation, As a result, the disturbance of the sample is suppressed as much as possible, and at the same time, the sound wave transmitting / receiving part formed on the insertion plate is closely adhered to the unconsolidated sediments to perform the sound wave transmission / reception.
A frame for measuring the sound wave propagation velocity of a marine sediment according to the present invention comprises: a base plate; A vertical guide installed vertically to the upper side of the base plate; A vertical moving body fixed to the vertical guide so as to be movable up and down; A horizontal guide coupled to the vertical moving body and integrally moving with the vertical moving body, the horizontal guide having a plurality of guide legs; A plurality of mounting tables which are horizontally movably fixed to the guide legs of the horizontal guiding table, wherein the distance measuring means for measuring the distance between the mounting tables facing each other are provided between A plurality of loading tables are inserted into the deposit placed on the base plate along with the descent of the vertical moving body and the horizontal guide table, and the sound wave delay time between the facing tables of the plurality of loading tables, The distance is measured by the sound wave transmitting / receiving unit and the distance measuring unit so that the sound wave propagation speed of the deposit can be calculated.

Description

FIELD OF THE INVENTION [0001] The present invention relates to a frame for measuring a sound velocity of a marine sediment,

The present invention relates to a frame for measuring the sound wave transmission rate of marine sediments, and more particularly to a frame for measuring the sound wave transmission rate through an insertion plate inserted into a sediment by a descending operation, In addition, since the sound wave transmitting / receiving unit formed on the insert plate is closely adhered to the unconsolidated sediments to perform the sound wave transmission / reception, the sound wave transmission of the marine sediments that can reduce the sound wave transmission rate error can be reduced And a frame for speed measurement.

Understanding the physical properties of marine sediments in geological resource research is very useful as a basic data. Typical equipment for sampling marine sediments to determine the physical properties of marine sediments are grab samplers and piston drills.

Grab samplers are used in various sizes and shapes depending on the application for surface sediment sampling. Usually, sediment depths up to 15 cm can be sampled, but samples may be disturbed. On the other hand, piston drills play an important role in drilling continuous sediments (depths) with little disturbance of the sediment and allowing them to elucidate the long-term deposition history.

The method of grasping the physical properties of marine sediments has great economic and temporal losses and spatial limitations. Therefore, studies on classification of marine sediments using acoustic equipments are actively under way.

Studies on the acoustic properties of marine sediments have been difficult due to technical problems due to measurement methods. However, as the development of measurement equipment has been actively promoted, research on acoustic has been attempted in earnest.

In order to measure sediment layer thickness using seismic data at sea, it is necessary to know the propagation speed of each layer. The schematic velocity structure can be calculated by seismic wave data analysis, but it often differs from the actual measurement value.

In order to calculate the acoustic impedance, which is directly related to the exact reflection surface position and the reflection coefficient, it is necessary to measure the sound wave propagation velocity for marine sediments.

The speed of sound wave propagation in marine sediments is considered to be important in itself, although it is also necessary to relate to the property action and interpretation of other physical properties.

However, it is not easy to directly measure the sound wave propagation speed of unconsolidated sediment, which is an unconsolidated sediment, and requires very high technical power.

It is difficult to measure the sound wave propagation rate in the nonconsolidated sediments even though the automatic sound wave transmission device manufactured by Geotek of England is sold for over 100 million won.

The Hamilton frame is used as the most accurate method to measure the sound wave propagation speed of the unconsolidated sediments. However, this equipment must measure the sound wave transmission rate after forming the sediment of the drill core first. There is a problem that measurement can not be performed, and there is a problem that accurate sound wave transmission rate can not be measured when a disturbance occurs in a sample while forming a sediment in a drilling core.

Korean Patent No. 10-1248829 discloses a sampling case for measuring the sound wave propagation speed of marine sediments and a sampling device comprising the sampling case.

The above-described prior art allows a plurality of samples to be obtained at a controlled position from a drilling core at a time using a sampling device, and to measure the speed of sound wave transmission through holes formed in the sampling case.

However, such a conventional technique also has a problem in that it is difficult to suppress the occurrence of disturbance of the sample during sample collection and transportation, and the measured sample can not be reused, and the sound transmission rate is measured by mounting the sound transmission / reception unit after sampling have.

Korean Patent No. 10-1248829 entitled "Sampling Case for Measurement of Sound Wave Velocity of Marine Sediments and Sampling Device Comprising the Sampling Case"

SUMMARY OF THE INVENTION Accordingly, the present invention has been made in view of the above problems, and it is an object of the present invention to provide a structure in which a sound wave transmission rate is measured while inserting a sound wave transmitting / receiving part into a sediment, And the sound wave transmission rate of the new type of marine sediments which can reduce the error rate of the sound wave transmission rate is achieved because the sound wave transmission / reception section formed on the insertion plate is closely adhered to the unconditioned sediment, It is an object of the present invention to provide a frame for measurement.

According to an aspect of the present invention, there is provided a plasma display panel comprising: a base plate; A vertical guide installed vertically above the base plate; A vertical moving body fixed to the vertical guide so as to be vertically movable; A horizontal guide coupled to the vertical moving body and integrally moving with the vertical moving body and having a plurality of guide legs; And a plurality of mounting tables fixed to the guide legs of the horizontal guide so as to be movable in the horizontal direction, wherein the distance measuring means for measuring the distance between the mounting tables facing each other, The plurality of loading tables are inserted into the deposit placed on the base plate in accordance with the descent of the vertical moving body and the horizontal guide, and the plurality of loading tables between the loading tables facing each other The sound wave delay time and the distance are measured by the sound wave transmitting and receiving unit and the distance measuring unit so that the sound wave propagation speed of the sediment can be calculated.

In the frame for measuring the sound wave propagation velocity of a marine sediment according to the present invention, the horizontal guide is formed at the lower end of the vertical moving body and has four guide legs extending at right angles to each other and extending in the horizontal direction, An upper movable table inserted horizontally into the guide leg of the horizontal guide so as to be horizontally movable; And an insertion plate formed in a flat plate shape and vertically formed on a lower portion of the upper movable table, inserted into the deposit, and the sound wave transmitting and receiving unit and the distance measuring unit are formed on the inner surface.

The frame for measuring the sound wave propagation velocity of the marine sediment according to the present invention may further include a spring disposed between the guide leg end of the horizontal guide and the upper movable bar to elastically support the upper movable bar have.

In the frame for measuring the sound wave propagation velocity of the marine sediment according to the present invention, the upper movable table of the mount table is formed with screw grooves in the vertical direction, screwed into the screw grooves of the upper movable table, And a fine adjustment screw for fixing the mounting table to the horizontal guide bar while the protruding lower end contacts the upper surface of the guide leg.

In the frame for measuring the sound wave transmission rate of a marine sediment according to the present invention, the guide legs are formed such that a pair of grooves are spaced apart along the longitudinal direction, and the fine adjustment screw is positioned between the pair of grooves .

In the frame for measuring the sound wave transmission rate of a marine sediment according to the present invention, the vertical guide is vertically disposed, and the vertical movable body is movably inserted therein. An intermediate support horizontally disposed at an intermediate portion of the guide rod; The vertical guide has a middle support and an upper support, both ends of which are rotatably fixed and vertically arranged. The vertical guide is supported by a lead A screw; Further comprising an operation handle formed on an upper end of the lead screw for rotationally driving the lead screw, the vertical moving body is moved in a vertical direction along the guide rod and the lead screw by rotational driving of the lead screw by the operation handle .

According to the frame for measuring the sound wave transmission rate of marine sediments according to the present invention, since the measurement of the sound wave transmission rate is performed through insertion of the sediment into the sediment according to the descending operation of the insertion plate formed with the sound wave transmitting / receiving part, And the sound wave transmission rate calculation error is reduced because the sound wave transmission and reception part formed on the insertion plate is closely adhered to the unconsolidated sediment to perform the sound wave transmission and reception.

1 is a perspective view of a frame for measuring a sound wave propagation velocity of marine sediments according to an embodiment of the present invention;
FIG. 2 is a perspective view of a horizontal guide bar and a mount bar which form a frame for measuring the sound wave propagation velocity of marine sediments according to an embodiment of the present invention; FIG.
3 is an exploded perspective view of a horizontal guide bar and a mount bar which form a frame for measuring the sound wave propagation velocity of marine sediments according to an embodiment of the present invention;
FIG. 4 is a plan view of a horizontal guide bar and a mount table forming a frame for measuring the sound wave propagation velocity of marine sediments according to an embodiment of the present invention; FIG.
5 is a cross-sectional view of a horizontal guide bar and a mount bar that form a frame for measuring the sound wave propagation velocity of marine sediments according to an embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings 1 to 5. In the drawings and the detailed description, the construction and operation of the workers in the field from common sediments, unconsolidated sediments, screws, sound waves transmission and reception, distance measurement and the like are simplified or omitted. In the drawings and specification, there are shown in the drawings and will not be described in detail, and only the technical features related to the present invention are shown or described only briefly. Respectively.

The frame for measuring the sound wave transmission rate of marine sediments according to the present invention is for measuring the sound wave transmission rate in various sediments and can be effectively applied to the measurement of the sound wave transmission rate of the non-consolidated sediments. 1, the frame for measuring the sound wave transmission rate of a marine sediment according to an embodiment of the present invention includes a base plate 110, a vertical guide 120, a lead screw 130, an operation handle 131, And includes a moving body 140, a horizontal guide 150, a mount 160, a spring 152, a fine adjustment screw 170, a sound transmission / reception unit 180, and a distance measuring unit 190.

A base plate 110 is provided below the measuring frame.

In the upper part of the base plate 110, a semicylindrical non-solidified sediment obtained by cutting the columnar sample obtained in the ocean in half can be placed.

A vertical guide 120 is vertically provided on one side of the base plate 110.

The vertical guide base 120 is provided with a pair of vertically arranged guide rods 121. An intermediate support base 122 is provided at the middle portion of the guide rods 121, An upper support 123 is provided.

A lead screw 130 is provided on the intermediate support 122 and the upper support 123.

The lead screw 130 is vertically disposed while being rotatably supported by the intermediate support 122 and the upper support 123. [

At the upper end of the lead screw 130, an operation handle 131 for rotating the lead screw 130 is provided.

In the vertical guide 120, the vertical moving body 140 is guided in the vertical direction.

That is, the vertical moving body 140 is vertically guided by the pair of guide rods 121 of the vertical guide 120 and moves in the vertical direction by the rotation of the lead screw 130.

Since the movement of the vertical moving body 140 in the vertical direction by the lead screw 130 is a general technique, a detailed description thereof will be omitted.

One side of the vertical moving body 140 is moved up and down by the lead screw 130 while the other side thereof is positioned above the center portion of the base plate 110.

A horizontal guide 150 is provided below the vertical moving body 140.

The horizontal guide 150 is fixed at a central portion thereof to the lower end of the vertical moving body 140 while four guide legs 151 are provided.

The four guide legs 151 are all plate-shaped and extend in the horizontal direction at right angles to each other.

On the other hand, each of the guide legs 151 has a pair of groove portions 151a formed along the longitudinal direction of the guide legs 151.

Therefore, the portion of the guide leg 151 positioned between the pair of the groove portions 151a is somewhat free to deform in the vertical direction as compared with other portions.

A mounting table 160 is provided for each of the guide legs 151 as described above.

In other words, the horizontal guide 150 is provided with four mounting tables 160.

The mount table 160 comprises an upper movable table 161 and an insert plate 162.

The upper movable base 161 is provided to be movable in the horizontal direction along the guide legs 151. For this purpose, the upper movable base 161 is provided with a leg opening 161a through which the guide leg 151 is inserted.

A screw groove 161b is formed in the upper movable base 161 in the vertical direction and the screw groove 161b is formed so that the leg opening 161a is communicated with the screw groove 161b.

An insertion plate 162 is provided below the upper movable base 161.

The insertion plate 162 is vertically provided as a portion to be inserted into the non-consolidated sediments.

In the present embodiment, the lower end of the insertion plate 162 has a blade shape for easy insertion.

On the other hand, the horizontal guide 150 is provided with a spring 152 for elastically supporting the upper movable table 161 of the table 160.

In addition, a spring support 153 is fixed to the horizontal guide 150 to support the other side of the spring 152.

A fine adjustment screw 170 is provided in the screw groove 161b of the upper movable table 161 of the mounting table 160. [

The fine adjustment screw 170 includes a screw body 171 and a screw head 172. The screw body 171 is screwed into the screw groove 161b so that the lower end of the screw body 171 is engaged with the upper surface of the guide leg 151 .

The screw head 172 is provided at an upper portion of the screw body 171 so as to be rotatable, whereby the contact pressure between the lower end of the screw body 171 and the guide leg 151 can be finely adjusted.

The fine adjustment screw 170 is fixed to the mounting table 160 so that the contact pressure with the guide leg 151 can be finely adjusted and consequently the mounting table 160 can be controlled by the spring 152 .

The fine adjustment screw 170 is positioned between the pair of grooves 151a of the guide leg 151 and the guide leg 151 is also easily deformed according to the insertion depth of the fine adjustment screw 170, Fine adjustment is possible.

The mounting plate 160 of the present embodiment, specifically, the insertion plate 162 is provided with the sound wave transmitting / receiving unit 180 and the distance measuring unit 190.

The sound wave transmitting / receiving unit 180 includes a sound wave transmitting unit and a sound wave receiving unit arranged to face each other, and the sound wave receiving unit receives sound waves generated from the sound wave transmitting unit. That is, one of the two insertion plates 162 facing each other is provided with a sound wave transmitting unit and the other is provided with a sound wave receiving unit.

A PZT ceramic piezoelectric body may be used as the acoustic transducer 180.

The distance measuring means 190 may be a laser distance measuring means or the like.

The sound wave propagation speed in the non-consolidated sediments is accurately measured by the sound wave delay time measured by the sound wave transmitting / receiving unit 180 and the distance measured by the distance measuring unit 190.

The sound wave transmitting / receiving unit 180 and the distance measuring unit 190 are connected to a control unit (not shown) to calculate a sound wave transmission speed, and the result is displayed.

Therefore, in the case of the four mounts 160 in this embodiment, the sound wave propagation velocity can be measured with respect to two mutually orthogonal axes.

The operation of the frame for measuring the sound wave propagation velocity of the marine sediments will be described.

First, a non-consolidated deposit of semicylindrical shape is placed on the upper portion of the base plate 110, that is, the lower portion of the insertion plate 162.

The manipulation handle 131 is rotated to move the vertical moving body 140 downward by the lead screw 130 so that the insertion plate 162 of the loading table 160 maintains a correct vertical posture, .

When the insertion plate 162 is inserted into the non-consolidated sediment, the contact between the sound transmission / reception unit 180 and the non-consolidated sediment may be poor during the insertion process. Therefore, after inserting the fine adjustment screw 170, 170 and the guide leg 151 is weakened, the insertion plate 162 is finely tilted by the elastic force of the spring 152, so that the sound wave transmitting / receiving unit 180 and the non-consolidated sediment are in intimate contact with each other.

The distance between the insertion plates 162 due to the movement of the insertion plate 162 is measured by the distance measuring means 190.

In this way, the sound wave propagation speed is calculated by measuring the sound wave delay time and the distance in a state where the sound transmission / reception unit 180 is completely in contact with the non-consolidated sediment.

After the measurement, the manipulation handle 131 is rotated to move the vertical moving body 140 upward by the lead screw 130, whereby the insertion plate 162 of the mounting table 160 is separated from the unconsolidated deposit.

As described above, since the frame for measurement does not require the sample molding or sample collection, disturbance of the sample is suppressed to the utmost, and the sound wave transmitting / receiving section is closely adhered to the unconsolidated sediments, so that the error of the sound wave transmission rate can be reduced.

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 variations and modifications may be made without departing from the scope of the present invention. And modifications may be made by those skilled in the art.

110: base plate 120: vertical guide
121: guide rod 122: intermediate support
123: upper support 130: lead screw
131: Operation handle 140: Vertical moving body
150: level guide 151: guide leg
151a: groove portion 152: spring
153: spring plate 160: mount table
161: upper movable base 161a: leg opening
161b: screw groove 162: insertion plate
170: fine adjustment screw 171: screw body
172: screw head 180: sound wave transmitting /
190: Distance measuring means

Claims (6)

A base plate forming a lower portion;
A vertical guide installed vertically above the base plate;
A vertical moving body fixed to the vertical guide so as to be vertically movable;
A horizontal guide coupled to the vertical moving body and integrally moving with the vertical moving body and having a plurality of guide legs;
And a plurality of mounts fixed to the guide legs of the horizontal guide so as to be horizontally movable,
A sound wave transmitting and receiving unit for performing sound wave transmission and reception and a distance measuring unit for measuring the distance between the facing stands facing each other are formed on the mounting table facing each other,
Wherein the plurality of mounts are inserted into the sediment placed on the base plate along with the descent of the vertical moving body and the horizontal guide, and the sound wave delay time and distance between the mounts facing each other, And a sound wave propagation velocity of the sediments can be calculated while being measured by the distance measuring means. The method according to claim 1,
The horizontal guide is provided at the lower end of the vertical moving body and has four guide legs extending at right angles to each other and extending in the horizontal direction,
An upper movable table which is inserted into the guide leg of the horizontal guide so as to be horizontally movable;
And an insertion plate formed in a flat plate shape and vertically formed in a lower portion of the upper movable table and inserted into the deposit, wherein the sound wave transmitting and receiving unit and the distance measuring unit are formed on the inner surface. Frame for measuring speed. 3. The method of claim 2,
Further comprising a spring disposed between the guide leg end of the horizontal guide and the upper movable table to elastically support the upper movable table. 3. The method of claim 2,
The upper movable table of the mount table is formed with screw grooves in the vertical direction,
And a fine adjustment screw screwed into the screw groove of the upper movable table and having a lower end protruding downward through the screw groove in contact with the upper surface of the guide leg to fix the table to the horizontal guide bar Wherein the at least one of the at least two of the at least two of the at least two of the plurality of the at least two of the plurality of the at least two of the plurality 5. The method of claim 4,
The guide legs are formed such that a pair of grooves are spaced from each other along the longitudinal direction,
And the fine adjustment screw is positioned between the pair of grooves. The method according to claim 1,
The vertical guide is vertically disposed, and includes a guide rod into which the vertically movable body is movably inserted; An intermediate support horizontally disposed at an intermediate portion of the guide rod; And an upper support disposed above the guide rod,
A lead screw having both ends rotatably fixed to an intermediate support and an upper support of the vertical guide and vertically disposed, the vertically movable body being movably inserted;
Further comprising an operation handle formed on an upper end of the lead screw for rotationally driving the lead screw,
And the vertically movable body is moved in the vertical direction along the guide rod and the lead screw by rotational driving of the lead screw by the operation handle.

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