KR101658565B1 - Inert ammunition collecting equipment and launch position - Google Patents

Abstract

A suggested technology relates to an inert ammunition collection facility, and a launching position. More specifically, the present invention relates to the collection facility which can collect inert ammunition of a medium caliber and a large caliber. The collection facility comprises: a canon fixed artillery; a towed howitzer; the launching position having a movable crane (gantry type); a sand storage tank; and a small ammunition collector.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a non-

The present invention relates to a non-activated carbon recovery facility and a firing site, and more particularly, to a firing site, a sand storage tank, and a small-sized bobbin, in which a fixed war machine for towing and a towing howitzer and a movable (gantry type) , And a recovery facility capable of recovering medium and large diameter non-activated carbon.

At the test site where ammunition and ammunition tests are carried out, it is necessary to introduce a wide range of near and far maritime maritime activities, since the shooting is performed using the sea as an impact point. However, since it is physically almost impossible to secure maritime conditions without fishing vessels, the test was conducted by selecting the weather in which the wind without the fishing vessels was severely blowing, resulting in frequent test delays. In addition to the production disruption caused by the armed producers, the test delay may lead to the production disruption of the system assembler assembling the self-propelled self-propelled system.

Also, the acceptance test of the armament assembly has always been concerned about the safety problem due to the weight assembly, the work time and the space problem in the operation of the external crane according to the arm replacement before and after the test.

In order to remedy these difficulties, we have set up a carbon recovery facility and launch site for inactive ammunition and armament tests on land, rather than on the offshore.

As shown in Fig. 1, domestic and overseas guns and ammunition test sites have self-test sites that utilize a carbon recovery facility to carry out small-caliber ammunition tests, but they do not have facilities capable of recovering medium and large diameter non-activated carbon Has been confirmed. This is because there are many difficulties in constructing facilities capable of recovering medium and large diameter non-activated carbon.

United States Patent No. 5456155

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems, and an object of the present invention is to establish a medium and large diameter non-activated carbon recovery facility and launch site on the land.

In order to minimize the damage caused by the shooting, a fixed carriage for 155mm and 120mm was placed at the center of the launching area, and a fixed carriage was placed at the front for 105mm, 155mm. It is also intended to arrange a mobile crane and to secure a space in which the test subject can wait on the rear surface of the stationary can.

The recovery facility is equipped with a small borehole and a sand storage tank to provide a non-activated carbon recovery facility and launch site that minimizes the impact on test personnel, test equipment, and specimens due to scattering of dust and small stones during firing There is a purpose.

A composite type fixed mount provided at the center of the ball stud and an anvil mounted on the fixed mount may be provided with another fixed mount on one side of the fixed mount, A rail for a crane is installed so that a movable gantry crane can be used on both sides of the fixed mount and can be loaded with a loading arm installed next to the long arm. The rail for a crane is installed in front of the fixed mount and is not subject to interference from the movable gantry cranes The location is characterized by a launch site in which the towing howitzer sites are installed.

A ventilation chimney as an air purification device is installed in the ceiling and a sand storage tank is installed in the rear side ceiling, the sand storage tank is a sloping hopper type tank, A sand supply device connected to the inside of the recovery facility is installed at the bottom of the sand storage tank, a rear wall is reinforced by H beams and rocks, and a small-sized bobbin is installed in the inside of the sand storage tank.

A slant surface is provided between the firing site and the collection facility in consideration of the distance of fragments generated in the collection facility, the bottom surface of the slanting surface is horizontal, and the width of the slanting surface is And a road capable of running the vehicle is installed at the center of the slanting surface.

According to the present invention, it is possible to construct a system capable of performing an efficient test in the thermal power test site, thereby making it possible to appropriately perform the acceptance test, to solve the safety problem in heavy material work due to the mobile crane operation, It becomes.

Therefore, it is possible to reduce test costs by reducing the cost of borrowing from external cranes, strengthening defense capability by timely delivery of defense materials, and improving test capability and efficiency.

1 is a conventional carbon recovery facility.
FIG. 2 is a view showing the structure of a non-activated carbon recovery facility and a fire source according to the present invention. FIG.
3 is a view showing the launching position according to the present invention;
4 is a firing-position movable crane according to the present invention.
Figure 5 is a firing depth reef structure according to the present invention.
Fig. 6 is a front view of the recovery facility according to the present invention. Fig.
7 is a side view of the recovery facility according to the present invention.
FIG. 8 is a schematic view of a small-sized bullet receiving apparatus according to the present invention; FIG.
9 is a rear view of the inside of the recovery facility according to the present invention.

BRIEF DESCRIPTION OF THE DRAWINGS The above and other features and advantages of the present invention will become more apparent from the following detailed description of the present invention when taken in conjunction with the accompanying drawings, It will be possible. The present invention is capable of various modifications and various forms, and specific embodiments are illustrated in the drawings and described in detail in the text. It is to be understood, however, that the invention is not intended to be limited to the particular forms disclosed, but on the contrary, is intended to cover all modifications, equivalents, and alternatives falling within the spirit and scope of the invention. The terminology used herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

In the present invention, a composite type fixed mount (4) installed at the center of the ball stud and an anvil are provided on the fixed mount (4), and another fixed mount (4) is installed on one side of the fixed mount And a loading arm 4 installed on the rear side of the fixed mount 4 so that the loading robot 4 can be loaded with the loading robot 4 mounted on the side of the long arm 11, A rail 8 for a crane is installed so as to use a movable gantry crane 4 on both sides thereof and at a position in front of the fixed mount 4 and not subject to the interference of the movable gantry crane 4, (10) in which the light source (3) is installed.

A plurality of square column beams 24 provided inside the door with the door openings and a ventilation chimney 23 as an air purification device are installed in the ceiling and a sand storage tank 21 is installed in the rear side ceiling, The bottom of the sand storage tank 21 is provided with a sand supply device 22 connected to the inside of the recovery facility 20 and the rear wall is provided with an H beam 25, And a recovery facility (20) reinforced by a rock (26), in which the small-sized bobbin (27) is installed.

FIG. 2 shows the non-activated carbon recovery facility and the launch site configuration according to the present invention.

All the facilities and the test system should be constructed considering the maximum sound pressure of 200 db generated in the launch site 10 and the high impact energy generated in the coal recovery facility 20. In the launch site 10, A stationary mount 4, and an enclosed environmental chamber 2 that can control humidity, temperature, pressure, fluid volume, noise, and motion to mimic various other environmental conditions.

The firing site 10 and the collection facility 20 are constructed on a lower terrain than the ground and the firing site 10 and the collection facility 20 are provided with fire fighting water supply facilities, Communication, and an intranet.

A down range 30 is provided between the firing site 10 and the collection facility 20 in consideration of the distance of fragments generated in the collection facility 20, The bottom surface of the sloping surface 30 is horizontally held so that the bullet can be drawn into the recovery facility, and the width of the sloping surface 30 can be set to a fire level. .

FIG. 3 illustrates a launch configuration according to the present invention.

In the same way as in the present invention, the acceptance test of the armed assembly of a large diameter canvas is to be replaced with a test specimen after the test. For this purpose, a vehicle type crane including a heavy object must be assembled and disassembled by lease.

The 155mm weapon is heavy in weight and long in length, so safety issues have always been a concern due to assembling, working time and space problems in the field, and there was a problem of lack of waiting space in the subject.

In order to solve this difficulty, a fixed mount (4) for medium and large diameter arresters is arranged at the center of the launching site, and a gantry crane (7) as a launching crane (10) And it is implemented to be able to replace the armed assembly and to be able to stand out after the test.

A rail (8) was installed at the bottom of the test site for the travel of the mobile crane (7) and a space for loading a large amount of medium and large canvas armed assemblies was secured.

In the launch site 10 of the present invention, a fixed type and moving type shooting test bed is provided to satisfy the test of various conditions.

In the fixed form, a plurality of fixed mounts 4 are installed at the center of the launching site so as to be connected to the intermediate plate 14 of the rechargeable substructure 12 shown in FIG. 5 by bolts. In order to minimize the damage caused by the shooting On the front of the fixed mount (4), a traction bobbin trunk (3) in the form of a movement is arranged.

A plurality of fixed mounts 4 may be provided and the self-contained levitation 5 and the electrostatic-charging levitation 6 may be provided. The diameter of the levitation provided on the fixed mount 4 is 120 mm and 155 mm, The bore for the howitzers (3) may be 105mm, 155mm.

FIG. 6 is a front view of the recovery facility according to the present invention, and FIG. 7 is a side view of the recovery facility according to the present invention.

The basic skeleton of the collection facility 20 is made of a concrete structure, and a material having high strength is used in order to maintain the safety when the fragments collide with each other.

The entrance to the recovery facility (20) was designed to facilitate access to and work on a work vehicle (dump, forklift, truck, etc.), and a hinged door was installed in consideration of secondary debris.

In order to protect the collection facility 20 by fragments, a steel plate was reinforced on the ceiling. In order to increase the safety of the structure and reduce scattering of the secondary fragment in the entrance direction, Respectively.

After the fire test, a ventilation chimney (23), which is an air purifier, is installed on the ceiling of the recovery facility to remove soot and dust from heavy equipment between sand replacement operations.

In addition, a hopper type sand storage tank 21 having a roof on the upper part of the structure is constructed to supply sand. A sand supply device (22) is provided under the sand storage tank (21) to supply sand into the collection facility.

FIG. 8 shows a collecting facility small bobbin according to the present invention.

The consumable small bobbin 27 made of iron is installed in the recovery facility 20 in consideration of the safety of the recovery facility 20. [

9 is a rear view of the inside of the recovery facility according to the present invention.

After the large H beams 25 are densely installed at the rear of the collection facility 20, the angles are welded in the transverse direction and the rocks 26 are filled in the rear of the H beams 25 to reinforce them.

While the present invention has been described in connection with what is presently considered to be practical and exemplary embodiments, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims.

10: Firing site 20: Collection facility
1: Control room 21: Sand storage tank
2: environmental chamber 22: sand feeder
3: Towing Howitzer area 23: Ventilation chimney
4: Fixed mount 24: Square beam
5: Self-inflating reward 25: H beam
6: Tank Injury Award 26: Rock
7: Removable crane 27:
8: Rail for crane 30: Down range
9: loading robot arm
11: Bowel progression
12: Substructure
13: Rotation center
14: Middle plate

Claims (7)

Composite fixed mount installed at the center of the balancer
The fixed mount is provided with an auger,
The other fixed mount may be installed on one side of the fixed mount,
A mounting bracket is provided on the rear surface of the fixed mount so as to be able to be loaded with a loading arm provided on the side of the long arm,
A rail for a crane is installed to use movable gantry cranes on both sides of the fixed mount,
A traction bobbin head is installed at a position in front of the fixed mount and not under the interference of the movable gantry crane,
A firing position in which an enclosed environmental chamber for controlling humidity, temperature, pressure, fluid volume and noise is installed to mimic the ambient environment;
The door with the hinged door,
A plurality of square column beams installed inside,
Ventilation chimneys, air purifiers, are installed on the ceiling,
A sand storage tank is installed in the rear ceiling, the sand storage tank is a sloping hopper type tank, and a sand supply device connected to the inside of the recovery facility is installed at the bottom of the sand storage tank,
The rear wall being reinforced with H beams and rocks, and a small-sized bobbin placed inside the rear wall;
Characterized in that the non-activated carbon recovery and firing position is characterized by the following: The method according to claim 1,
And a slanting surface between the firing site and the collection facility considering a range of fragments generated inside the collection facility,
The bottom surface of the oblique surface is kept horizontal, the width of the oblique surface is capable of installing a firearm, and a road capable of running the vehicle is installed at the center of the oblique surface
Characterized in that the non-activated carbon recovery and firing position is characterized by the following: The method according to claim 1,
Wherein the fixed mount is provided with a self-contained capsule and a tank-holding capsule. The method of claim 3,
Wherein the fixed mount is installable in a plurality of positions. The method according to claim 1,
Wherein the launch site and the collection facility are installed at a lower level than the ground. The method according to claim 1,
Wherein the rear wall of the collection facility is angled in the transverse direction after the H beam is installed and the rock is filled behind the H beam. The method according to claim 1,
Wherein the firing site and the collection facility are provided with fire fighting water, electric power, and communication.

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