KR102612307B1 - The apparatus of fragment collecting test and the fragment collecting test method using the same - Google Patents

Abstract

It includes a debris recovery module, a water tank that accommodates the debris recovery module and a predetermined amount of water so that the debris recovery module is immersed in water, and a fixing module that supports the debris recovery module outside the water tank, and the debris recovery module Silver, a test bullet fixing part that fixes and supports the test bullet to test the shape of the fragment; a lifting unit that surrounds the outside of the test coal fixing unit and moves the test coal fixing unit into or out of the water tank; A detonator that detonates the test bullet; and a sealing part that seals the lifting part and the detonating part from water in the water tank. A fragment recovery test device and a fragment recovery test method using the same are provided.

Description

{The apparatus of fragment collecting test and the fragment collecting test method using the same}

The present invention relates to a debris recovery test device that can be carried out underwater to protect workers and reduce noise, and to a debris recovery test method using the same.

Explosive bombs are designed to fly a long distance to their destination and then detonate at the destination, causing the fragments of the bomb to scatter to an area within a certain radius after detonation, causing damage to surrounding enemies. The explosive shell has a structure in which the high explosive charged in the shell burns and fragments scatter. For efficient scattering of fragments, the combustion of the high explosive generates high pressure inside the shell, so the shell and warhead can withstand a certain pressure. It must be capable of explosion and must be manufactured to explode accurately at its destination.

Therefore, the performance test of explosive bombs can be considered very important, and the performance test of explosive bombs can be performed by testing in advance the explosion pressure generated during detonation and the effect of scattered fragments.

Methods for testing the effect of fragments include detonating an explosive bomb at a predetermined location, analyzing the speed and kinetic energy of the fragments generated after detonation, and analyzing the shape of the recovered fragments and the number of fragments. However, the phenomenon that occurs due to fragments can vary depending on the scope, nature of the threat depending on the target, and the characteristics of the materials used for protection. In addition, most fragments are very small in size and designed to have a very high speed compared to the applied energy, and a lot of dust may be generated when the explosive bomb is detonated, so there may be limitations in analysis.

To solve this problem, Korean Patent No. 10-1677985, ‘Warhead performance test device and operation method thereof’ and Korean Patent No. 10-1827222, ‘Fragment velocity measurement device and fragment velocity measurement method’ have been disclosed. . The above technologies can be said to be methods capable of analyzing the path, speed, and kinetic energy of fragments, but it is not a solution to analyze the distribution of fragments by weight while reflecting the safety of workers and noise generation during detonation. It can be seen as difficult to do.

Korean Patent No. 10-1677985 (registration date: November 15, 2016) Korean Patent No. 10-1827222 (Registration Date: February 1, 2018) Korean Patent Publication No. 10-2014-0145852 (Publication date: December 24, 2014)

The technical problem to be achieved by the present invention is to provide a fragment recovery test device that can analyze the distribution of fragments by weight regardless of the type and shape of the test bullet and a fragment recovery test method using the same.

In addition, another technical problem to be achieved by the present invention is to provide a fragment recovery test device and a fragment recovery test method using the same, which can perform a fragment recovery test even if the operator is not around the test device and thereby ensure work safety. The purpose is to provide

Furthermore, another technical problem to be achieved by the present invention is to reduce the risk due to non-explosion by preventing test bullets from being exposed to water, to increase the accuracy of fragment recovery by preventing disruption of fragmentation by water pressure, and to increase the accuracy of fragment recovery and the noise generated during detonation. The purpose is to provide a debris recovery test device that can reduce and a debris recovery test method using the same.

The purpose of the present invention is not limited to the purposes mentioned above, and other purposes not mentioned will be clearly understood by those skilled in the art from the description below.

In order to solve the above problem, the present invention includes a debris recovery module, a water tank that accommodates the debris recovery module and a predetermined amount of water so that the debris recovery module is submerged in water, and a device that supports the debris recovery module outside the water tank. It includes a fixing module, wherein the fragment recovery module includes: a test bullet fixing unit for fixing and supporting the test bullet to be tested for the shape of the fragment; a lifting unit that surrounds the outside of the test coal fixing unit and moves the test coal fixing unit into or out of the water tank; A detonator that detonates the test bullet; and a sealing part that seals the lifting part and the detonating part from water in the water tank. It is possible to provide a debris recovery test device comprising a.

The test bullet fixing unit includes an upper fixing member for fixing the upper position of the test bullet, a lower fixing member for fixing the lower position of the test bullet, and an airtight container into which the upper fixing member and the lower fixing member are inserted and combined, It may include an airtight cover covering the airtight container.

The test bullet fixing unit may further include a weight located below the lower fixing member.

The sealing part may be made of vinyl material.

The fixing module may be coupled to a lifting rope located at one end of the lifting unit and include a lifting drive unit that drives the lifting unit to move up and down.

One end of the sealing portion is coupled to the fixing module to be wound or unwound, and may be wound or unwound in conjunction with the up and down movement of the lifting rope.

The detonator exposed from one end of the sealing portion may be guided and positioned along the fixing module and connected to a detonator located outside the fixing module.

In addition, in order to solve the above problem, the present invention includes the steps of fixing the test bullet inside the test bullet fixing unit; Preparing a seal; Surrounding the lower and side surfaces of the test bullet fixing unit with a lifting part; Connecting the lifting unit to a fixing module; Positioning the lifting unit inside a tubular seal with a closed lower end; Connecting the detonator to the test bullet and airtightening the test bullet fixing part; and a step of unwinding one end of the sealing part and lowering it together with the lifting part into the water tank containing water, and fixing the sealing part and the lifting part to the fixing module at a predetermined height. can be provided.

Fixing the test bullet inside the test bullet fixing unit fixes the lower position of the test bullet to the lower fixing member of the test bullet fixing part, and fixes the upper position of the test bullet to the upper fixing member of the test bullet fixing part. It may be fixed by combining the upper fixing member and the lower fixing member inside the airtight container.

Airtightening the test bullet fixing unit involves connecting the detonator to the test bullet, passing the detonator through a hole formed in the center of an airtight cover covering the top of the airtight container, and sealing the hole with a sealant. It can be included.

Before fixing the test bullet inside the test bullet fixing unit, it may further include placing a weight on the lower surface of the airtight container.

The sealing part may be made of vinyl material.

Connecting the lifting unit to the fixing module may mean connecting a lifting rope located at one end of the lifting unit and a lifting drive unit located in the fixing module.

The fragment recovery test device according to an embodiment of the present invention and the fragment recovery test method using the same are provided with a fragment recovery module combined with the test projectile, thereby performing analysis on the distribution of fragments by weight regardless of the type and shape of the test projectile. There are advantages to doing this. In addition, by providing a debris recovery module and a fixing module so that the debris recovery test can be performed underwater, the debris recovery test can be performed without the operator being around the test device, which has the advantage of ensuring work safety.

Furthermore, by testing using a sealed fragment recovery module inside a water tank containing a certain amount of water, it is possible to prevent the test projectile from being exposed to water, reduce the risk of non-explosion of the test projectile, and prevent the fragmentation phenomenon caused by water pressure. This has the effect of increasing the accuracy of fragment recovery and reducing the noise generated during detonation.

1 is a cross-sectional view showing a debris recovery test device according to an embodiment of the present invention;
Figure 2 is a cross-sectional view showing the debris recovery module of the debris recovery test device according to an embodiment of the present invention;
Figure 3 is a top view showing a part of the debris recovery module of the debris recovery test device according to an embodiment of the present invention;
Figure 4 is a process flow diagram showing a fragment recovery test method according to an embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the attached drawings. The embodiments introduced below are provided as examples so that the idea of the present invention can be sufficiently conveyed to those skilled in the art. Accordingly, the present invention is not limited to the embodiments described below and may be embodied in other forms. Also, in the drawings, the length and thickness of layers and regions may be exaggerated for convenience. Like reference numerals refer to like elements throughout the specification.

Figure 1 is a cross-sectional view showing a fragment recovery test device according to an embodiment of the present invention, Figure 2 is a cross-sectional view showing a fragment recovery module of the fragment recovery test device according to an embodiment of the present invention, and Figure 3 is a fragment recovery test device according to an embodiment of the present invention. Figure 4 is a top view showing a part of the debris recovery module of the debris recovery test device, and Figure 4 is a process flow diagram showing the debris recovery test method according to an embodiment of the present invention.

Referring to Figures 1 to 3, the debris recovery test device 10 according to an embodiment of the present invention includes a debris recovery module 100 and a predetermined amount of water (W) so that the debris recovery module 100 is submerged in water. And a water tank 200 for accommodating the debris recovery module 100, and a fixing module 300 for supporting the debris recovery module 100 on the outside of the water tank 200, wherein the debris recovery module 100 ) is a test bullet fixing unit 110 that fixes and supports the test bullet (A) to test the shape of the fragment; A lifting unit 120 that surrounds the outside of the test coal fixing part 110 and moves the test coal fixing part 110 into or out of the water tank 200; A detonator 130 that detonates the test bullet; and a sealing part 140 that seals the lifting part 120 and the detonating part 130 from water in the water tank.

In detail, the water tank 200 that accommodates the fragment recovery module 100 to be immersed in water (W) has at least 100 to 120 ounces per 1 kg of high explosive charge in order to recover fragments, ensure the safety of workers, and ensure efficient water consumption. It may accommodate ㎥ of water.

The fragment recovery module 100, which includes a test bullet fixing part 110, a lifting part 120, a detonator 130, and a sealing part 140, is coupled to the fixing module 300, and the water tank 200 ) can be moved inside or outside. The test bullet fixing part 110, which fixes and supports the test bullet (A) for testing the shape of the fragment, includes an upper fixing member 111 that fixes the upper position of the test bullet (A), and the test bullet ( A lower fixing member 113 that fixes the lower position of A), an airtight container 115 into which the upper fixing member 111 and the lower fixing member 113 are inserted and combined, and a cover for the airtight container 115. It may include an airtight cover 117. The lower fixing member 113 is processed to correspond to the shape of the lower part of the test bullet (A), and the lower part of the test bullet (A) can be fitted and fixed. In addition, the upper fixing member 111 is processed to correspond to the upper shape of the test bullet (A), and the upper part of the test bullet (A) can be fitted and fixed. Since the central area of the upper fixing member 111 and the lower fixing member 113 is processed according to the shape of the test bullet (A) to be tested, the test bullet fixing part ( 110) can be prepared respectively, and as a result, the fragment recovery module 100 can also be prepared according to the type of test projectile (A). In other words, analysis of the distribution of fragments by weight can be performed regardless of the type of test bullet (A).

The upper fixing member 111 and the lower fixing member 113 are processed to correspond to the inner surface shape of the airtight container 115, and the upper fixing member 111 and the lower fixing member ( 113) can be inserted and coupled and fixed, so the test bullet (A) can be mounted and fixed inside the test bullet fixing part 110.

Furthermore, the test bullet fixing unit 100 may further include a weight 119 located below the lower fixing member 113. For example, the weight 119 uses a filling material such as clay to fill the empty area between the weight 119 and the lower fixing member 113 or the weight 119 and the test bullet (A) to increase the fixing force. It can be further strengthened. When the test bullet fixing part 110 is placed inside the water tank 200 to be submerged in water, it may be difficult to descend to a predetermined height due to the effect of buoyancy. In order to overcome this, the weight 119 is placed inside the test bullet fixing part 110, that is, on the lower surface of the airtight container 115, and the test bullet is placed at the desired location inside the water tank 200 without being affected by buoyancy ( A) can be placed. As an example, under conditions that minimize the influence of buoyancy and place the test bullet (A) inside the water tank 200, (weight of test bullet (A): weight of weight 119: airtight container (115) The ratio for the volume of ) may be 1 kg: (6.1 to 6.5) kg: (6.2 to 7.2) L.

The lifting part 120, which surrounds the outside of the test bullet fixing part 110 and moves the test bullet fixing part 110 into or out of the water tank 200, can be operated by the fixing module 300. And, the test bullet fixing part 110 can be safely moved to a desired location inside the water tank 200. In this case, the lifting unit 120 can move the test coal fixing unit 110 in a direction in which the upper fixing member 111 and the lower fixing member 113 are parallel to the bottom surface of the water tank.

In order to be able to move the test coal fixing part 110 into or out of the water tank 200 regardless of the shape of the test coal fixing part 110, the lifting part 120 is made of a fabric having a mesh structure that is strong against friction and has a light mesh structure. It is advisable to use a net as an example.

The sealing part 140 that seals the lifting part 120 and the detonating part 130 from the water W in the water tank 200 is formed on the outer surface of the lifting part 120 by the water pressure in the water tank 200. The shape may be formed accordingly. For example, the sealing portion 140 may be made of a vinyl material, and further, may be a conductive vinyl material. Static electricity may affect electronic devices connected to the detonator 130 or the fragment recovery test device 10, which may pose a risk to the tester installing the fragment recovery test device 10, so prevent the generation of static electricity. It may be considered desirable to provide a sealing portion made of a conductive vinyl material.

The detonating part 130 for detonating the test bullet (A) may be exposed from one end of the sealing part 140 located outside the water tank 200, and runs along the support body 320 of the fixing module 300. It may be guided and positioned and connected to the detonator 400 located on the outside of the fixing module 300 to detonate the test projectile (A) located inside the water tank 200. Therefore, the fragment recovery test can be performed even if the operator is not around the test device, thereby ensuring work safety.

The fixing module 300, which is located outside the water tank 200 and moves or fixes the position of the debris recovery module 100 so that the debris recovery module 100 is submerged in water, supports the lifting unit ( It may include a lifting drive unit 310 that is coupled to the lifting rope 124 located at one end of the lifting unit 120 and drives the lifting unit 120 to move up and down. For example, the lifting unit 120 may include a lifting unit body 122 surrounding the test bullet fixing part 110 and a lifting rope 124 coupled to one end of the lifting unit body 122, The lifting rope 124 may be combined with the lifting drive unit 310. Therefore, the lifting rope 124 moves up and down due to the lifting part 310, and the lifting part body 122 connected to the lifting rope 124 can also move up and down together. In order to prevent fragments from scattering upward or from loss of fragments during detonation, it is desirable that the coupling area between the lifting rope 124 and the lifting part body 122 have a diameter within a range that does not interfere with the operation of the detonating part 130. And, it may be smaller than the diameter of the test bullet fixing part 110.

The sealing part 140 can be released or rolled up simultaneously with the lifting rope 124 by the tester's hand. As another example, one end of the sealing part 140 is wound or unwound by the fixing module 300. It is coupled to, and can be wound or unwound in conjunction with the up and down movement of the lifting rope 124. That is, when the lifting rope 124 extends downward, the sealing part 140 surrounding the lifting part 120 is also unwound and moves inside the water tank 200, so that the lifting part 120 and the test coal located within the lifting part The government 110 is sealed from the water W in the water tank 200 and can be moved to a target location in the water tank 200. Therefore, by preventing the test projectile (A) from being exposed to water, the risk due to non-explosion of the test projectile (A) can be reduced and the fragmentation interference phenomenon caused by water pressure can be prevented, thereby increasing the accuracy of fragment recovery.

Referring to Figures 1 to 4, the fragment recovery test method according to an embodiment of the present invention includes the step of fixing the test bullet (A) inside the test bullet fixing part 110 (S110); Preparing the sealing portion 140 (S120); Surrounding the lower and side surfaces of the test bullet fixing part 110 with the lifting part 120 (S130); Connecting the lifting unit 120 to the fixing module 300 (S140); Positioning the lifting part 120 inside a tubular sealing part 140 whose lower end is closed (S150); Connecting the detonator 130 to the test bullet (A) and airtightening the test bullet fixing part 110 (S160); And the sealing part 140 is unwound at one end and is lowered into the water tank 200 containing the water W together with the lifting part 120, and the sealing part 140 and the lifting part 120 are at a predetermined height. It may include a step (S170) of fixing to the fixing module 300.

As described in the fragment recovery test device 10, the test bullet fixing part 110, the lifting part 120, the detonator 130, and the sealing part 140 constitute the fragment recovery module 100, The test bullet fixing unit 110 may include an upper fixing member 111, a lower fixing member 113, an airtight container 115, and an airtight cover 117.

To explain in detail, first, the test bullet (A) can be fixed inside the test bullet fixing unit 110 (S110). Fixing the test bullet (A) inside the test bullet fixing part 110 (S110) involves positioning the lower part of the test bullet (A) on the lower fixing member 113 of the test bullet fixing part 110. Fix the upper position of the test bullet (A) to the upper fixing member 111 of the test bullet fixing part 110, and place the upper fixing member 111 and the lower fixing member 113 in an airtight container ( 115) It may be fixed by combining it internally. The upper fixing member 111 and the lower fixing member 113 may have a central area processed according to the shape of the test bullet (A) to be tested, and the test bullet (A) has an upper and lower part in the processed shape. It can be fitted and fixed inside the airtight container (115). Therefore, since the test bullet fixing part 110 is prepared according to the shape and size of the test bullet (A), the fragment recovery module 100 can also be prepared according to the type of test bullet (A). In other words, analysis of the distribution of fragments by weight can be performed regardless of the type of test bullet (A).

In addition, before fixing the test bullet (A) inside the test bullet fixing unit 110, a step of positioning a weight 119 on the lower surface of the airtight container 115 may be further included. For example, the weight 119 can be inserted into the lower surface of the airtight container 115, the lower fixing member 113 and the test bullet (A) can be mounted on the upper part, and the weight 119 and the lower fixation The fixing force can be further strengthened by filling the empty area between the member 113 or the weight 119 and the test bullet (A) using a filling material such as clay. When the test bullet fixing part 110 is placed inside the water tank 200 so that it is submerged in water, it may be difficult to descend to a predetermined height due to the action of buoyancy. To overcome this, the inside of the test bullet fixing part 110, That is, by placing the weight 119 on the lower surface of the airtight container 115, the test bullet (A) can be placed at a desired location inside the water tank 200 without being affected by buoyancy. As an example, under conditions that minimize the influence of buoyancy and place the test bullet (A) inside the water tank 200, (weight of test bullet (A): weight of weight 119: airtight container (115) The ratio for the volume of ) may be 1 kg: (6.1 to 6.5) kg: (6.2 to 7.2) L.

Next, the sealing portion 140 can be prepared (S120). The step of preparing the sealing portion 140 may be performed before the step of fixing the test bullet (A) inside the test bullet fixing part 110 (S110). For example, the sealing portion 140 may be made of a vinyl material, and further may be made of a conductive vinyl material.

Next, the lower portion and side of the test bullet fixing part 110 can be surrounded by the lifting part 120, and the test bullet fixing part 110 can be positioned within the lifting part 120 (S130). Regardless of the shape of the test coal fixing part 110, the lifting part 120 is made of fabric having a mesh structure, for example, a net, so that the test coal fixing part 110 can be moved inside or outside the water tank 200. It is desirable.

Afterwards, the lifting unit 120 can be connected to the fixing module 300 (S140). Connecting the lifting unit 120 to the fixing module 300 includes a lifting rope 124 located at one end of the lifting unit 120 and a lifting drive unit 310 located on the fixing module 300. It may be combined and connected. That is, the lifting unit 120 may include a lifting unit body 122 surrounding the test bullet fixing part 110 and a lifting rope 124 coupled to one end of the lifting unit body 122, The lifting rope 124 may be combined with the lifting drive unit 310. Therefore, the lifting rope 124 moves up and down due to the lifting tool eastern part 310, and the lifting part body 122 connected to the lifting rope 124 can also move up and down together. In order to prevent fragments from scattering upward or from loss of fragments during detonation, it is desirable that the coupling area between the lifting rope 124 and the lifting part body 122 have a diameter within a range that does not interfere with the operation of the detonating part 130. And, it may be smaller than the diameter of the test bullet fixing part 110.

Next, as shown in FIG. 3, the lifting part 120 can be placed inside the tubular sealing part 140 with the lower end closed (S150). That is, the sealing part 140 may be prepared in a tubular form with a closed lower end, and the lower part of the lifting part 120 surrounding the test bullet fixing part 110 may be located on the closed lower end. Therefore, since the sealing part 140 can be positioned surrounding the lifting part 120, the test bullet (A) is prevented from being exposed to water in the water tank 200 during the detonation test, thereby preventing the test bullet (A) from being exposed to water. The accuracy of fragment recovery can be improved by reducing the risk caused by water pressure and preventing fragmentation interference caused by water pressure.

Next, the detonator 130 can be connected to the test bullet (A), and the test bullet fixing part 110 can be airtight (S160). The test bullet fixing part 110 is airtightened by connecting the detonator 130 to the test bullet (A) and forming a hole in the center of the airtight cover 117 that covers the top of the airtight container 115. This may include passing the detonator 130 through the detonator 130 and sealing the hole with a sealant 117a. Therefore, the risk due to detonation can be further reduced by further sealing the test bullet (A) from external moisture. For example, the sealant 117a may be a silicone coating agent such as RTV-3145.

Next, one end of the sealing part 140 in which the lifting part 120 is located is unwound and lowered together with the lifting part 120 into the water tank 200 containing water, and the sealing part 140 inside the water tank 200 is lowered. The sealing part 140 and the lifting part 120 can be fixed to the fixing module 300 at a predetermined height (S170). In this case, the lifting unit 120 can lower the test coal fixing unit 110 in a direction in which the upper fixing member 111 and the lower fixing member 113 are parallel to the bottom surface of the water tank. The lifting part 120, which surrounds the outside of the test bullet fixing part 110 and moves the test bullet fixing part 110 into or out of the water tank 200, includes a test bullet (A) and a weight 119. The airtight container 115 containing can be safely moved to a desired location inside the water tank 200 by operating with the fixing module 300. That is, the fragment recovery module 100 equipped with the test bullet (A) is protected from the water (W) in the water tank 200 using the lifting part 120 and the sealing part 140, and the test bullet (A) is protected from the water (W) in the water tank (200). After being submerged in (200), the debris recovery module (100) can be fixed at a predetermined height. In addition, the sealing part 140 that seals the lifting part 120 and the detonating part 130 from the water W in the water tank 200 is formed along the outer surface of the lifting part 120 by the water pressure in the water tank. Shapes can be formed.

The water tank 200, which accommodates the fragment recovery module 100 to be submerged in water, may accommodate at least 100 to 120 m3 of water per 1 kg of high explosive charge in order to recover fragments, ensure the safety of workers, and ensure efficient water consumption. there is.

Finally, when the fragment recovery module 100 is fixed at the desired position in the water tank 200, the test bullet (A) is detonated through the detonator 130 to generate fragments, and the lifting part 120 and the sealing part ( 140) can be raised to the outside of the tank to recover the fragments (S180). The detonator 130 for detonating the test bullet (A) may be exposed from one end of the sealing part 140 located outside the water tank 200, and may be guided and installed along the fixing module 300. there is. The detonator 130 may be connected to the detonator 400 located on the outside of the fixing module 300 to detonate the test projectile (A) located inside the water tank 200. Therefore, the fragment recovery test can be performed even if the operator is not around the test device, thereby ensuring work safety.

The fragment recovery test device 10 and the fragment recovery test method using the same according to an embodiment of the present invention include a fragment recovery module 100 coupled to the test projectile (A), so that the type and shape of the test projectile (A) can be determined. Regardless, there is an advantage in being able to perform analysis on the distribution of fragments by weight. In addition, by providing a debris recovery module 100 and a fixing module 300 to perform a debris recovery test in water, a debris recovery test can be performed without the operator being around the test device, thereby ensuring work safety. There are advantages to this. Furthermore, by testing using a sealed fragment recovery module 100 inside a water tank 200 containing a predetermined amount of water, it is possible to prevent the test bullet (A) from being exposed to water, and the non-explosion of the test bullet (A). It can reduce the risk caused by water pressure, prevent fragmentation interference caused by water pressure, increase the accuracy of fragment recovery, and reduce the noise generated during detonation.

Although the present invention has been described above with reference to preferred embodiments, those skilled in the art may make various modifications and changes to the present invention without departing from the spirit and scope of the present invention as set forth in the claims below. You will understand that you can do it.

10; Debris recovery test device
100; Debris recovery module
110; Test bullet fixing part
120; salvage department
130; detonator
140; seal
200; water tank
300; Fixed module
400: Detonator

Claims (13)

It includes a debris recovery module, a water tank that accommodates the debris recovery module and a predetermined amount of water so that the debris recovery module is immersed in water, and a fixing module that supports the debris recovery module outside the water tank,
The debris recovery module,
A test bullet fixing unit that fixes and supports the test bullet whose shape the fragment is to be tested for;
a lifting unit that surrounds the outside of the test coal fixing unit and moves the test coal fixing unit into or out of the water tank;
A detonator that detonates the test bullet; and
A debris recovery test device comprising a sealing part that seals the lifting part and the detonating part from water in the water tank.
According to claim 1,
The test bullet fixing unit includes an upper fixing member for fixing the upper position of the test bullet, a lower fixing member for fixing the lower position of the test bullet, and an airtight container into which the upper fixing member and the lower fixing member are inserted and combined, A debris recovery test device comprising an airtight cover covering the airtight container.
According to claim 2,
The test bullet fixing unit is a fragment recovery test device characterized in that it further includes a weight located on the lower side of the lower fixing member.
According to claim 1,
A debris recovery test device, wherein the sealing portion is made of vinyl material.
According to claim 1,
The fixing module is coupled to a lifting rope located at one end of the lifting unit and includes a lifting drive unit that drives the lifting unit to move up and down.
According to claim 5,
A debris recovery test device characterized in that one end of the sealing part is coupled to the fixing module to be wound or unwound, and is wound or unwound in conjunction with the up and down movement of the lifting rope.
According to claim 1,
A fragment recovery test device, characterized in that the detonator exposed from one end of the sealing portion is guided and located along the fixing module and is connected to a detonator located outside the fixing module.
Fixing the test bullet inside the test bullet fixing unit;
Preparing a seal;
Surrounding the lower and side surfaces of the test bullet fixing unit with a lifting part;
Connecting the lifting unit to a fixing module;
Positioning the lifting unit inside a tubular seal with a closed lower end;
Connecting the detonator to the test bullet and airtightening the test bullet fixing part; and
A debris recovery test method comprising the step of unwinding one end of the sealing part and lowering it together with the lifting part into the water tank containing water, and fixing the sealing part and the lifting part to the fixing module at a predetermined height.
According to claim 8,
Fixing the test bullet inside the test bullet fixing unit fixes the lower position of the test bullet to the lower fixing member of the test bullet fixing part, and fixes the upper position of the test bullet to the upper fixing member of the test bullet fixing part. A fragment recovery test method characterized by fixing and fixing the upper and lower fixing members by combining them inside an airtight container.
According to clause 9,
Airtightening the test bullet fixing unit involves connecting the detonator to the test bullet, passing the detonator through a hole formed in the center of an airtight cover covering the top of the airtight container, and sealing the hole with a sealant. A fragment recovery test method comprising:
According to clause 9,
A fragment recovery test method further comprising placing a weight on the lower surface of the airtight container before fixing the test bullet inside the test bullet fixing unit.
According to claim 8,
A fragment recovery test method, characterized in that the sealing part is made of a vinyl material.
According to claim 8,
A debris recovery test method characterized in that connecting the lifting unit to the fixing module involves connecting a lifting rope located at one end of the lifting unit and a lifting drive unit located in the fixing module.