FR2986610A1 - Release device for pneumatic launching device, has tube for launching projectile, push stopper provided for tube, where push stopper is arranged interdependent of projectile, and is linked with tube by releasable locking unit - Google Patents

Abstract

The device has a tube (10) for launching a projectile (9) i.e. rocket projectile. The projectile is powered out of gas e.g. air, compressed by a secondary container (6). A push stopper (51) is provided for the tube, where the push stopper is arranged interdependent of the projectile, and is linked with the tube by a releasable locking unit (43). The locking unit is arranged with an obstacle i.e. ball (52), that is placed in a drilling (54) of the tube. The locking unit comprises an end that engages against a surface of the locking unit.

Description

The technical field of the invention is that of rapid expansion devices for pneumatic projectile launching device. In order to propel projectiles without the use of pyrotechnic means, a well-known method is that of the blowgun where the rapid expansion of a volume of gas in a tube provides a pulse projecting the projectile out of the tube. Thus US2960977 discloses a pneumatic launcher having a primary reservoir of compressed gas connected to a secondary reservoir by a valve. The second reservoir contains the volume of compressed gas for projecting a projectile placed in a tube. The valve makes it possible to approximately adjust the gas pressure in the secondary tank according to the amount of energy that it is desired to blow the projectile. A means of rapid expansion of the gas from the secondary reservoir to the tube allows the triggering of the firing by means of a network of pipes. The pressure accumulated in the secondary tank must be able to be relaxed as quickly as possible during the firing. The flow of gas in the pipe network described above, which connects the secondary chamber to the relaxation means, generates considerable pressure losses due to the complexity of the path and section variations between the various ducts to the rear section. of the projectile. Mastering the accuracy of the amount of energy delivered to the projectile is critical to achieving the desired range especially for the practice of non-lethal shots that are generally conducted at close range. The previously described device adjusts the amount of energy (thus the scope of the projectile) by playing only on the pressure. To control the range it is necessary to precisely control the pressure in the secondary chamber, which is difficult to obtain. This may require the release of some of the pressure by venting if necessary to solve the problem of a possible excess pressure. This release involves a loss of energy. On the other hand the projectiles used may need to be armed by the initial impulse communicated at the start of the stroke. For safety reasons, this pulse must generally be greater than a threshold value, the pulses or shocks below the threshold must not cause the projectile to be armed. The device described by patent US2960977 proposes, when the ejection speed is too low, to use a manual arming device.

This device can not therefore deliver in all cases the pulse required for arming, in particular for short-range shots requiring low pressure. Finally, the accumulated pressure must be relaxed as quickly as possible when firing. The device described in US Pat. No. 2,609,777 imposes a circulation of gas in a pipeline network connecting the secondary chamber to the expansion means, which generates pressure losses due to the complexity of the path and the variations in section between the various pipes and the section. rear of the projectile. Thus, the object of the invention is to allow rapid expansion of the gases in order, in particular, to provide a sufficient pulse for the arming of a projectile rocket. The invention also has advantages: Significantly reduce propulsive energy losses. To allow a modification of the range without necessarily modifying the pointing of the weapon in elevation.

Thus, the invention comprises a rapid expansion device for a pneumatic launching device comprising a projectile lance tube fed with gas compressed by a reservoir, an expansion device characterized in that it comprises a means for closing the tube which is integral with the projectile and which can be connected to the tube by releasable locking means. According to a characteristic of the invention, the locking means comprises at least one obstacle disposed in a radial hole of the tube and having an end engaging against a surface of the closure means, which obstacle is held in the locking position by a sliding ring surrounding the tube. Advantageously, the ring has an internal groove in which the obstacle can be housed in the unlocked position. According to a feature of the invention, the ring is integral with a collar ring which slides on the tube and bears against a shoulder of the tube in the locking position, a spring being interposed between the ring and the shoulder for hold the ring in the lock position. The invention will be better understood on reading the following description, which description is made with reference to the accompanying drawings, in which: FIG. 1 represents an operating diagram of a pneumatic launching device. Figure 2 shows a longitudinal sectional view of a particular embodiment of a pneumatic launching device, incorporating a rapid expansion device according to the invention. FIG. 3 more precisely represents a view in longitudinal section of a tube of the launching device, the section simultaneously showing at its upper part a projectile at the station before firing and at its lower part a view at the time of firing. shooting. FIG. 4 represents a front view of the device according to the embodiment of FIG. 2. FIG. 5 represents a longitudinal sectional view of a particular embodiment of a plug interfaced with a projectile (plug shown before firing). ). Figure 6 shows a longitudinal sectional view of the same plug shown alone at the time of firing. According to FIG. 1, a pneumatic launch device 1 comprises a primary reservoir 2 intended to receive a compressed gas, preferentially air or carbon dioxide. The supply of this primary reservoir 1 is done by a compressor 3 coupled to a network 4 of gas distribution pipes within the device 1. The coupling is carried out according to a known method, for example via a coupling comprising an anti-flow valve. return 5 allowing the entry of the gas into the device and blocking the evacuation of the gas in the opposite direction. In order to fire, the compressed gas contained in the primary reservoir 1 is controlledly conveyed to a secondary reservoir 6. The control of the gas flow is effected with a first distributor 7 preventing or permitting the flow of gas in both directions between primary reservoir 2 and secondary reservoir 6. Following the first distributor 11 is a pressure reducer 8 for delivering a constant gas pressure to the secondary reservoir 6. A manometer 8b allows to to know the pressure accumulated in the secondary chamber 6. The secondary reservoir 6 comprises a cylindrical body 6a in which can slide a piston 6b integral with a rod 6c which exits the body 6a and on which one can act to adjust the piston stroke 6b. Depending on the position of the piston 6b in the cylindrical body 6a, the chamber 6d delimited by the body 6a and the piston 6b 5 will have a volume V more or less important. Other embodiments of the variable volume secondary reservoir 6 may be envisaged, for example by means of a membrane sphere whose volume is adapted by the injection of a liquid on one side of the membrane or else 10 by other solutions. At one end of the network 4 is a launching tube 10 containing a projectile 9. On the network 4, between the tube 10 and the reservoir 6 is a second distributor 11. This second distributor 11 constitutes in FIG. The opening of the distributor 11 thus causes the volume V of compressed gas contained in the chamber 6d of the secondary reservoir 6 to be expelled. This volume of gas V propels the projectile 9 towards the front AV The second distributor 11 shown here schematizes the operation of the pneumatic launching device 1. In accordance with the invention, this distributor 11 is replaced by a rapid expansion device allowing the opening of the secondary reservoir 6 towards the tube. The rapid expansion device according to the invention will be described hereinafter with reference to FIGS. 2,3,5 and 6. The rapid expansion device 11 according to the invention will make it possible to directly connect the tube 10 and the secondary reservoir 30. 6. The pneumatic launching device 1 described above, makes it possible to adjust the amount of energy supplied to the projectile. Indeed this amount of energy is directly related to the product of the pressure by the volume of gas contained in the secondary reservoir 6 according to the ideal gas law. The pressure inside the secondary tank is kept constant until the shot and it is the same for each shot made, regardless of the desired range. This makes it possible to obtain initial acceleration conditions of the projectile that are identical from one shot to another, but the duration of the thrust that determines the range will be a function of the volume V of available gas. We can thus ensure in all cases the arming of a projectile rocket. Thus, in a firing sequence, the volume V of the chamber 6d of the secondary reservoir 6 is first adjusted with a chamber pressure equal to atmospheric pressure.

Then this volume V is filled with the gas of the primary reservoir 2, the fixed operating pressure which is desired to give at least the pulse for arming the projectile rocket. The shot can then take place.

The volume control is an easy parameter to modify precisely. This is not the case for an adjustment of the pressure introduced into the chamber as proposed in the state of the prior art. If one compares a pneumatic launching device as described, having a constant pressure and a variable secondary chamber volume, to a second device such as US2960977 where the volume of the secondary chamber is constant but the pressure is variable, the device The launching method described with reference to FIG. 1 makes it possible to obtain a better accuracy on the energy supplied to the projectile over all the spans (the advantage is however limited to large spans). Indeed, the ratio of the errors is of 2,5 for the range mini then becomes equal to 1 with the maximum range (because then all the parameters of shooting, pressure and volume, are equal for the two compared devices). According to FIGS. 3 and 5 and according to another embodiment, a pneumatic launching device 1 comprises two parallel tubes 10a and 10b, each comprising a projectile 9. The upper tube 10a is capable of being supplied with compressed gas contained in the secondary reservoir 6. gas volume is adapted to the firing needs according to the principle previously expressed by the sliding of a piston 6b whose position is determined accurately by a motor, slaved in position to a displacement sensor, motor actuating a screw-nut system 6c and 6d (motor and sensor not shown). The secondary reservoir 6 is supplied with compressed gas 15 by a gas inlet 12 connected to a network as described previously (see description in FIG. 1). The secondary reservoir 6 has an opening 17 which communicates with a launch tube 10a or 10b. In the position shown in FIG. 2, it is the tube 10a facing the opening 17. Each tube 10a and 10b comprises a rapid expansion device 13 according to the invention which forbids (or allows according to the need) the direct passage of gas between the tube 10 and the secondary reservoir 6. The second tube 10b also comprises a rapid expansion device 13 and is placed symmetrically to the first tube 10a with respect to a pivot axis 14 secured to a plate 15. The plate 15 has a window 16 placed opposite the second tube 10b. This window 16 is used for projectile recharging 9 of the second tube 10b. The two tubes 10a and 10b are integral and can pivot together about the axis 14 so as to place a tube containing a projectile 9 ready to be launched opposite the opening 17 of the secondary reservoir 16 and an empty tube facing of the window 16 of reloading. It will be noted that during the rotation of the tubes, the pressure in the secondary tank is at atmospheric pressure. The repressurization of fire of the secondary reservoir 6 is done when a loaded tube is opposite the opening 17 and the sealing is ensured. According to Figure 3 (upper part), the rapid expansion device according to the invention comprises a closure means 51 of the tube 10a which is connected to the tube 10 by a releasable locking means 43. The sealing means 51 is formed by a thrust plug 51 that can be fixed to the rear part of the projectile 9 and is slidable inside the tube 10. This cap 51 is shown according to a particular embodiment of FIG. 5 in position ready to fire and it forms a thrust means 51 of the projectile 9. It comprises a rear portion 55a having an outer diameter substantially equal to that of the tube 10, the relative clearance is chosen so as to form the best compromise between sealing and friction in the tube 10. It may be provided a peripheral ring or lip seal (not shown) on the rear portion 55a. The plug 51 also has a front portion 55b of reduced diameter which is housed inside the tail 9a of the projectile 9. The plug 51 has an axial bore 59 25 extended at the rear portion 55a by a counterbore 60. rod 57 integral with a pressure plate 56 integral with a bar 57 is housed in the axial bore 59, the pressure plate 56 being positioned in the counterbore 60. The bar 57 can slide coaxially with the projectile 9 in the bore 59. As seen in FIG. 5, the bore 59 has a larger diameter portion 61 (or flare 61) and the front portion 55b of the plug 51 is further divided into at least two portions by longitudinal slots. .

The end of the bar 57 has a bulge 58 having an outer diameter greater than the inner diameter of the front end 62 of the plug 55b. This bulge 58 is separated from the rest of the bar by a groove 66. In the position of the bar visible in Figure 5, the bulge 58 is positioned facing the end 62 of the front portion 55b of the cap 51. The diameter of the boring 59 being the same on each side of the flare 61, the bulge 58 then exerts a radial force on the end 62 of the front portion 55b of the plug placed in the projectile tail 9. Because of the slots arranged at this end level, the bulge 58 causes the expansion of this end 62 and thus blocks the plug 51 in the projectile tail 9. In this way the projectile is secured to the plug and can be introduced into the tube 10. Referring to FIG. 3, when the projectile 9 is stationary, ready to fire, the cap 51 is blocked relative to the tube 10 by a locking means 43 to prevent its advance in the tube 10. The locking means 43 comprises at least one obstacle 52 who is trained here pa r balls 52 which interfere with a chamfer 53 located at the front periphery of the plug 51. Each ball 52 is partially housed in a bore 54 passing through the thickness of the wall of the tube 10. When the pressure is introduced into the secondary chamber 6 it is exerted on the sealing means 51, the thrust of the chamfer 53 on the balls 52 tends to eject them through their holes 54. This movement of the balls is blocked or allowed by the sliding of a ring 63 surrounding the outside of the tube 10.

The ring 63 has in its internal part at least one internal groove 64 intended to be placed in front of the bore 54 and receive all or part of the ball 52 when the firing is triggered as visible in Figure 3 (lower part).

The ring 63 also comprises a zone 65 in correspondence with the outside diameter of the tube 10 and which prevents the balls 52 from leaving their holes 54 when firing is prohibited. The ring 63 is pushed towards the position prohibiting firing by the action of a compression spring 45 which bears on a shoulder 47 of the tube 10. A flanged ring 44 integral with the ring 63, clamps the stroke of the ring 63 when it undergoes the thrust of the spring 45, the flange of the ring 44 bearing on the shoulder 47. According to Figure 3 lower part, a sliding of the ring 63 towards the front of the tube 10 position the housing 64 opposite each of the balls 52. The pressure accumulated 15 behind the cap 51 advances the latter which pushes the balls 52 to the housing 64. Those ci do not more obstacle to the cap 51 which propels the projectile 9 in the tube 10. As soon as the secondary chamber 6 is pressurized, it can be observed in FIG. 6 that at the stopper 51, the thrust plate 56 slides the rod 57 towards the front of the projectile (FIG. projectile not shown). Thus the bulge 58 is placed out of the front portion 55b of the cap 51. The expansion of the end 62 of this front portion 55b is no longer maintained. Therefore the projectile is no longer secured to the plug 51. The plug 51 pushes the projectile out of the tube and, once out of the tube, it separates the projectile in flight by the action of the aerodynamic pressure exerted on the rear portion 55a of the cap 51. According to the embodiment illustrated in Figure 2, the opening 17 of the secondary reservoir 6 is the diameter of the tube and corresponds directly with it. In this way the pressure losses are extremely limited. According to an embodiment not shown, the locking means may comprise a wedge having an inclined profile in correspondence with a chamfer of the plug or a groove thereof. This proposed alternative reduces the contact pressure between cap and locking means according to the desired effort for the firing control. The rapid expansion device according to the invention can be implemented with other pneumatic launching devices of different technology than that described with reference to FIG. 1. It will thus be possible to associate the expansion device according to the invention with a device in which the speed of the projectile is adjusted by adjusting the firing pressure.

Claims (4)

CLAIMS1- rapid expansion device for pneumatic launching device comprising a projectile lance tube (9) supplied with compressed gas by a reservoir (6), expansion device characterized in that it comprises (13) a closure means ( 51) of the tube (10) which is integral with the projectile (9) and which can be connected to the tube (10) by a releasable locking means (43). 2- rapid expansion device (43) according to claim 1, characterized in that the locking means (43) comprises at least one obstacle (52) disposed in a radial hole (54) of the tube (10) and comprising a end engaging a surface of the closure means (51), an obstacle (52) which is held in the locking position by a sliding ring (63) surrounding the tube (10). 3- quick release device (43) according to claim 2, characterized in that the ring (63) has an internal groove (64) in which can be housed the obstacle 20 (62) in the unlocked position. 4- rapid expansion device (43) according to one of claims 2 or 3, characterized in that the ring (63) is integral with a collar ring (44) which slides on the tube (10) and abuts against a shoulder (47) of the tube in the locking position, a spring (45) being interposed between the ring (63) and the shoulder (47) to maintain the ring in the locking position.