KR20130047277A - Bulletproof performance testing apparatus for knifeproof material - Google Patents

Abstract

PURPOSE: A device for measuring the bulletproof performance of a bulletproof material is provided to accurately and safely obtain a result of a performance test, to improve the reliability of the test, and to conveniently perform the test. CONSTITUTION: A device for measuring the bulletproof performance of a bulletproof material comprises a support(200), a frame unit(100), a bullet throwing unit(300), a speed measuring unit(400), and a control unit(700). A target material is placed on the top surface of the support which is arranged perpendicular to the ground. The frame unit supports the support to be movable in a y-axis and a z-axis. The bullet throwing unit horizontally throws a testing bullet to the support by using air pressure. The speed measuring unit measures the speed of the testing bullet shot at the support. The control unit controls a position of the frame unit, the existence of a supply of the testing bullet, and a shooting speed. [Reference numerals] (330) Air compressor; (700) Control unit

Description

Bulletproof performance measuring device of bulletproof material {BULLETPROOF PERFORMANCE TESTING APPARATUS FOR KNIFEPROOF MATERIAL}

The present invention relates to a performance measuring apparatus, and more particularly to a ballistic performance measuring apparatus that can measure the ballistic resistance of the bulletproof material using pneumatic.

Bulletproof material is a material that prevents bullets from being inserted into the human body when bullets are blown to the user.

Since the bulletproof material affects the wearer's life, it measures whether the ballistic performance is specified by the country, and is processed into a body armor for the satisfied product.

Conventional ballistic test methods are mainly used NIL-3TD-662, NATO STANAG 2920, NIJ standards. The apparatus used in this experiment consists of three parts: warhead launcher, warhead velocity measuring device and tester support. However, since the conventional bulletproof test method uses a real bullet, it is difficult to test the bulletproof performance by installing easily because high cost and safety above all are required in terms of a test facility.

An object of the present invention is to solve the above problems, to provide an anti-ballistic performance measuring device of the bulletproof material that can effectively measure the bulletproof performance of the bulletproof material against the bullet thrown in the horizontal direction.

Another object of the present invention is to provide an anti-ballistic performance measuring apparatus of the anti-ballistic material to ensure the safety of the measurer when measuring the anti-ballistic performance of the bulletproof material.

Still another object of the present invention is to provide an antiballistic performance measuring apparatus for a bulletproof material that can easily measure antiballistic performance using pneumatic pressure.

The above objects and various advantages of the present invention will become more apparent from the preferred embodiments of the present invention by those skilled in the art.

The object of the present invention can be achieved by an apparatus for measuring the ballistic resistance of the bulletproof material. The anti-ballistic performance measurement apparatus of the anti-ballistic material of the present invention, the support is provided in the vertical direction on the ground and the material to be measured on the upper surface; A frame part which supports the support so as to be movable in the Y-axis and Z-axis directions; A bullet throwing unit positioned to be spaced apart in a horizontal direction with respect to the support and throwing a test bullet therein into the support horizontally by pneumatic; A speed measuring unit measuring a speed of the test bullet thrown by the bullet throwing unit to the support unit; And a control unit for controlling the position of the frame unit, whether the bullet throwing unit is supplied, and the throwing speed.

According to one embodiment, the bullet supply unit, a bullet coupling unit for detachably coupling the test bullet by pneumatic and magnetic force; Pneumatic forming unit for forming a pneumatic pressure in the bullet coupling portion to couple or leave the test bullet to the bullet coupling portion; It may include an air compressor connected to the pneumatic forming unit.

In the anti-ballistic performance measuring apparatus according to the present invention, the test bullet is thrown horizontally by pneumatic pressure and collides with the material to be measured, and the performance result is measured based thereon. This allows safe and accurate performance test results to be measured.

In addition, the anti-ballistic performance measurement apparatus according to the present invention is thrown in a state in which the initial speed is controlled by the pneumatic pressure to improve the reliability of the test and can be easily performed.

In addition, since the position and the pneumatic pressure of the support by the control unit may be repeated test in a variety of test conditions.

1 is a perspective view showing the configuration of an antiballistic performance measuring apparatus according to the present invention,
Figure 2 is an exemplary view showing a side configuration of the ballistic performance measurement process of the ballistic performance measuring apparatus according to the present invention.

In order to fully understand the present invention, preferred embodiments of the present invention will be described with reference to the accompanying drawings. The embodiments of the present invention may be modified into various forms, and the scope of the present invention should not be construed as being limited to the embodiments described in detail below. The present embodiments are provided to enable those skilled in the art to more fully understand the present invention. Therefore, the shapes and the like of the elements in the drawings can be exaggeratedly expressed to emphasize a clearer description. It should be noted that in the drawings, the same members are denoted by the same reference numerals. Detailed descriptions of well-known functions and constructions which may be unnecessarily obscured by the gist of the present invention are omitted.

1 is a perspective view showing the configuration of the anti-ballistic performance measuring apparatus 1 according to the present invention, Figure 2 is a side view schematically showing a measurement process of the anti-ballistic performance measuring apparatus (1).

As illustrated, the ballistic resistance measuring apparatus 1 according to the present invention supports a support 200 on which a material to be measured B is loaded on an upper surface thereof, and supports the support 200 to be movable in the Y-axis and Z-axis directions. Measures the velocity of the bullet unit 300, which throws the frame bullet 100, the test bullet A coupled with the sword toward the support 200, and the test bullet A thrown toward the support 200. And a control unit 700 for controlling the position of the frame unit 100 and the pneumatic pressure of the bullet throwing unit 300.

The material to be measured (B) is cut on a reference size for measurement and then loaded on the support 200. A support member C is provided below the material B to be measured. The support member (C) is provided with a dough mass, such as clay, to determine the degree to which the material to be measured (B) is pushed against the support 200 by the impact of the test bullet (A), puncture, deformation.

The test bullet A is provided corresponding to the shape and weight of the actual bullet. Test bullet (A) is provided harmless to the human body without the explosives. A magnet (not shown) is built in the upper portion of the test bullet A. The test bullet A is detachably coupled to the bullet coupling part 310 by a magnetic force formed by a magnet (not shown). Test bullet (A) may be provided in various ways depending on the size.

The frame unit 100 supports the support 200 to be movable in the Y-axis and Z-axis directions, and supports the bullet throwing unit 300 and the X-axis position of the speed measuring unit 400 to be adjusted. Frame portion 100 is provided in the lower portion of the support 200, the support frame 110 provided in the vertical direction, and the horizontal is provided horizontally to the bullet throwing unit 300 and the speed measuring unit 400 is horizontal Frame 130.

The support frame 110 is provided to have a predetermined area, and is provided with a Z-axis feed rail 111 and a Y-axis feed rail 113 on an upper surface thereof. As shown in FIG. 2, the Y-axis feed rail 113 accommodates the Y-axis feed shaft 210 under the support 200 so that the support 200 is positioned in the Y-axis direction. In addition, the lower region of the Y-axis feed rail 113 is fixed on the Z-axis feed rail 111 to adjust the position of the support 200 in the Z-axis direction.

Here, the Y-axis and Z-axis position adjustment is adjusted through the control of the control unit 700 by the LM guide method between the feed shaft and the feed rail. That is, the position adjustment in the X-axis and Y-axis directions is automatically adjusted by the coordinate values input by the measurer 700 through the control unit 700.

The horizontal frame 130 is provided with a predetermined length in a vertical direction with respect to the support frame 110. In the horizontal frame 130, the coupling plate 140, which the bullet throwing unit 300 and the speed measuring unit 400 are coupled to, X It is coupled to the left and right movable along the axis feed rail (141). X-axis position adjustment of the coupling plate 140 is automatically adjusted through the control unit 700.

The support 200 supports the material to be measured B and the supporting member C to be stably positioned during the performance measurement. Support 200 is provided with a plate-like material having a predetermined area and is provided to enable position adjustment in the Y-axis and Z-axis direction by the support frame 110. Accordingly, the contact point of the test bullet (A) can be adjusted. Therefore, the ballistic resistance measurement at various positions of the material to be measured (B) can be performed.

One side of the support 200 is a horizontal direction of the guide plate 220 for preventing the measurement material (B) and the support member (C) from being separated from the support 200 by collision with the test bullet (A) It is provided with.

The bullet throwing unit 300 throws the test bullet A toward the support 200 using pneumatic pressure. The bullet throwing unit 300 has a pneumatic pressure between the bullet coupling unit 310 and the bullet coupling unit 310 and the bullet coupling unit 310 by injecting air into the bullet coupling unit 310 and the test bullet A and the bullet coupling unit 310. Pneumatic forming unit 320 to form a, and the air compressor 330 for supplying air to the pneumatic forming unit 320.

Bullet coupling portion 310 is provided in a hollow cylindrical shape, the test bullet (A) is coupled to the inside. A metal plate 311 is provided inside the bullet coupling part 310 and is coupled to a magnet (not shown) inserted into the test bullet A by magnetic force. The plate surface of the metal plate 311 is provided with an air supply hole (311a) for supplying or suctioning air so that the test bullet A is thrown toward the support 200 by pneumatic pressure.

The bullet coupling portion 310 is provided with air through the pneumatic forming portion 320 in a state in which airtight is maintained when the test bullet A is coupled to the metal plate 311, so that pneumatic pressure is formed. Depending on the size of the pneumatic pressure, the initial speed at which the test bullet A is thrown can be adjusted.

The pneumatic forming unit 320 supplies air to the bullet coupling unit 310 so that a pneumatic pressure is formed between the bullet coupling unit 310 and the test bullet A. The pneumatic forming unit 320 supplies air to correspond to the pressure set in the control unit 700. After the set pressure is formed, when a test measurement signal is input, the air pressure is momentarily removed so that the test bullet A is dropped from the bullet coupling part 310 and thrown toward the support 200. The larger the pneumatic size, the greater the initial velocity thrown.

The air compressor 330 is coupled to the pneumatic forming unit 320 to supply compressed air.

Speed measurement unit 400 is provided in the horizontal direction spaced apart from the pneumatic forming unit 320 to measure the speed of the test bullet (A) thrown from the pneumatic forming unit 320. The speed measuring unit 400 is provided with a first speed sensor 410 and a second speed sensor 420 provided to be spaced apart from each other by a predetermined interval. The first speed sensor 410 is provided on one side of the bullet coupling unit 310 to measure the initial speed of the test bullet (A), the second speed sensor 420 is provided on the support 200 side test bullet ( Measure the final speed of A).

Bulletproof performance of the material to be measured (B) is measured based on the initial speed and the final speed measured in the speed measuring unit 400 and the degree of damage to the surface of the material to be measured (B).

The first speed sensor 410 and the second speed sensor 420 are each coupled on a semi-circular frame. The first speed sensor 410 and the second speed sensor 420 are provided to enable position adjustment with respect to the horizontal frame 130. Accordingly, the spacing can be adjusted.

The control unit 700 controls the position of the frame unit 100 and the pneumatic pressure of the pneumatic forming unit 320. In addition, the speed measured by the measurement unit 400 stores. The control unit 700 adjusts the frame unit 100 so that the supporter 200 can be disposed at a position where a measurer is input through an input unit (not shown). In addition, by controlling the air compressor 330 and the pneumatic forming unit 320 so that the set pneumatic pressure is formed. And, bulletproof performance measurement test is performed accurately according to the input signal.

One side of the control unit 700 is provided with a monitor (not shown) to allow the measurer to monitor the position and pressure value of the current support 200, the speed of the test bullet A, and the like.

The use process of the ballistic resistance measuring apparatus 1 of the anti-ballistic material according to the present invention having such a configuration will be described with reference to FIGS.

The measurer loads the measurement target material B to measure the ballistic performance on the support 200. At this time, the fixing band 230 may be provided on the support 200 to fix the position of the material to be measured (B). Then, the coordinate value is input through an input unit (not shown) to adjust the position of the support 200. The support 200 is moved along the Z-axis feed rail 111 and the Y-axis feed rail 113 to correspond to the input coordinate value.

When the preparation of the material to be measured (B) is completed, the measurer combines the test bullet (A) to the bullet coupling unit (310). The test bullet A is fixed inside the bullet coupling part 310 by a magnet inside the test bullet A. When the fixing of the test bullet A is completed, the measurer inputs a pneumatic formation signal, and pneumatic pressure is formed between the test bullet A and the bullet coupling unit 310 under the control of the controller 700.

When the set air pressure is established, the operator inputs a test start signal. When the test start signal is input, the air pressure disappears instantaneously and the test bullet A is separated from the bullet coupling part 310 and thrown out. With the throwing of the test bullet A, the first speed sensor 410 and the second speed sensor 420 measure the speed of the test bullet A.

The test bullet A is thrown onto the material under test B, and the surface of the material under test B and the supporting member C is damaged by the impact of the collision of the test bullet A. Measuring the degree of tearing or puncture of the material to be measured (B), the degree of sliding and deformation of the support member (C), the speed measured by the first speed sensor 410 and the second speed sensor 420, and a test bullet Finally, the ballistic performance of the material under test (B) is measured in consideration of the amount of impact due to the weight of (A).

This antiballistic performance is repeatedly performed under the same test conditions for the same material under test (B) to provide reliable results.

As described above, the apparatus for measuring the anti-ballistic material according to the present invention throws a test bullet in a horizontal direction and collides with the material to be measured, and measures the performance result based thereon. This allows safe and accurate performance test results to be measured.

In addition, the anti-ballistic performance measurement apparatus according to the present invention is thrown in a state in which the initial speed is controlled by the pneumatic pressure to improve the reliability of the test and can be easily performed.

In addition, since the position and the pneumatic pressure of the support by the control unit may be repeated test in a variety of test conditions.

The embodiment of the bulletproof performance measuring device of the anti-ballistic material of the present invention described above is merely exemplary, and those skilled in the art to which the present invention belongs to various modifications and equivalent other embodiments are possible. You can see the point well. Therefore, it is to be understood that the present invention is not limited to the above-described embodiments. Therefore, the true technical protection scope of the present invention will be defined by the technical spirit of the appended claims. It is also to be understood that the invention includes all modifications, equivalents, and alternatives falling within the spirit and scope of the invention as defined by the appended claims.

1: Bulletproof performance measuring device 100: Frame part
110: support frame 111: Z-axis feed rail
113: Y-axis feed rail 120: Support leg
130: horizontal frame 140: bonding plate
160: control unit support frame 200: support
210: Y axis feed shaft 220: guide plate
300: bullet throwing unit 310: bullet coupling unit
320: pneumatic forming unit 330: air compressor
400: speed measuring unit 410: first speed sensor
420: second speed sensor 600: bullet
700:

Claims (2)

In the ballistic resistance measuring apparatus of the bulletproof material,
A support provided in a direction perpendicular to the ground and on which an object to be measured is placed on an upper surface thereof;
A frame part which supports the support so as to be movable in the Y-axis and Z-axis directions;
A bullet throwing unit positioned to be spaced apart in a horizontal direction with respect to the support and throwing a test bullet therein into the support horizontally by pneumatic;
A speed measuring unit measuring a speed of the test bullet thrown by the bullet throwing unit to the support unit;
And a control unit for controlling the position of the frame unit, whether the bullet throwing unit is supplied, and the throwing speed.
The method of claim 1,
The bullet supply unit,
A bullet coupling unit for detachably coupling the test bullet by pneumatic and magnetic force;
Pneumatic forming unit for forming a pneumatic pressure in the bullet coupling portion to couple or leave the test bullet to the bullet coupling portion;
Bulletproof performance measuring device of the bulletproof material, characterized in that it comprises an air compressor connected to the pneumatic forming unit.

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