DE3029725A1 - Pressure gas operated gun - has rotary firing valve with plug turning in complementary seat - Google Patents

Abstract

The gun is operated by gas under pressure, having a tube accommodating the missile to be fired, together with a gas pressure chamber with inlet valve from the supply, and a firing valve connecting it to the rear end of the tube. The firing valve (6) is of the rotary type, with a plug (10) turning in a complementary seat (11). It can be so coupled to the inlet valve that the latter shuts immediately before it opens, either electrically or mechanically. The inlet valve can be of the solenoid type. Alternatively, the two valves can be combined into a single three-way one.

Description

The Secretary of State for Defense in Her Britannic

Majesty's Government of the United Kingdom of Great Britain and Northern Ireland, Whitehall, London SW1A 2MB, England Pressurized gas shooting device The invention relates to a pressurized gas firing device according to the preamble of claim 1.

The field of application of the invention includes ballistic tests and in particular the ballistic examination of protective clothing, such as Protective goggles, lielmen and: test.

In the traditional method of ballistic inspection of protective clothing the test object to be tested is shot at with live ammunition. This well-known However, the method has numerous disadvantages. On the one hand, a shooting range is required, and there must be those associated with the handling and storage of armed @unition Risks are accepted.

On the other hand it is necessary to vary the projectile velocities, the cartridge cases with variable, each removed, known propulsion ranks to fill, which is usually done by hand. The well-known investigation method using live ammunition is therefore expensive, inconvenient and time consuming.

From GB-PS 203 076 and GB-PS 713 044 as well as in a different design from GR-PS 525 065 and GR-PS 552 055 shit devices are already known from which projectiles can be shot with the help of compressed gas. With these known shooting devices, however, cannot handle the very high projectile speeds reach (namely in general several hundred or even several thousand meters per second) required for ballistic tests and the known ones Shooting devices also do not offer the possibility of precise variation of Gas pressure and the projectile velocity.

It is also known from US Pat. No. 3,662,729 and US Pat. No. 3,680,540, Baseball balls and golf balls using pressurized gas ball throwing machines at known speeds eject from thrown pipes. The gas presses into the pressurized gas chambers from the just Known ball throwing machines can be controlled, but the available pressure range is only between about .7 bar and 15 bar. As a result are also -the valves of these ball throwing machines, through which the compressed gas from the Compressed gas chamber is passed into the throwing tube and used as a flap or ball valve or are designed as a piston valve, for these relatively low pressures designed and therefore fundamentally unsuitable for use in ballistic Experimental devices in which the shooting valve pressures up to about 140 bar or even more be able to withstand it and still seal, but must open quickly.

The invention is therefore based on the object of a shooting device To develop the type mentioned at the beginning, the shooting of projectiles a wide Range of projectile velocities up to at least 50 m / s suitable is without the numerous security problems and other difficulties inherent in Purchase to have been taken that associated with the use of sharp tuners are.

This Aufhabe is according to the invention by the in the characterizing Part of claim 1 specified arrangement solved.

The inlet valve is preferably coupled to the shut-off valve in such a way that that the closing of the inlet valve just before the opening of the shut-off valve he follows. This can be through electrical coupling or mechanical coupling or thereby take place that inlet valve and shut-off valve to a single three-way slide with each other be combined. The inlet valve can be used as a rotary slide valve or in another Eauart be designed, for example, as an electromagnetic valve.

The rotary slide valve plug can be cylindrical, spherical or preferably be conical. It has surprisingly turned out that a rotary valve Executed shooting valve is able to transfer the pressurized gas charge from the compressed gas chamber in the tube in the essential instantly and without causing any significant pressure drop during the opening phase. Also works it very quickly even at very high gas pressures. Presumably this is based on one Gas bearing effect of the compressed gas between the rotary valve plug and the seat.

The compressed gas chamber is made of a material that corresponds to the im Has the required strength in view of the nayimal gas pressure. In the case of very high gas pressures (above about 100 bar) stainless steel is used as the carrier to be preferred for the pressurized gas chamber, although other suitable metals are also possible or alloys are available. If only relatively low gas pressures are used, the compressed gas chamber can also be made of reinforced plastic material are made.

The tube can be made from any of the commonly used materials exist. The preferred material is steel, but other metals can also be used, Alloys or proven plastic materials of suitable strength are used. The bore of the pipe can be smooth or drawn. When the pipe is pulled, there is a certain minimum gas pressure in the compressed gas chamber to shoot the Floor required, which depends on the depth of the pipe runs.

The shooting rotary valve plug is preferably strong in the direction of it Open position biased, including suitable biasing means, for example one or renrere feathers, serve. The valve plug must then be used to close the shut-off valve Ent-Leen by means of a suitable actuator, for example a fog the preload force can be rotated until the bore of the rotary valve plug out of congruence come with the associated connection opening to the compressed gas chamber and / or to the pipe is. The shooting valve is activated either by hand or by means of a suitable interlock held in its cocked closed position.

When released, the rotary valve plug then rotates under the effect the preload force automatically returns to its open position, in which the compressed gas chamber and the barrel are in communication with each other, the muzzle velocity of the projectile depends on the acceleration of the projectile in the barrel and on the length of the barrel within the limits of the product (pressure x cross section) that is required, and the Overcome friction in the pipe. The initial acceleration A is given by the equation A? a where #P is the excess gas pressure above the outer Air pressure, a is the effective floor cross-sectional area (or the light cross-sectional area of the tube) and M is the projectile mass.

For a given bullet weight and tube length, so the floor speed with #P and with a to. In the area of application of the Shooting device according to the invention have the projectiles used in general only small cross-sectional areas a, which means correspondingly low projectile accelerations and projectile velocities. By the method known per se the placing of the projectiles on sabot leaves the effective projectile cross-sectional area increase and so under other given conditions a greater acceleration and muzzle velocity. However, by properties of the used Gases, especially the gas elasticity, a theoretical upper limit speed given. Accordingly, when using air as the pressurized gas, the practically achievable maximum speed is 310 m / s, while more elastic gases, such as helium, have speeds can reach up to about 1000 / s. Flammable or explosive gases are a matter of course to avoid. The actual gas pressure used in each case depends on the required Velocity from and can for example in the range of about 7 bar to 140 bar vary, but mainly in the range from about 35 bar to 140 bar is to achieve projectile velocities i @ range of about 250 m / s to 530 m / s.

It follows that the compressed gas chamber of the shooting device according to the invention consist of a @ material @ uss, the gas pressures in the mentioned range of about Withstands 7 bar to 140 bar.

The dimensions of the shooting device according to the invention are less critical, should, however, be chosen so that the pressure drop and consequently the loss of acceleration are as small as possible during the acceleration phase of the projectile in the barrel.

The volume of the compressed gas chamber should therefore be large compared to Be pipe volume. In addition, the tube should be long enough to accommodate the projectile can be accelerated to an equilibrium speed. Since the projectile mass with the third power of its linear expansion increases, while that of the compressed gas loaded cross-sectional area only increases with the square of the linear dimension, requires an increase in bullet size (i.e. barrel caliber) to achieve the same projectile velocity not only a larger compressed gas chamber, but also a higher gas pressure. To achieve maximum efficiency should therefore the tube diameter should preferably be below about 10 mm.

It goes without saying that there should be facilities for washing and control of the gas pressure be provided in the compressed gas chamber. The compressed gas can with the help conventional devices are introduced into the compressed gas chamber, for example from gas bottles or other pressurized gas containers equipped with a pressure control valve are, or directly from a compressor that has an automatic cut-off switch is provided to regulate the gas pressure reached.

The pressurized gas shooting device according to the invention is particularly united for ballistic examination of objects that are designed to fly Unfold bullets, and especially for protective clothing. The invention £ enc: ße Shooting device is suitable for series of ballistic tests on protective clothing, at which projectiles one after the other, each with a slightly increased muzzle velocity be shot at the test object.

This gradual increase in the speed of the projectile can be in the shooting device according to the invention easily by controlling the gas pressure in the Achieve compressed gas chamber in such a way that the gas pressure built up in the compressed gas chamber with each subsequent shot something compared to the gas pressure in the previous sight is increased. They can also be used for a ballistic examination of Protective clothing required projectile speeds in the range of more than approximately Easily reach 300 m / s with the shooting type according to the invention. Of course the shooting device according to the invention is equally suitable for routine fire resistance tests at constant projectile speed.

The pressurized gas shooting device according to the invention is, however, in terms of its Area of application does not apply to ballistic examinations of objects by shooting of bullets on the test object to determine the penetration depth of the bullets limited to the test object. Rather, the strength of the bullet itself can also be to be examined. Dic-s can be done by moving the projectile at a known speed Shot against an impenetrable hard surface and then in a suitable position Way the deformation of the projectile caused by the impact is measured.

An embodiment of the invention is hereinafter referred to described in detail on the attached drawings. It shows: Fig. 1 A longitudinal section through a pressurized gas shooting device according to the invention, Fig. 2 the Shooting device according to FIG. 1 in side view, and 3 shows the shooting device in an experimental shooting range.

According to FIG. 1, the shooting device has a cylindrical compressed gas chamber 1 with a steel jacket wall 2 and a steel rear wall 3, in which a gas inlet pipe 4 opens. At the front is the pressurized gas chamber through the rear wall 5 of a shooting valve 6 designed as a rotary slide valve. The matel wall 2 and the rear wall 3 of the compressed gas chamber 1 are each made using a suitable, firmly setting sealant attached to the shut-off valve 6 with the help of screws 7, each through the chamber rear wall 3 and along the outside of the jacket wall 2 and are screwed into the rear wall 5 of the shooting valve 6.

The front wall 8 of the shooting valve has a threaded hole: provided for receiving a tube 9. The shut-off valve 6 is a conical rotary valve plug 10, which is rotatably seated in a complementary seat 11. There is a rotary valve plug 10 is provided with a radial through hole 12, through which two each other opposing openings 13 and 14 in the opposing wall areas 15 and 16 of the valve seat connectable are those with the compressed gas chamber 1 or the bore 17 of the tube 9 are in communication. A projectile to be shot 18 is provided with a sabot 19, pushed into the BohrunÖ 17 of the tube 9.

About a steel thrust bearing 20, which is attached to one by means of screws 22 aii valve housing of the shut-off valve attached pressure plate 21 rests, is the rotary valve plug 10 held in full contact with the complementary seat 11. The size of the contact pressure of the rotary valve plug 10 on the seat can be varied, either by tightening the screws 22 to a greater or lesser extent or by placing documents between the valve housing and the pressure plate 21. The thrust bearing 20 can be supplied with lubricant through a grease nipple 23.

The rotary valve plug 10 can be rotated by means of a trigger lever 24 be, the one formed at the free end of the rotary valve plug cylindrical Approach 25 is attached. Above the firing lever 24 is a clamping lever 25 on the cylindrical Approach 25 of the rotary valve plug rotatably attached and by means of a nut 27 held.

Fig. 2 shows the compressed gas chamber 1, the shooting valve 6 and the ear 9 in side view. The shooting lever 24 has a rotatable upper Part 30 in which a slot 31 is formed and one thereon by a hinge joint hinged, non-rotatable part 32 on which a steel cross bar 33 two springs 34 are attached, which the rotary valve plug in its open position preload. The tensioning lever 26 carries a metal one under tension Wedge, which can be brought into engagement with the slot 31 of the firing lever 24 and with the help a trigger mechanism 35 can be pulled out of the slot 31.

The shooting valve 6 can thus be closed in that the clamping lever 26 brought into engagement with the firing lever 24 and then the firing lever by means of the The clamping lever is rotated against the bias caused by the springs 34. The two levers are in the tensioned position by means of a locking element 35 lockable, the springs 34 being under tension.

In the cocked position, the firing lever 24 actuates a microswitch 37, which then opens an electromagnetic inlet valve 38 in the gas inlet line 4.

When the firing lever 24 is released from its cocked position, it closes which then no longer operated Microswitch 37 the electromagnetic Inlet valve 38. In this way, the compressed gas chamber 1 only becomes immediately disconnected from the source of pressurized gas before opening the shooting valve 6, if the shooting lever 24 is rotated back into its rest position due to its bias.

A shock absorber 39 prevents the firing lever 24 after the Release from its clamping position by turning it beyond its rest position.

Fi6 '. 3 shows an experimental shooting range with a pressurized gas cylinder 4, with a pressure control valve 41 and a pressure gauge indicating the outlet pressure 42 is equipped. Another manometer 43 for pressure monitoring is between the inlet valve 38 and the compressed gas chamber 1 connected. The shooting device is firmly mounted on a wooden frame 44 and the tube 9 points to a target 45 in a shooting range 46.

ink rear wall 47 made of wood or other energy-absorbing material Material intercepts projectiles that penetrate target 45. Light barriers with Photo elements 48 enable the projectile velocity to be measured at the Traverse the shooting range 46.

The pressure regulating valve 41 of the compressed gas cylinder 40 is used adjusted so that the nanometer 42 has a predetermined required outlet pressure indicates.

a projectile 18 is provided with a sabot 19 and into the The rear end of the tube 9 is then inserted2 into the receiving thread in the shooting valve 6 is screwed in. Now the clamping lever 26 is first pivoted forward and brought into engagement with the firing lever 24 and then back into the Tightened position pulled, the shooting valve 6 closed and the microswitch 37 actuated and consequently the inlet valve 38 is opened. When the pressure gauge 43 that the required pressure has been reached in the compressed gas chamber (which is the general takes place after less than 1 s), the trigger 35 is pulled, causing the firing lever 24 released and swung back quickly due to the tension of the springs 34 w rd, whereby the actuation of the microswitch 37 first stops and this the Inlet valve 38 closes and then the shut-off valve 6 is opened immediately thereafter and the projectile is launched. The cycle just described can then be repeated will.

Of course, other gas supply devices and others can also be used preferably automatic charging devices are used.

The following examples show those using the shooting device described above Results achieved according to the invention: Example 1: A compressed gas chamber with a Volume of 200 was filled with helium up to a pressure of 50 bar. am sabot made of reinforced plastic with a diameter of 7.62 mm with a metal bullet of the weight 1 g was then inserted into the rear end of a 660 mm long tube of the alibers 7.62 mm inserted. When firing, there was a projectile velocity of 300 m / s.

Example 2: With otherwise the same conditions as in the example 1 the gas pressure of the helium in the compressed gas chamber was increased to 105 bar. At the When it was fired, the projectile speed was 460 m / s.

Example 3: The same conditions were applied as in Example 2 with the exception that instead of helium, air is now used as the compressed gas became.

The projectile speed was 310 m / s.

Example 4: A pressurized gas chamber with a volume of 200 cm³ was Filled to a pressure of T, 6 bar. in a metal bullet with a diameter of 6 mm inserted into the rear end of a tube with a smooth bore of 6.5 mm diameter. When fired, the projectile velocity was between 100 m / s and 120 m / s. Blank page

Claims (12)

Claims 1. Pressurized gas shooting device with a tube for receiving and for launching a projectile, further with a pressurized gas chamber, which has an inlet valve is assigned to the introduction of pressurized gas, and with a shut-off valve, by means of which the compressed gas chamber can be connected to the rear end of the tube, characterized in that that the shooting valve (6) as a rotary valve with one in a complementary seat (11) rotatable slide plug (10) is formed. 2. Pressurized gas shooting device according to claim 1, characterized in that the inlet valve (38) is coupled to the shooting rotary valve (63) that the Close the inlet valve immediately before opening the rotary slide valve he follows. 3. Compressed gas shooting device according to claim 2, characterized in that that the inlet valve (38) and the shooting rotary slide valve (6) electrically with one another are coupled. 4. Compressed gas shooting device according to claim 2, characterized in that that the inlet valve and the SchieR rotary valve are mechanically coupled to one another are. 5. Pressurized gas shooting device according to one of claims 1 to 4, characterized characterized in that the inlet valve (38) is an electromagnetic valve. 6. Pressurized gas shooting device according to one of claims 1 to 4, characterized characterized in that inlet valve and rotary slide valve in the form of a three-way rotary valve are combined with each other. T 7 * compressed gas shooting device according to one of claims 1 to 6, characterized characterized in that the shooting rotary slide valve (10) is iconic. 8. Pressurized gas shooting device according to one of claims 1 to 7, characterized characterized in that the shooting rotary valve plug (10) in the direction of its the compressed gas chamber (1) is biased to the open position connecting the rear end of the pipe 9. Pressurized gas gun according to claim 8, characterized in that for prestressing the rotary slide valve plug (10) at least one spring (34) is provided. 10. Pressurized gas shooting device according to one of claims 1 to 9, characterized characterized in that the pressurized gas chamber (1) for a gas pressure in Range from 7 bar to 140 bar is designed. 11. Pressurized gas shooting device according to one of claims 1 to 10, characterized characterized in that the compressed gas chamber (1) is connected to a compressed gas source containing helium (40) is connected. 12. Experimental set-up for testing bulletproof clothing or objects, consisting of a pressurized gas shooting device according to one of claims 1 to 11, one Measuring device (48) for measuring the projectile speed and a holder for the test object to be shot at.