CN216977653U

CN216977653U - Pneumatic simulated shooting platform

Info

Publication number: CN216977653U
Application number: CN202220434633.3U
Authority: CN
Inventors: 伍世瑜
Original assignee: Guangdong Shengshi Hanwang Technology Co ltd
Current assignee: Guangdong Shengshi Hanwang Technology Co ltd
Priority date: 2022-03-02
Filing date: 2022-03-02
Publication date: 2022-07-15
Anticipated expiration: 2032-03-02

Abstract

The utility model discloses a pneumatic simulated shooting platform which comprises an air compressor cabinet and a high-pressure gas cylinder for storing compressed air, wherein the air compressor cabinet is communicated with a high-pressure gas cylinder through a first pipeline, the first pipeline is provided with a check valve, the high-pressure gas cylinder is communicated with a bullet magazine for placing a bullet through a second pipeline, the second pipeline is provided with an electromagnetic valve for controlling the second pipeline to be conducted or closed, and an outlet of the bullet magazine is provided with a chamber pipe for accelerating ejection of the bullet. The bullet shooting test device is simple in structure, compressed air is compressed to the high-pressure bottle through the air compressor cabinet, the compressed air is conveyed to the bullet supply bin through the pipeline to push the bullet to be shot out from the chamber pipe in an accelerating mode, bullet shooting is simulated to detect the bullet-proof device under the condition that firearms and ammunition do not need to be held, in addition, the speed of the bullet can be adjusted according to the pressure of the compressed air or the length of the chamber pipe, the speeds of various types of guns of bullets can be simulated, the application range is wide, and the test and research and development cost of the bullet-proof device is reduced.

Description

Pneumatic simulated shooting platform

Technical Field

The utility model relates to a simulated shooting device, in particular to a simulated device for propelling a simulated gun to shoot by using high-pressure gas.

Background

The bulletproof equipment is one of the modern common military and police equipment, can absorb and dissipate kinetic energy of a bullet and a fragment, prevent penetration and effectively protect the protected part of the human body of an attacker. With the development of the society and the promotion of the integration of military and civilian, more and more non-military and non-police companies and scientific research institutions develop the research and development and manufacturing of bulletproof equipment. But due to the national gun management regulation, non-military and non-police type companies and scientific research institutions cannot hold guns, and the performance of bulletproof equipment cannot be tested after the bulletproof equipment is developed; if the performance of developed bulletproof equipment needs to be tested, the products and equipment can only be transported to a military police unit for testing, or the products and equipment are transported to a unit with detection qualification for testing, and because the products and the equipment have large volume and heavy weight, the time of the research, development and production cycle is prolonged in the transportation process, and if the test fails, the products and the equipment are most likely to need to be transported back for reworking and adjustment, so that the cost of repeated inspection is greatly increased.

SUMMERY OF THE UTILITY MODEL

The utility model provides a high-pressure gas-propelled pneumatic simulated shooting platform which simulates the speed of a gun to test the performance of bulletproof equipment without holding a gun.

The pneumatic simulated shooting platform comprises an air compressor cabinet and a high-pressure gas cylinder for storing compressed air, wherein the air compressor cabinet is communicated with a high-pressure gas cylinder through a first pipeline, the first pipeline is provided with a check valve, the high-pressure gas cylinder is communicated with a bullet magazine for placing bullets through a second pipeline, the second pipeline is provided with an electromagnetic valve for controlling the second pipeline to be conducted or closed, and an outlet of the bullet magazine is provided with a chamber pipe for accelerating the bullets to be shot out.

The pneumatic simulated shooting platform compresses air through the matching of the air compressor cabinet and the check valve, stores the air in the high-pressure air bottle and the second pipeline from the electromagnetic valve to the high-pressure air bottle, can control the pressure intensity in the high-pressure air bottle, enables the high-pressure air bottle to have enough pressure intensity to release the compressed air instantly, and further enables the warhead to have enough initial velocity of instant firing; after the high-pressure gas cylinder releases the compressed air, the pressure inside the high-pressure gas cylinder keeps balance with the outside, the condition of continuous bullet cannot occur, and the operation safety is improved; the second pipeline is conducted or closed through the electromagnetic valve, compressed air is released instantly to enter the bullet supply bin, the bullet placed in the bullet supply bin is pushed to accelerate and eject in the bore tube, and bullet shooting is simulated to detect bulletproof equipment under the condition that firearms and ammunition do not need to be held; meanwhile, the speed of the bullet can be adjusted according to the pressure of compressed air or the length of the bore tube, the speed of bullets of various gun types can be simulated, the application range is wide, and the testing and research and development cost of the bulletproof equipment is reduced.

Drawings

Fig. 1 is a schematic structural diagram of a pneumatic simulated shooting platform.

Fig. 2 is a partially enlarged view of a portion a in fig. 1 when the bullet is put in.

Fig. 3 is a partially enlarged view of a portion a of fig. 1 when the bullet is pushed.

Detailed Description

As shown in fig. 1-3, a pneumatic simulated shooting platform, includes pneumatics rack 1 and the high-pressure gas cylinder 2 of storing compressed air, the pneumatics rack is through first pipeline 3 and high-pressure cylinder intercommunication, first pipeline is provided with check valve 4, high-pressure cylinder supplies magazine 6 intercommunication through second pipeline 5 and the warhead of placing the warhead, the second pipeline is provided with control second pipeline and switches on or closed solenoid valve 7, and the export that the warhead supplied the magazine is provided with the bore pipe 8 that is used for the warhead to jet out with higher speed. The pneumatic simulated shooting platform compresses air through the matching of the air compressor cabinet and the check valve, stores the air in the high-pressure air bottle and the second pipeline from the electromagnetic valve to the high-pressure air bottle, can control the pressure intensity in the high-pressure air bottle, enables the high-pressure air bottle to have enough pressure intensity to release the compressed air instantly, and further enables the warhead to have enough initial velocity of instant firing; after the high-pressure gas cylinder releases the compressed air, the pressure inside the high-pressure gas cylinder keeps balance with the outside, the condition of continuous bullet cannot occur, and the operation safety is improved; the second pipeline is conducted or closed through the electromagnetic valve, compressed air is released instantly to enter the bullet supply bin, the bullet placed in the bullet supply bin is pushed to accelerate and eject in the bore tube, and bullet shooting is simulated to detect bulletproof equipment under the condition that firearms and ammunition do not need to be held; meanwhile, the speed of the bullet can be adjusted according to the pressure of compressed air or the length of the bore tube, the speed of bullets of various gun types can be simulated, the application range is wide, and the testing and research and development cost of the bulletproof equipment is reduced.

The pressure value of the compressed gas of the high-pressure gas bottle is P_{Gas cylinder}(ii) a The cross section area of the inner cavity of the hearth tube is S_{Bore tube}The gas thrust is F, the length of the bore tube is L_{Bore tube}Warhead weight is M and warhead speed is V_{Spring speed}The gas volume of the high-pressure gas cylinder, the gas volume of the bore pipe and the gas volume of the pipeline from the electromagnetic valve to the high-pressure gas cylinder are respectively V_{Gas cylinder}；V_{Bore tube}；V_{Pipeline from electromagnetic valve to gas cylinder}. Thrust by gas: f = P × S; the gas does work: w = F × L; kinetic energy of warhead: ek = 1/2M V_{Spring speed} ²(ii) a Energy conversion: w = Ek available:

bullet discharging speed: v_{Spring speed}=

The friction force of the bullet in the bore tube and the influence of the heat generated by the friction bore tube on the air pressure are also caused; the influence of gas temperature reduction on the gas pressure caused by heat absorption when the compressed gas expands rapidly; the gas can not do work uniformly in the process of expanding to push the warhead to move, and the acceleration is gradually reduced.

Under the condition that the requirements of the cross section area of the inner cavity of the bore tube, the cross section area S of the bullet, the weight M of the bullet and the bore discharge speed V are determined, the influence of the factors on the bore discharge speed V is met by adjusting the gas pressure P and the length of the bore tube L.

The pressure intensity adopts the arithmetic mean value of the initial air pressure value of the air bottle and the pressure intensity before the bullet is taken out of the chamber:

pwave =1/2 [ P ]_{Gas cylinder}+P_{Gas cylinder}*V_{Gas cylinder}/（V_{Gas cylinder}+V_{Bore tube}+V_{Pipeline from electromagnetic valve to gas cylinder}）】

Correcting the bore exit speed of the bullet:

the discharging speed: v_{Spring speed}=

The first conduit is in communication with a second conduit. The opening of the high-pressure gas cylinder can be reduced, and the risk of leakage of compressed air from the opening is reduced.

The second pipeline is further provided with an air pressure sensor 9 and an air pressure meter 10, and the air pressure sensor is further in communication connection with the air compressor cabinet. When the experiment, the pressure of compressed air is observed to the accessible barometer to the operation of control air compressor rack, and then the speed of control warhead, baroceptor can detect compressed air's pressure value, returns the air compressor machine to the pressure value, reaches the setting value, and the air compressor machine realizes stopping operation by oneself.

And an inlet for placing the bullet and a plug 11 for sealing the inlet are arranged above the bullet magazine. The bullet is convenient for put into in the entry that the top of bullet confession magazine set up, and the stopper can seal the entry, prevents that compressed air from revealing or preventing that the bullet from popping out.

The pipe diameter of bullet supply magazine is slightly greater than the pipe diameter of bore pipe, the pipe diameter of bore pipe is still slightly greater than the diameter of bullet. The pipe diameter of warhead confession magazine is slightly greater than the pipe diameter of bore pipe, because warhead front end is circular-arc, consequently can be convenient push into the bore pipe with warhead direction, because the pipe diameter of bore pipe slightly is greater than the diameter of warhead again, avoids the pipe diameter of bore pipe too big and reveals compressed air, also avoids the pipe diameter undersize of bore pipe and blocks the warhead and jet out.

Still including the anchor clamps 13 of fixed thorax pipe, anchor clamps can set up a plurality ofly, and anchor clamps can not only play the fixed action of location to the thorax pipe from upper and lower, all directions about, can also prevent when the experiment that the thorax pipe from taking place vibrations, have guaranteed the accuracy of experiment.

The support cushion is arranged below the bore tube and can be provided with a plurality of support cushions, so that the support cushion not only plays a role of supporting the bore tube, but also can maintain the levelness of the bore tube and prevent the bore tube from deforming.

The supporting pad sets up between two anchor clamps, can further cushion the rifling pipe section between two anchor clamps, prevents to shake.

Still include brace table 14, bore pipe and warhead supply magazine setting are on the mesa, and pneumatics rack and high atmospheric pressure bottle setting are under the mesa, and the brace table of setting is favorable to installing bore pipe and warhead supply magazine according to the laboratory. The placing table is also provided with an electromagnetic valve switch 15 for controlling the electromagnetic valve to act and a high-pressure air source switch 16 for controlling the air compressor cabinet to act.

Claims

1. The utility model provides a pneumatic simulation shooting platform, its characterized in that, includes pneumatics rack (1) and stores compressed air's gas cylinder (2), the pneumatics rack is through first pipeline (3) and high-pressure cylinder intercommunication, first pipeline is provided with check valve (4), high-pressure cylinder supplies magazine (6) intercommunication through second pipeline (5) and the warhead of placing the warhead, the second pipeline is provided with control second pipeline and switches on or closed solenoid valve (7), and the export that the warhead supplied the magazine is provided with bore pipe (8) that are used for the warhead to jet out with higher speed.

2. A pneumatic simulated shooting platform as claimed in claim 1 wherein said second conduit is further provided with an air pressure sensor (9) and an air pressure gauge (10), said air pressure sensor being further in communicative connection with an air compressor cabinet.

3. A pneumatic simulated shooting platform as claimed in claim 1 wherein the bullet magazine is provided with an entry for the bullet and a plug (11) to seal the entry above the bullet magazine.

4. A pneumatic simulated shooting platform as claimed in claim 3 wherein the magazine of ammunition heads has a bore diameter slightly larger than the bore diameter of the bore tube, which is also slightly larger than the diameter of the ammunition heads.

5. A pneumatic simulated shooting platform as claimed in claim 1 further comprising a cartridge (13) to which the bore tube is secured.

6. An aerodynamic simulated shooting platform as claimed in claim 5 further comprising a support pad (12) to be cushioned below the bore tube, said support pad being disposed between the two clamps.