DE3922454A1 - HIGH-SPEED PARTICLE SPINNER - Google Patents

Abstract

A thrower of at least one flare 20 at very high velocities has, from upstream to downstream in a bore 1, an upstream explosive charge 2, an stream projectile 3, and then at least one propulsive stage 4, the propulsive stages succeeding upstream to downstream in the bore and each being constituted by an explosive charge 5, a projectile 7 downstream of the explosive, and a gap 6 occupied by gas or a vacuum extending between the explosive and the projectile, the projectiles having masses decreasing towards the downstream side and the flares being located on or constituting the furthest downstream projectile 107. The bore 1 may be cylindrical or conical tapering downstream. An obliquely disposed screen 22 may be provided, having openings 24 facing the flares 20. <IMAGE>

Description

The present invention relates to a Spinner or particle spinner at very high speeds, i.e. in dozens of Kilometers per second. Such particles can be interesting to impacts of small celestial bodies to simulate, for ballistic experiments or for the Research into fusion controlled by sudden strong Compression of plasma due to particle impact.

Such high speeds cannot pass through simply placing a projectile in front of one Explosion charge according to the principle of the conventional Cannons are provided. This therefore led to the fact that into the soul of the slingshot below the projectile second projectile was used by a lesser Mass with respect to the first. According to the well known Impact equations (maintaining the motion and Amount of energy), the projectile takes a larger one below Speed on than the projectile above when the Cohesion of these projectiles after impact is maintained. It is therefore necessary that between the projectiles a light very compressible Material is brought in between.

This light intermediate material, the compression of which Shock absorbs and prevents flaking or flaking or shattering the front projectile. Instead of light material an explosive layer was used which has substantially the same properties that however, still allowed by their self-ignition, one driving floor to form the lower or rear  Projectile accelerated even further.

The main problem that arises here is that the Detonation of the explosive layer particularly strong pressures generated that act on the rear projectile and too its destruction by melting, fragmentation or even cause evaporation. In practice they are Speeds achieved by the process can, therefore limited.

The invention allows these disadvantages to be overcome by a new one Design of the explosion charge with respect to the rear Projectile to overcome, according to which it is intended Layer of air or any other gas with to bring enough pressure between them. In in practice, air under ambient pressure is very possible, although the vacuum leads to better results.

The explosive charge detonates under the influence of Contact with the front or first projectile, and the products of the detonation can thus differ between the explosive charge and the rear projectile. The compressibility of the gases is therefore very high more important, which leads to the lower one Projectile transferred pressures are less high about four times less. This is enough to to prevent any destruction of the lower projectile.

It is therefore possible and advantageous to provide further similarly constructed but smaller driving levels downstream of the driving level, which is formed from the explosion charge and the rear projectile, in terms of both the mass of the projectile and that of the explosion charge. The hurling thus ends in a succession of impacts from projectiles, each projectile accelerating the projectile arranged immediately after it. Speeds of several tens of kilometers per second can be achieved with a sufficient number of floating floors or sections. The particles are either formed from the lower projectile itself - it is then a single-shot spinner - or are carried by this lower projectile, for example introduced into incisions adapted to their shape in the projectile.

The invention is in its most general form formed from a slingshot or one Spin device of at least one particle or Ejection at very high speeds from above down in a soul, an upper explosion charge, an upper projectile, at least one floating floor, where the floors are consecutively from top to bottom in arranged by the soul and each by one Explosion charge are formed, a projectile downstream of the Explosion charge, and has an interval from that Gas or the vacuum that is between the Explosion charge and the projectile extends, the Projectile decreasing masses in the downstream direction and the particles are on the bottom Projectile.

Two main versions are detailed below described: In one of them the soul is cylindrical and the explosive charges as well as the projectiles and Plates are flat; in a second Embodiment, the soul is conical and converged downstream, while the explosion batches or -charges and the plates concave cylinder sections or hollow spherical sections, for example, are.  

Sample rules are also available that in particular show that the floating floors advantageously an identical geometric Configuration except for a similarity transformation have exactly.

Another object of the invention is the particles too shoot without trying by shooting out to disrupt unwanted matter, for example from fragments of the bottom plate, which the Carries particles. This can be done downstream of the plate a screen inclined with respect to the soul that of recesses towards the particles is enforced. During the detonation, the screen normally destroyed and in by these chips hurled a direction that is close to the direction is perpendicular to its surface while the Chipping through the screen before its destruction in to be distracted in the opposite direction.

Further advantages of the present invention result from the subclaims.

More details, features and advantages of the present invention result from the following Description with reference to the drawing which basic aspects of the invention clarified. In this shows:

Fig. 1 shows a possible embodiment of the invention,

Fig. 2 shows another embodiment of the invention,

Fig. 3 shows a possible embodiment of the bottom plate carrying the particles

Fig. 4 shows another possible embodiment of this plate in the case where the ejection or the particle is unique, and

Fig. 5 shows another embodiment of the soul of the slingshot.

In FIG. 2, the main components of the invention are shown. A core or a soul 1 successively shields from top to bottom an explosive charge 2 , which detonates above, a projectile or an upper plate 3 and a certain number of driving levels 4 , which are shown here in the number of 4, and which are formed from top to bottom from a detonating explosive charge 5 , an interval 6 of air or vacuum and a plate 7 . The core 1 can be tubular or more generally formed from a solid structure, the combination or arrangement of which ensures the definition of its content and the longitudinal guidance of the plates 3 and 7 . An arrangement of longitudinal rods 15 , which are connected by contour frames 16 ( FIG. 5), can also be suitable.

An unoccupied space 12 appears between each floor 4 , whereby it can be filled with air or vacuum and the thickness of which is sufficient to allow each plate 3 or 7 not to damage the explosive charge 5 of the subsequent driving floor 4 after it was accelerated sufficiently. In this embodiment, the core 1 is, for example, cylindrical and the projectiles 3 and 7 are flat plates, while the explosive charges 5 , the intervals 6 and the unoccupied spaces 12 are also essentially flat volumes. The driving levels 4 taper from top to bottom, the ratios of the thicknesses of the explosive charges 5 of the interval 6 and the plate 7 being constant inside each driving level 4 ; moreover, the ratio of the thicknesses of the two components of the same type, for example the plates 7 , is uniform between two successive driving floors 4 , whichever these floors 4 are. A geometric configuration is thus obtained, where each driving level 4 can be derived from the previous level by a similarity transformation from constant level or slightly variable ratio from one level to another.

The soul 1 is cut on its outside 8 by circumferential notches or incisions 9 , which are deep and narrow. As shown in French Patent No. 87 16 888, the shock or shock wave generated by the detonation circulates faster inside the soul 1 than inside it, and is transmitted through a contraction or compression of the soul 1 that constrains the projectiles . The notches 9 are intended to filter this shock wave.

The explosive upper charge 2 partially protrudes outwards relative to the core 1 , the centrifugal device being provided with a base piece. The upper explosive charge 2 is ignited by a detonator 10 which is connected to any suitable ignition device 11 . The detonator first abuts a flat detonation wave generator 2 ', which is part of the explosive upper charge 2 and has the shape of a truncated cone.

According to the intended application, the ejection or the particle to be spun may be formed by the very bottom plate of the spinner, which is designated 107 here, or simply by particles 20 of smaller dimensions contained in this lower plate 107 , which is also shown in Fig. 3. The particles 20 can be of different dimensions depending on the requirements. They are inserted into the lower plate 107 before being thrown out, after suitable incisions have been made therein, and are separated from the lower plate 107 at the time of the explosion. In the case where only the impact of particles 20 on a target object 21 , shown in FIG. 1 with respect to the soul 1 , is sought, it can be interesting or useful to arrange a screen 22 between the soul 1 and the target object 21 , which is inclined with respect to the core 1 and the trajectory of the particles 20 . The screen 22 is connected, for example, at the lower end of the core 1 to metallic rods 23 and is provided with recesses 24 which are arranged opposite the particles 20 and parallel to their trajectory.

The particles 20 are spun under the action of the ignition device 11 , which thus causes the preferably flat detonation of the upper explosive charge 2 . The energy generated by this detonation in turn produces the movement of the upper plate 3 which crosses the first unoccupied space 12 . An impact is generated with the explosive charge 5 of the first driving level and detonates the latter. The explosion gases spread under a relatively weak pressure in the intermediate space 6 , so that the plate 7 is accelerated without excessive impact and is not destroyed by decay, fusion or evaporation.

Since the plate 7 has a lower mass with respect to the upper plate 3 , it is propelled at a higher speed, especially since the explosive charge 5 also gives it an increase in kinetic energy. The subsequent explosive charge 5 then detonates as soon as it is struck by the plate 7 , and the process is repeated through all the floating floors 4 until it is the turn of the lower plate 107 . The particles 20 are then flung onto the target object or target 21 according to straight-line trajectories 30 and reach them after they have passed through the recesses 24 . The other original projectile parts of the plates 3 and 7 , on the other hand, are deflected or caught by the screen 22 against which they hit before they are deflected according to the trajectory 31 . The screen 22 itself may be destroyed by the multiple impacts and its parts are thrown further according to the trajectories 32 . Thanks to the inclination of the screen 22 , the trajectories 31 and 32 therefore pass outside the target 21 , which is only reached by the particles 20 .

However, the screen 22 is not always necessary. This is the case, for example, if the part that is to be spun is nothing other than the lower plate 107 itself. This is also the case in the configuration according to FIG. 4, where the lower plate, here reference number 207 , is not is flat but conical and tapers at its center where a single particle 22 is located. This configuration of the projectile 207 is suitable if the plates 7 of the previous floors rebound on the detonation products of the charges before 5 and 5 '. During the explosion, the lower plate begins to deform, then shatter into pieces that are provided with a centrifugal velocity that removes them from particle 220 in turn. The latter can thus be designed in an original form in the form of a tablet, which allows it to deform during the detonation in order to finally reach a front convex edge 221 and a rear concave edge 222 , which give it an aerodynamic shape.

Another preferred embodiment of the invention is shown in FIG. 2. Most of the elements of FIG. 1 are found here with the similar functions and different shapes. So the soul 1 'of conical shape and tapers downwards into a cone with an acute angle of approximately 60 °, and the tip of which is arranged very close to the lower plate 107 '. The lower plate 107 'accordingly has very small dimensions with respect to the rest of the spinner, which means that this solution is primarily adapted to a lower plate 107 ', which carries only a single particle 20 '.

The lower plate 107 'is quasi flat and installed in a cylindrical mouth 19 ' of the core 1 ', while the rest of the inner surface 18 ' of the core 1 'is conical and the upper explosive charge 2 ', the upper projectile 3 'and the components the driving floors 4 ', that is, as before and in succession, an explosive charge 5 ', an intermediate space 6 'and a projectile 7 ', are formed in hollow spherical sections which are perpendicular to the inner surface 18 'of the soul 1 '. The outer surface 8 'of the soul 1 ' is cut with incisions 9 ', while several detonators 10 ' or preferably a generating device for a spherical detonation wave (to enable a shorter detonation of the upper explosive charge 2 ') are connected to a detonator system 11 '.

Unoccupied rooms 12 'exist between the floating floors 4 '.

The operation of this embodiment is identical to that of Fig. 1. The main difference is that the lower plate 107 'is accelerated with a greater energy and thus reaches a greater speed, with all other things, as in the system of Fig. 1, are the same. The configuration of a cylindroconical or spherical conical implosion does not allow a large number of emissions to be generated.

A comparison between the embodiments of FIGS. 1 and 2 can be carried out with the help of Tables I and II, of which the first relates to a flat slinger with a cylindrical core 1 and the second a spherical slinger with a conical core 1 '.

The explosive in both cases is the octolite and the projectiles are made of steel. The upper explosive charge is 400 mm thick and the upper projectile 16 mm. For each floating floor, the ratio between the explosive mass per unit area and the projectile mass per unit area is 0.5. The ratio of the similarity transformation (thickness of an element of a driving floor with respect to the corresponding thickness in the previous floor) is equal to 0.4. For the table, the outer radius of the explosive top load is 550 mm. The intervals 6 have a thickness approximately twice that of the projectiles 7 starting from the second floor, just like the explosive charges 5 .

Tables I and II thus indicate, depending on the number of each driving level 4, the thickness of the projectiles of the driving level in question and the speed which it achieves after the detonation. What is striking here is that in order to achieve increased speeds, it is necessary to increase the number of driving floors and so the configuration of the spherical-conical implosion becomes considerably more interesting, since the thicknesses of the plates and particles or splinters that are thrown out can be, so much larger, in planar configuration, in a ratio close to 2 from the first floor and approximately 500 at the tenth floor. For a large number of floors, only the implosion configuration can be considered. However, other concave shapes of the projectiles 3 'and 7 ' and the explosive layers 2 'and 5 ' can be used.

The air that occupies the intervals 6 or 6 'must allow the initiated relaxation of the gases generated by the detonation of the explosive charges 5 or 5 '; the ambient pressure is suitable for this. Even better results can be achieved if vacuum 6 is generated in intervals 6 and 6 '. The air can also be replaced by any other gas.

Claims (11)

1. centrifugal device of at least one particle ( 20 , 20 ') at very high speeds, the top down in a soul ( 1 , 1 ') an upper explosive charge ( 2 , 2 '), an upper projectile ( 3 , 3 ' ), and then at least one driving level ( 4 , 4 '), the driving levels ( 4 , 4 ') each consisting of an explosive charge ( 5 , 5 ') and a projectile ( 7 , 7 ') below the explosive charge ( 5 , 5 ') are formed, the projectiles ( 3 , 3 ', 7 , 7 ') having decreasing masses, and the particles ( 20 , 20 ') on the projectile ( 107 , 107 ') the most is located furthest down, characterized in that the driving floors are equally formed from an interval ( 6 , 6 '), which is occupied by gas or vacuum, which is between the explosive charge ( 5 , 5 ') and the projectile ( 7 , 7 ') extends. 2. centrifugal device according to claim 1, characterized in that the core is a rigid structure which the attachment of the driving floors ( 4 , 4 ') of the upper explosive charge ( 2 , 2 ') and the upper projectile ( 3 , 3 ') allowed. 3. centrifugal device according to claim 1, characterized in that the core ( 1 ) is cylindrical. 4. centrifugal device according to claim 1, characterized in that the core ( 1 ') is conical and tapers downwards or downstream. 5. Centrifugal device according to one of claims 2 to 4, characterized in that the projectiles ( 3 , 7 ) and the explosive charges ( 5 ) are flat. 6. Spin device according to one of claims 2 to 5, characterized in that the projectiles ( 3 ', 7 ') and the explosive charges ( 5 ') have a concave shape. 7. centrifugal device according to one of claims 1 to 6, characterized in that the driving levels ( 4 , 4 ') have a geometric configuration which are approximately identical to an approximate similarity transformation. 8. Centrifugal device according to one of claims 1 to 7, characterized in that the particles ( 20 ) are inserted in incisions in the plate ( 107 ) which is arranged at the bottom. 9. Centrifugal device according to claim 8, in which in each case there is only a single particle, characterized in that the particle ( 220 ) is arranged in an incision in the center of the lowermost plate ( 207 ), the lowermost plate increasing tapered towards the center. 10. Spinner according to one of claims 1 to 9, characterized in that the gas which occupies the intervals ( 6 , 6 ') is under a pressure between atmospheric pressure and the vacuum pressure. 11. Centrifugal device according to one of claims 1 to 8, characterized in that a screen ( 22 ) is interposed below the bottom plate, wherein it is arranged obliquely with respect to the soul, and that the screen of recesses ( 24 ) against each of the particles ( 20 ) is enforced.