KR102171956B1 - Mounting frame of geoacoustic apparatus for measurement of sound speed and attenuation in sea floor sediment - Google Patents

Abstract

A frame for installing geoacoustic measuring equipment is disclosed. The frame for installing the geoacoustic measurement equipment includes a main frame forming an exterior; An equipment mounting unit installed in the inner space of the main frame and provided to mount and fix the geoacoustic measurement equipment; A rotating part installed on one side of the main frame and rotating about an axis; And a rotation preventing unit that restricts rotation of the pivoting unit by applying an external force from a lower side of the pivoting unit to an upward direction, wherein when the rotation of the pivoting unit is restricted by the rotation preventing unit, the pivoting unit At one point, it is maintained in a state connected to one side of the equipment mounting part, but when the external force by the rotation preventing part disappears, the rotating part rotates by its own weight, and the equipment mounting part may be dropped in a downward direction by separating the equipment mounting part.

Description

Mounting frame of geoacoustic apparatus for measurement of sound speed and attenuation in sea floor sediment}

The present invention relates to a frame for installation of geoacoustic measuring equipment for measuring the sound velocity and sound attenuation of a sedimentary layer on the sea floor.

In general, analyzing marine sediments to understand physical properties is one of the most important parts in marine research, and Korean Patent Publication No. 10-1435617 discloses a field sound wave transmission velocity measurement system technology for subsea geological surveys.

Meanwhile, in the geoacoustic measurement equipment used in the INSEA (INvestigation of SEdiments by Acoustics) system, a plurality of stakes each including a transducer for signal transmission and a transducer for reception are provided at the bottom of the equipment. The acoustic properties of the sedimentary layer (eg, sound velocity, sound attenuation) can be measured after being embedded in the sedimentary layer on the sea floor.

However, conventionally, in order to fix the stakes of the geoacoustic measuring equipment in the sedimentary layer on the sea floor, the diver had to dive into the water and apply an external force to the measuring equipment, so installation was inconvenient. There was a disadvantage that the installation was limited. Therefore, there is a need for the development of a new technology capable of easily measuring the acoustic characteristics (sound speed, sound attenuation) of the sedimentary layer on the sea floor even if a person does not directly install the measuring equipment.

An object of the present invention is to solve the above-described problems, and an object of the present invention is to provide a technology capable of measuring acoustic characteristics (sound speed, sound attenuation) of a sedimentary layer at the bottom of the sea without a person directly installing a geoacoustic measurement equipment. .

In addition, another object of the present invention is to provide a technique for easily installing geoacoustic measurement equipment on the sea floor sedimentary layer and convenient recovery of the installed equipment.

The problem to be solved by the present invention is not limited to the above-described problem, and other technical problems that are not mentioned will be clearly understood by those of ordinary skill in the technical field to which the present invention belongs from the following description.

In order to achieve this object, as an embodiment of the present invention, a frame for installing a geoacoustic measuring equipment includes a main frame forming an exterior; An equipment mounting unit installed in the inner space of the main frame and provided to mount and fix the geoacoustic measurement equipment; A rotating part installed on one side of the main frame and rotating about an axis; And a rotation preventing unit that restricts rotation of the pivoting unit by applying an external force from a lower side of the pivoting unit to an upward direction, wherein when the rotation of the pivoting unit is restricted by the rotation preventing unit, the pivoting unit At one point, it is maintained in a state connected to one side of the equipment mounting part, but when the external force by the rotation preventing part disappears, the rotating part rotates by its own weight, and the equipment mounting part may be dropped in a downward direction by separating the equipment mounting part.

In addition, the rotation unit includes a first rotation member installed on the upper end of the main frame so as to be rotatable at a predetermined angle; And a clasp that is connected to the first rotating member and is capable of fixing one side of the equipment mounting portion.

In addition, the rotation preventing unit connection member having a predetermined length; And a locking member that is coupled to surround the connection member at a point of the connection member and restricts movement of the first rotation member when in close contact with the first rotation member.

In addition, the frame for installation of the acoustic measurement equipment further includes an auxiliary fastening unit for temporarily fixing the connecting member to the main frame until the equipment mounting unit is dropped, and when the equipment mounting unit falls, the equipment is mounted. By cutting the auxiliary fastening part due to the weight of the part, the connecting member may be separated from the main frame.

Further, the frame for installation of the acoustic measurement equipment further includes a cover part for covering at least a part of the main frame to prevent the cable connected to the connection member from being entangled while flowing into the inner space of the main frame, and the cover part has A communication hole through which the connecting member passes may be formed.

In order to achieve this object, as another embodiment of the present invention, the rotating part of the frame for installing the acoustic measuring equipment includes a first rotating member installed on the upper end of the main frame so as to be rotatable at a predetermined angle; And a second rotating member formed at one end of the first rotating member, wherein a clasp for fixing one side of the equipment mounting part is provided at one end of the second rotating member, and the first rotating member includes the When the external force by the rotation preventing unit is removed, it may have a greater weight than the second rotation member to rotate in a direction closer to the equipment mounting unit.

The means for solving the above-described problems are merely exemplary and should not be construed as limiting the present invention. In addition to the above-described exemplary embodiments, there may be additional embodiments described in the drawings and detailed description of the invention.

As described above, according to an embodiment of the present invention, when the external force caused by the rotation preventing unit disappears, the rotating unit rotates by its own weight and separates the equipment holder, so that the equipment holder falls in a downward direction and the acoustic measurement equipment Gets stuck in the ground. Therefore, it is convenient to install the geoacoustic measurement equipment, and when the connecting member is lifted upwards by a crane, the main frame rises together when recovering the geoacoustic measurement equipment installed on the ground. It works.

In addition, according to an embodiment, since the geoacoustic measurement equipment can be easily installed even in a deep-sea sedimentary layer, which is difficult for a diver to access, it is possible to measure the acoustic impedance of the deep-sea sedimentary layer.

Effects according to various embodiments of the present invention are not limited to the above-mentioned effects, and other effects that are not mentioned will be clearly understood by those skilled in the art from the description of the claims.

1 is a perspective view schematically showing a frame for installing a geoacoustic measurement equipment according to an embodiment of the present invention.
FIG. 2 is a partially enlarged view showing an enlarged part of the frame for installing the geoacoustic measurement equipment of FIG. 1.
3 is a perspective view schematically showing a frame for installation of a geoacoustic measurement equipment according to another embodiment of the present invention.
4 is an operational state diagram schematically showing a process in which a frame for installation of a geoacoustic measurement equipment according to an embodiment of the present invention is installed on the sea floor by a crane.
5 is an operational state diagram schematically showing a process in which a frame for installation of a geoacoustic measurement device according to an embodiment of the present invention is pulled upward and recovered.

Preferred embodiments of the present invention will be described in more detail with reference to the accompanying drawings, but technical parts that are already well-known will be omitted or compressed for conciseness of description.

It should be noted that references to "one" or "one" embodiment of the present invention in this specification are not necessarily to the same embodiment, and they mean at least one.

In the following embodiments, terms such as first and second are not used in a limiting meaning, but are used for the purpose of distinguishing one component from another component.

In the following examples, a singular expression includes a plural expression unless the context clearly indicates otherwise.

In the following embodiments, terms such as include or have means that the features or elements described in the specification are present, and do not preclude the possibility of adding one or more other features or elements.

In the following embodiments, when a certain part is said to be "connected" with another part, it is not only "directly connected", but also "indirectly connected" with another member interposed therebetween. Include.

In the drawings, components may be exaggerated or reduced in size for convenience of description. For example, the size and thickness of each component shown in the drawings are arbitrarily shown for convenience of description, and the present invention is not necessarily limited to what is shown.

1 is a perspective view schematically showing a frame for installing a geoacoustic measurement equipment according to an embodiment of the present invention, and FIG. 2 is a partially enlarged view showing an enlarged part of the frame for installing a geoacoustic measurement device of FIG. 1. Referring to FIGS. 1 and 2, a frame 10 for installing a geoacoustic measuring device may include a main frame 100, an equipment mounting part 200, a rotating part 300, and a rotation preventing part 400.

The main frame 100 forms the overall appearance, and the main frame 100 according to an embodiment includes side frames 110 and 120, upper frames 130 and 140, lower frames 150, and mounting frames 160, 170) may be included. Here, the lower frame 150 is a base frame positioned under the main frame 100, and the lower frame 150 supports side frames 110 and 120 coupled to the lower frame 150. The side frames 110 and 120 are coupled to the upper side of the lower frame 150 and applied as a pair to be disposed at positions facing each other. The upper frames 130 and 140 are disposed on the upper side of the side frames 110 and 120 and may connect a pair of side frames 110 and 120 to each other. Further, the rotating part mounting plates 131 and 141 may be coupled to the lower side of the upper frames 130 and 140.

A plurality of support plates 151 and 152 are coupled to one side and the other side of the lower frame 150, respectively, and weight bodies 153 and 154 having a constant weight may be coupled to the support plates 151 and 152. The weights (153, 154) coupled to the support plates (151, 152) maintain the position of the main frame (100) stably so as not to be swept away by ocean currents after the frame (10) for installation of geoacoustic measurement equipment is installed in the ocean sediment layer. I can. In an embodiment, the weight bodies 153 and 154 may be implemented in the form of a mass of heavy metal (for example, lead).

Mounting frames (160, 170) are installed on one side of the side frames (110, 120), the mounting frames (160, 170) for limiting the rise of the equipment mounting portion 200, which will be described later, limiting plate (161, 171) ) Can be combined. That is, the ascending limiting plates 161 and 171 serve to prevent the equipment mounting unit 200 from rising beyond a certain distance.

Guide rails 180 and 190 are installed at the lower side of the rising limiting plates 161 and 171, and the guide rails 180 and 190 are connected between the support plates 151 and 152 and the rising limiting plates 161 and 171, It helps the equipment mounting part 200 to rise or fall in a direction perpendicular to the ground.

Safety clasps (1611, 1711) may be hinged to the lower side of the rising limit plate (161, 171). Inclined surfaces 16111 and 17111 having a certain inclination may be formed under the safety clasps 1611 and 1711. In addition, clasp handles (16112, 17112) may be coupled to the outer circumferential surface of the safety clasps (1611, 1711), and the safety clasps (1611, 1711) are springs (1612, 1712) coupled to the lower side of the support plates (151, 152) Can be connected with.

On the upper side of the support plates 151 and 152, impact relief members 181 and 191 formed in the shape of a hollow cylinder are installed, and the guide rails 180 and 190 pass through the impact relief members 181 and 191, and the support plate 151, 152). The shock absorbing members 181 and 191 are made of a material capable of absorbing shock, and by absorbing the shock when the equipment mounting part 200 descends, the geoacoustic measuring equipment 20 installed in the equipment mounting part 200 is It can prevent damage by impact.

The equipment mounting part 200 is installed in the inner space S of the main frame 100, and is a device provided to mount and fix the geoacoustic measuring equipment 20. In one embodiment, the geoacoustic measurement equipment 20 refers to an equipment capable of measuring an acoustic signal transmitted through the submarine geology, and a transducer for signal transmission or a transducer for reception is provided below the geoacoustic measurement equipment 20 There may be a plurality of built-in steak 21 is provided.

A linking ring 210 may be installed on the upper side of the equipment mounting part 200, and the linking ring 210 may be bound to a part of the chain 260 to be described later. In addition, one or more weights 220 may be installed at one side of the equipment mounting part 200 so that the equipment mounting part 200 can rapidly descend in the direction of the ground.

In addition, locking projections 230 and 240 may be formed on side surfaces of the equipment mounting part 200. When the safety clasps (1611, 1711) support the lower end of the locking protrusions (230, 240), the descent of the equipment holder 200 is restricted, thus blocking the possibility of a safety accident in advance, and installed in the equipment holder 200. Damage to the geoacoustic measurement equipment 20 can be prevented. Hollow guide tubes 231 and 241 may be coupled to one side of the locking projections 230 and 240, and guide rails 180 and 190 may be coupled through the guide tubes 231 and 241.

In one embodiment, the chain 260 is a chain in which a plurality of key rings are connected to each other, and the connection ring 210 provided on the upper side of the equipment holder 200 is bound to one of the chains 260, and the chain One end 261 of the 260 may be bound to the coupling ring 250 and the other end 262 of the chain 260 may be bound to the coupling member 410.

The rotating part 300 is installed on one side of the main frame 100 and may rotate around the shaft 310. In one embodiment, the rotating part 300 may be coupled by the rotating part mounting plates 131 and 141 and the shaft 310. In addition, when the rotating part 300 and the rotating part mounting plates 131 and 141 are bound by the safety pin 1311, the rotating part 300 is not rotated. In one embodiment, the pivoting unit 300 may include a first pivoting member 320 and a second pivoting member 330.

Here, the first rotating member 320 may be installed on the upper end of the main frame 100 and may rotate at a certain angle. The second rotating member 330 is formed at one end of the first rotating member 320, and a clasp 331 capable of fixing one side of the equipment mounting part 200 is provided at one end of the second rotating member 330 Can be. In one embodiment, as the coupling ring 250 is bound to the clasp 331, and the coupling ring 250 is bound with the one end 261 of the chain 260, the second rotating member 330 is the equipment mounting part 200 ) Can be fixed.

In one embodiment, the first rotation member 320 is formed to have a relatively larger weight than the second rotation member 330, so that when the external force by the rotation preventing unit 400 to be described later is removed, the first rotation The first rotation member 320 rotates and moves downward by the center of gravity eccentric to the member 320 side, while the second rotation member 330 rises while rotating. That is, when the external force by the rotation preventing unit 400 is removed, the first rotating member 320 has a greater weight than the second rotating member 330 so as to rotate in a direction closer to the equipment mounting unit 200.

Meanwhile, in another embodiment, a clasp 331 may be formed at the lower end of the first rotating member 320. In this case, the first rotation member 320 may be axially coupled to the rotation unit mounting plates 131 and 141 and may rotate around the shaft 310.

When the rotation preventing part 400 is lifted upward, the rotation preventing part 400 may limit the rotation of the rotating part 300 by applying an external force from the lower side of the rotating part 300 to the upward direction. In one embodiment, the rotation preventing unit 400 may include a connecting member 410 and a locking member 420.

The connecting member 410 may be applied in the form of a wire having a predetermined length. In one embodiment, one end of the connecting member 410 may be bound to the cable C connected to the crane, and the other end of the connecting member 410 may be bound to the other end 262 of the chain 260. In addition, the locking member 420 may be coupled to surround the connection member 410 at one point of the connection member 410. When the connecting member 410 is lifted upward and the locking member 420 is in close contact with the first rotating member 320, the locking member 420 is a first rotating member to prevent the first rotating member 320 from rotating. 320) can be restricted. And, when the connecting member 410 is lifted upward, the locking member 420 is caught by the first rotating member 320 to press the first rotating member 320 in the upward direction. It is desirable to have a constant thickness.

The auxiliary fastening part 500 is a fastening device for temporarily fixing the connecting member 410 to the main frame 100 until the equipment mounting part 200 is dropped. When the first rotation member 320 rotates downward and the binding between the clasp 331 of the second rotation member 330 and the coupling ring 250 is released, the equipment holder 200 falls, and the equipment When the mounting part 200 falls, the auxiliary fastening part 500 is cut due to the weight of the equipment mounting part 200, so that the connecting member 410 can be naturally separated from the main frame 100.

In one embodiment, the chain 260 or the connecting member 410 is temporarily fixed to the upper frames 130 and 140 in a state in which the chain 260 and the connecting member 410 are connected to each other by using the auxiliary fastening part 500 can do. The auxiliary fastening part 500 temporarily fixes the chain 260 or the connecting member 410 to the upper frames 130 and 140, so that the chain 260 or the connecting member 410 is entangled and Prevents falling impediments.

In addition, the material of the auxiliary fastening part 500 may be formed of a material that can be easily cut off by a force generated when the equipment mounting part 200 falls. For example, the auxiliary fastening part 500 may be made of synthetic resin or natural resin, but the material of the auxiliary fastening part 500 is not limited to the above-described type.

3 is a perspective view schematically showing a frame for installation of a geoacoustic measurement equipment according to another embodiment of the present invention. Referring to FIG. 3, the frame 10 for installing the geoacoustic measurement equipment may further include a cover part 600.

When the cable (C) bound to the connection member 410 descends, the cover part 600 may prevent at least a portion of the main frame 100 from being entangled while flowing into the inner space S of the main frame 100. I can cover it. For example, the cover part 600 covers the top of the upper frames 130 and 140 so that the upper area of the main frame 100 is closed, so that some areas of the front and rear surfaces of the main frame 100 can be closed. It may be combined with some of the side frames 110 and 120. In addition, a communication hole 610 through which the connection member 410 passes may be formed in the cover part 600. That is, in one embodiment, as all of the upper region and part of the front and rear regions of the main frame 100 are closed by the cover part 600, the connection member 410 is the main frame 100 only through the communication hole 610. Since it may flow into the inside of the main frame 100, it is possible to prevent the phenomenon that the strings are entangled inside the main frame 100.

4 is an operational state diagram schematically showing a process in which a frame for installation of a geoacoustic measurement equipment according to an embodiment of the present invention is installed on the sea floor by a crane. 4, in one embodiment, when the rotation of the rotating part 300 is restricted by the compression of the rotation preventing part 400, one end of the rotating part 300 is connected to one side of the equipment mounting part 200 By maintaining the state, the equipment holder 200 remains suspended, but when the external force by the rotation preventing unit 400 disappears, the rotating unit 300 rotates by its own weight and the equipment holder 200 is separated to mount the equipment. The part 200 may be dropped in a downward direction.

A process in which the frame 10 for installing the geoacoustic measurement equipment according to an embodiment is installed on the sea floor by a crane (not shown) will be described in more detail as follows. First, while the crane is connected to the cable (C), lift the cable (C) upward, and then remove the safety pin (1311) that was plugged into the rotating part mounting plate (131, 141), and then remove the safety latch (1611, 1711). The primary configuration (ie, the safety pin 1311 and the safety latches 1611 and 1711) for controlling the fall of the equipment holder 200 by separating it from the locking projections 230 and 240 is released (Fig. 4A).

After that, the process of lowering the frame 10 for installing the geoacoustic measurement equipment to the seabed is in progress (Fig. 4b). In this process, gravity acts in the downward direction by the weight of the main frame 100, but since the connecting member 410 is suspended by a crane, the locking member 420 holds the first rotating member 320 in the upward direction. By pressing, rotation of the first rotating member 320 is restricted. And, since the coupling ring 250 maintains a state coupled to the clasp 331, the equipment mounting portion 200 does not fall.

The main frame 100 continues to descend downward and touches the bottom surface 30, and when the connecting member 410 descends downward by a crane, the locking member 420 and the first rotating member 320 As it is separated, the external force pressing on the first rotating member 320 disappears (Fig. 4C).

At the same time as the external force pressing the first rotating member 320 disappears, the first rotating member 320 descends downward and the second rotating member 330 is upward due to the eccentric center of gravity of the first rotating member 320. As the clasp 331 and the coupling ring 250 are released as they rise, the equipment mounting part 200 falls toward the bottom surface 30 (Fig. 4D).

The equipment mounting part 200 falls along the guide rails 180 and 190 to the floor surface 30, and the stake 21 of the geoacoustic measuring device 20 mounted in the equipment mounting part 200 is As a result, the installation of the geoacoustic measurement equipment 20 is completed by being embedded in the floor surface 30 (Fig. 4E).

5 is an operational state diagram schematically showing a process in which a frame for installation of a geoacoustic measurement equipment according to an embodiment of the present invention is pulled up and recovered. Referring to FIG. 5, a process in which the frame 10 for installing the geoacoustic measurement equipment according to an embodiment is pulled upward by a crane and recovered will be described in more detail as follows.

The chain 260 bound to the connection member 410 is also bound to the connection ring 210 of the equipment mounting unit 200, so when the cable (C) is lifted upward by a crane, the cable (C) and The connected connecting member 410 also rises, and in this process, the equipment mounting part 200 rises (Fig. 5a).

When the guide pipes (231, 241) contact the ascending limiting plates (161, 171) during the ascent of the equipment mounting part (200), an external force acts from the lower side of the ascending limiting plates (161, 171) to the upward direction to limit the ascent. The side frames 110 and 120 connected to the plates 161 and 171 are lifted upward, so that the frame 10 for installing the geoacoustic measurement equipment is lifted above the water surface (Fig. 5b).

When the guide pipes 231 and 241 ascend, the locking projections 230 and 240 move upward along the slopes 16111 and 17111 of the safety latches 1611 and 1711, and the safety latches 1611 and 1711 are springs. The lower sides of the locking projections 230 and 240 are automatically supported by the elastic force of the 1612 and 1712. That is, the safety clasps 1611 and 1711 support the lower side of the locking jaws 230 and 240 in the process of ascending the equipment mounting part 200, so that the equipment mounting part 200 is removed during the lifting process of the equipment mounting part 200. You can block the possibility of a sudden fall.

As described above, in the frame 10 for installing a geoacoustic measurement equipment according to an embodiment of the present invention, when the external force by the rotation preventing unit 400 disappears, the rotating unit 300 rotates by its own weight, and the equipment mounting unit Since (200) is separated, the equipment mounting unit 200 is dropped in the downward direction, so that the geoacoustic measurement equipment 20 is automatically stuck on the ground by gravity. Therefore, installation of the geoacoustic measurement equipment 20 is convenient, and when the connecting member 410 is lifted upward by a crane when the geoacoustic measurement equipment 20 installed on the ground is recovered, the main frame 100 is raised together. Therefore, there is an effect that it is easy to recover the installed geoacoustic measurement equipment 20. In addition, since the geoacoustic measurement equipment 20 can be easily installed even in a deep-sea sedimentary layer, which is difficult for a diver to access, acoustic characteristics (sound speed, sound attenuation) of the deep-sea sedimentary layer can be measured.

As described above, a detailed description of the present invention has been made by an embodiment with reference to the accompanying drawings, but since the above-described embodiment has been described with reference to a preferred example of the present invention, the present invention is limited to the above embodiment. It should not be understood as being, and the scope of the present invention should be understood as the following claims and the concept of equality.

10: Frame for installation of geoacoustic measuring equipment
100: main frame
110, 120: side frame
130, 140: upper frame
131, 141: mounting plate for rotating part
1311: safety pin
150: lower frame
151, 152: support plate
153, 154: heavy body
160, 170: mounting frame
161, 171: limited edition
1611, 1711: safety latch
16111, 17111: slope
16112, 17112: clasp handle
1612, 1712: spring
180, 190: guide rail
181, 191: shock absorbing member
S: inner space of the main frame
200: equipment mounting part
210: connection ring
220: weight body
230, 240: locking jaw
231, 241: guide hall
250: coupling ring
260: chain
261: one end of the chain
262: the other end of the chain
263: key ring
300: rotating part
310: axis
320: first rotating member
330: second rotating member
331: clasp
400: rotation prevention part
410: connecting member
420: locking member
500: auxiliary joint
600: cover part
610: communication hall
20: geoacoustic measurement equipment
21: steak
30: bottom surface
C: cable

Claims (6)

The main frame forming the exterior;
An equipment mounting unit installed in the inner space of the main frame and provided to mount and fix the geoacoustic measurement equipment;
A rotating part installed on one side of the main frame and rotating about an axis; And
Including; a rotation preventing unit for limiting the rotation of the rotating unit by applying an external force in the upward direction from the lower side of the rotating unit,
When the rotation of the rotating part is restricted by the rotation preventing part, one end of the rotating part remains connected to one side of the equipment mounting part, but when the external force by the rotation preventing part disappears, the rotating part rotates by its own weight. And by separating the equipment holder, the equipment holder is dropped in a downward direction,
The rotating part
A first rotating member installed on an upper end of the main frame so as to be rotatable at a certain angle; And
Including; a second rotating member formed at one end of the first rotating member,
At one end of the second rotating member, a clasp for fixing one side of the equipment mounting portion is provided,
The first rotation member is characterized in that it has a greater weight than the second rotation member so as to rotate in a direction closer to the equipment holder when the external force caused by the rotation preventing part is removed.
Frame for installation of geoacoustic measuring equipment. delete The method of claim 1,
The rotation preventing part
A connecting member having a certain length; And
And a locking member coupled to surround the connecting member at a point of the connecting member and restricting movement of the first rotating member when in close contact with the first rotating member.
Frame for installation of geoacoustic measuring equipment. The method of claim 3,
The frame for installing the geoacoustic measuring equipment
Further comprising; an auxiliary fastening part for temporarily fixing the connecting member to the main frame until the equipment mounting part is dropped,
When the equipment holder falls, the auxiliary fastening portion is cut due to the weight of the equipment holder, so that the connection member is separated from the main frame.
Frame for installation of geoacoustic measuring equipment. The method of claim 3,
The frame for installing the geoacoustic measuring equipment
A cover part for covering at least a part of the main frame to prevent the cable connected to the connection member from being entangled while flowing into the inner space of the main frame; further comprising,
A communication hole through which the connecting member passes is formed in the cover part.
Frame for installation of geoacoustic measuring equipment. delete

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