FR2678054A1 - METHOD FOR ACCELERATING A PROJECTILE, AND ACCELERATOR TUBE WITH DYNAMIC EFFECT FOR ITS IMPLEMENTATION. - Google Patents

Abstract

The invention relates to a dynamic effect accelerator tube comprising an accelerator tube in which is formed a closed chamber, filled with a mixture of fuel gas under pressure. A projectile (4) forms in the tube a dynamic effect channel in which the gas mixture can flow to be consumed behind the narrowest section of the channel and accelerate the projectile. This projectile (4) is placed either directly behind the chamber (3), outside the latter, or at its rear end and inside the latter, and in a fixed position with respect to this chamber. During launching, the chamber (3), filled to an appropriate pressure with an appropriate quantity of gas, is opened at its rear end, and the gas mixture which escapes from it flows against the projectile (4). so that the relative velocity between the projectile and the gas mixture, necessary for the initiation of the acceleration phase, is established.

Description

METHOD FOR ACCELERATING A PROJECTILE, AND TUBE

  ACCELERATOR WITH DYNAMIC EFFECT FOR ITS IMPLEMENTATION.

  The invention relates to a method for accelerating a projectile in a tube which comprises a closed chamber filled with a mixture of flammable gases under pressure, by establishing a relative speed between the projectile which forms in the tube a dynamic effect channel of the nozzle type. , in which the gas mixture can flow, and the gas mixture, and producing the combustion of the gas mixture behind the narrowest section of the dynamic effect channel, the projectile forming a ramjet moving against The invention also relates to an accelerator tube with dynamic effect for implementing the method, comprising an acceleration tube and a projectile forming therein a dynamic effect channel of the nozzle type, which extends continuously from its front side to its rear side, at least one chamber closed on each side by a membrane and can be filled with a mixture of inflammable gas e under pressure, being formed in the acceleration tube, the assembly also comprising a support housing disposed coaxially with the acceleration tube, where appropriate behind the chamber, and intended to receive the projectile

at rest, before acceleration.

  Such a method and such an accelerator tube with dynamic effect are disclosed by the publication "THE

  RAM ACCELERATOR: A NEW CHEMICAL METHOD OF ACHIEVING

  ULTRAHIGH VELOCITIES "by A Hertzberg, AP Bruckner and DW Bogdanoff, Aeroballistic Range Association, Quebec, Canada, 1986 The basic principle of this process is as follows: Between a fixed tube and a sub-calibrated projectile passing through it, is formed an annular gap through which flows a mixture of flammable gas present in the tube On this occasion, the relative speed between the projectile and the gas mixture is greater than the sonic speed typical for this gas mixture The gas mixture which the projectile is fired and burned, and an area that burns and accompanies the projectile in flight continuously exerts a thrust on the projectile, thereby causing its continual acceleration. dynamic effect comprises a tube capable of being filled by the gas mixture and whose interior space forms at least one chamber whose front side and the rear side re are each closed by a membrane This membrane must resist a

  high internal pressure in the chamber.

  The projectile, on the other hand, has radially projecting guide surfaces which provide the

  centered guidance of the projectile in the tube.

  In front of the tube and coaxially thereto, there is arranged a pre-accelerator in the form of a barrel, in which the projectile in combination with a propulsion base, is brought, by conventional means, to the speed required for the

  operation of the dynamic effect tube.

  However, before the projectile can penetrate the tube, its propeller base must first be evacuated; the pre-accelerator must for this purpose be at a considerable distance from the end

back of the tube.

  The known accelerator thus has a very important length; its use as a piece of cannon is excluded, if only because of its length. In addition, the parts of the propeller

  must be intercepted, which is complex.

  Also, the object of the invention is to simplify the known method, and in particular the accelerator tube with known dynamic effect, and to develop them.

  so that it is possible to get rid of a pre-

  acceleration and therefore a pre-accelerator.

  According to the invention, this object is achieved for a method of the type mentioned in the introduction, in that the projectile is arranged at least approximately in a fixed position in the tube, the chamber is open at its rear end, so that the gas mixture therein is forced to escape from the tube rearward and on this occasion, to move relative to the projectile, and that the gas mixture is ignited behind the section la narrower the channel with dynamic effect, so that the projectile is accelerated relative to the tube Furthermore, there is provided according to the invention a dynamic accelerator tube for the implementation of this method which comprises an acceleration tube and a projectile forming therein a dynamic jet channel of the nozzle type extending continuously from its front side to its rear side, at least one chamber closed on each side by a membrane and in being filled by a mixture of flammable gases, under pressure, being formed in the acceleration tube, the assembly also comprising a support housing arranged coaxially with the acceleration tube, and intended for

  receive the projectile at rest, before its acceleration.

  In the case where the support housing is disposed behind the chamber, it directly adjoins the chamber or the chamber located at the rear, and there is provided a device for destroying the membrane directed towards the projectile In another embodiment the support housing is disposed within the chamber, or the rearmost chamber, and at the rear end thereof, and there is provided a device for opening the rear end of the chamber; this

  room, at the back of the projectile.

  According to the invention, the projectile is arranged in a fixed position in the tube, and the gas mixture strongly compressed in the chamber is forced to escape from it. This makes it possible to obtain a flow against the projectile, as it was

  possible until now by launching the pre-projectile

  accelerated in the gas mixture at rest.

  This inventive concept can be concretized by two solutions of principle: a) the projectile is arranged behind the chamber, in the acceleration tube The chamber is sealed with respect to the projectile, by a pressure-resistant membrane At launch, the membrane is punctured or destroyed, so that the highly compressed gas mixture escapes to

  the back flowing against the projectile.

  b) the projectile is placed inside the chamber, immersed in the strongly compressed gas mixture, at the rear end of the chamber. At launch, the chamber is opened behind the projectile and the gas mixture flowing in direction of the opening, flows on this occasion against the projectile. In each case, a spontaneous or forced firing takes place behind the narrowest section of the dynamic effect channel formed by the projectile, and the pressure of the explosive or consuming gas mixture, which acts on the projectile, propels the The amount and pressure of the gas mixture must be chosen here so that in the case of (a) the velocity of flow against the projectile, and in the case of (b) the velocity of flow in the rear area of the projectile, not less than the speed of sound, specific In case b), the flow against the projectile is done with a speed

relative subsonic.

  As long as a projectile is used, as known from the state of the art cited above, and for which the dynamic effect channel is formed between the inner surface of the acceleration tube and the outer surface of the projectile, the projectile does not have a propulsion envelope, but rests against the wall of the tube, by means of its guide surfaces, radially projecting Also in case a) previously mentioned, the membrane located directly in front of the projectile, and in case b), the membrane located directly behind the projectile, is destroyed, so that the gas mixture relaxes in the direction of the projectile and flows on this occasion also around

of the projectile.

  When the pressure drop during relaxation is sufficient, the flow against the projectile

  is supersonic in case a).

  The gas mixture that has passed around the projectile is fired as soon as possible, in the area of the rear end of the projectile, and thus exerts a thrust on the projectile, while simultaneously, the relaxation of the mixture of gas is still going on; the amount of gas present in the chamber formed in the tube, is here large enough so that the trigger ends only when the projectile is for its part already accelerated to a speed greater than the speed of sound During this acceleration, the relative velocity between the projectile and the gas mixture flowing against it, must continually be greater than the typical speed of sound for the mixture of

gas considered.

  The gas mixture is constituted by at least one fuel, such as CH 4, C 2 H 2, H 2 and the like, with an oxidant (O 2), and, where appropriate, with at least one inert addition gas, such as, for example, He, C 02 and the like, which inter alia influences the speed of sound and

  the detonation velocity of the gas mixture thus formed.

  The tube can not have a fixed closure behind the projectile, because otherwise the mixture of gas flowing around the projectile could accumulate by quickly disrupting the flow around the projectile It is possible to set up a screen which regulates the flow of the flue gases so that the speed of the gas mixture flowing against the projectile is controlled above the speed of sound, even in the event of a fall in particularly high pressure, so as to prevent too rapid a relaxation and to ensure that the projectile already considerably accelerated, as far as it is in the absolute, in the subsonic domain, always meets a flow of

relaxation, important enough.

  According to a preferred configuration of the invention, however, it is particularly advantageous to leave the rear end of the support housing receiving the projectile, or the rear end of the tube in the rear section of which the projectile is disposed, substantially completely open. dynamic accelerator thus constructed operates in this case, without recoil The pressure of the gas and the quantity of the gas mixture in the chamber in front of the

  projectile, are to be chosen correspondingly.

  According to a preferred configuration of the invention, it is however particularly advantageous to have between the open end of the support housing or the tube and the base of the projectile, a sliding piston whose resistance, in particular the mass, opposite the sliding, prevents a too rapid expansion of the gas mixture in the starting phase of the acceleration of the projectile In addition, such a piston can perform particular functions during the firing of the projectile, as will be described more

in detail thereafter.

  The piston could be freely disposed behind the projectile and loaded separately therefrom, but, according to a preferred configuration of the invention, it is fixed on the base of the projectile, so that it can be torn off by the impact of gases from

gas mixture in relaxation.

  According to an advantageous configuration of the invention, the support housing is disposed in the rear part of the acceleration tube, and the acceleration tube preferably extends further beyond the rear of the support housing. here particularly advantageous that the support housing or the tube extends further beyond the rear of the piston and does not terminate directly behind the piston, so that it can still perform a defined race in the housing of support or the tube, on the one hand by acting on this occasion on the unfolding of the trigger so as to modulate it, and on the other hand being able to perform functions

auxiliaries described below.

  It is possible to use, in place of the projectile traversed by the flow of the gas mixture along its outer side, a projectile which is applied by its outer side, in a sealed manner against the accelerator tube with dynamic effect, The mode of action is the same as for the projectile described in the state of the art mentioned in the introduction, and the present invention also encompasses the use of a dynamic effect channel.

such hollow projectile.

  In the case of such a hollow projectile with dynamic effect, it is particularly advantageous, according to another configuration of the invention, to use, in place of a closure piston to the size of the caliper, a plug of shutter that is arranged in the outlet of the

  dynamic effect channel passing through the hollow projectile.

  This blanking plug can fulfill the same functions, described in this application, as the shutter piston; for this purpose, it is also possible to have centrally on the rear side of the closure cap, a closure piston relatively light configuration, and acting only in

as guidance.

  The closure cap can be held in a sealed and removable manner in the output of the dynamic effect channel, by means of a triggering device. The entire body of the projectile can instead be in sealing engagement at the end of the accelerator tube with dynamic effect, against the inner edge of a closure element which is traversed by an aperture of dimension almost equal to the caliber In this case, the accelerator tube with dynamic effect does not require a rear sealing membrane, but the body of the projectile provided with the closure cap, itself ensures sealing against the pressure of the gas mixture. When the triggering system is actuated, the shutter plug is ejected, by the pressure of the gas mixture, backwards, out of the exit of the dynamic effect channel, through the opening of the element of closure, and the gas mixture flows outward through the

dynamic effect.

  In the case of the acceleration tube with known dynamic effect, the membranes of the chamber are designed so as to allow an internal pressure in the

  room, can only reach 25 105 Pa.

  In the case of the invention, the possible lower limit of the pressure is already approximately at this value, namely around 20 105 Pa. But according to the invention, the chamber and its membranes are designed so as to be able to achieve an internal pressure of more than 100 105 Pa For this purpose, in the case of several successive chambers, only the rearmost chamber must be able to present such pressure; more room considered, a series of successive rooms, is located near the mouth of the tube, and lower can be the pressure in this room directly before launching. To create the necessary condition for the acceleration of the projectile, the mixture of strongly compressed gas must be forced to flow through the membrane closest to the projectile But this membrane is for its part quite stable, because it must able to withstand a pressure of up to 100 105 Pa, as mentioned above In the state of the art mentioned in the introduction, the projectile perforates the membrane, but in this case it

  However, it already has a speed

above the speed of sound.

  According to a preferred configuration of the invention, a device for perforating the membrane is formed or disposed on the projectile warhead; the particular advantage of such an arrangement lies in the fact that the membrane is perforated centrally, so that the flow against the projectile, after the perforation of the membrane, is carried out uniformly. According to another preferred configuration of the invention, the bullet of the projectile is itself made as a striker, and the entire projectile forms a striker body, which can be pushed against the diaphragm to make a shot with the accelerator tube with dynamic effect, by means of a percussion device which may comprise a spring of

  voltage or an acceleration magnet.

  According to a variant configuration of the invention, it may also be advantageous to perforate or destroy the membrane closest to the projectile, by means of a device independent of the projectile; thus, it is for example possible to loosely embrittle a thermoplastic plastic membrane, by means of an electric heating wire which is embedded therein; it is however necessary to make sure that the temperature of this heating wire does not get closer

  not the ignition temperature of the gas mixture.

  it is particularly advantageous to use a striker device which is substantially disposed in an area between the projectile guide surfaces and does not disturb the movement.

of it.

  In the case of the state of the art mentioned, the firing of the gas mixture is carried out by a blank cartridge revolver which is initiated by a small ball fixed in the center of the membrane which strikes the primer of the cartridge when the projectile perforated the membrane In the case of the accelerator tube with dynamic effect according to the invention, it is possible to provide a similar device that could be

  triggered by the impact of the projectile against the membrane.

  If necessary, it would also be advantageous to propel forward against the membrane, by means of a low propellant charge, a striker disposed in the projectile warhead, and to provide in the projectile exhaust channels directed towards the the back, so that the still hot powder gases coming out of these

  channels, could cause firing.

  A preferred configuration of the invention, however, takes advantage of the particular characteristics residing in the fact that for the dynamic accelerator tube according to the invention, the projectile is not initially in motion at launch, and that behind this projectile is disposed, in a configuration mentioned above, a sliding piston, which preferably is even fixed on the projectile so as to be separated from the projectile after the application of a predetermined force. According to a preferred configuration of the invention, the outer surface of the piston directed towards the projectile is made so as to produce the firing of the gas mixture, which during the firing, after the destruction of the membrane, flows with a supersonic velocity against the projectile, flows around the body of the projectile and then hits the said surface

outside of the piston.

  In this context, it may be sufficient that the piston has a polished outer surface extending transversely to the axis of the core of the tube; but it may also be advantageous to fashion in another appropriate manner, the said surface

  externally extending transversely.

  But it is also possible to provide on said outer surface an independent firing device, preferably in the form of a pyrotechnic firing system, but also in the form of an electric spark generator or the like The ignition of the gas mixture can also be done by means of electric heating filaments

  arranged in the area of the rear of the projectile.

  Since the aim is to obtain the firing as early as possible, but this firing must take place only when a sufficient quantity of gas mixture is available behind the projectile, provision is made, according to another configuration of the invention, between the piston and the projectile, a delay triggering device, which preferably and as simply as possible, is in the form of a rupture cord arranged between the piston and the projectile, and which is tensioned and finally torn off for a determined spacing between the piston and the projectile At this time, the tearing can cause the interruption of an electrical current of rest, while the tension of the cord to

  rupture can activate a friction detonator.

  The firing in due time is thus ensured

  reliably, by simple means.

  According to a characteristic of the invention, the accelerator tube with dynamic effect is preferably made in the form of a piece of recoilless gun The dynamic accelerator tube according to the invention is ultimately only constituted by a tube of open acceleration at the front and at the rear, in the interior space of which a chamber is formed, by at least two membranes; preferably there are several chambers In the wall of the acceleration tube are housed valves for filling and

  exhausting the gas mixture into the chamber or chambers.

  The rear part forms a support housing in which is disposed a projectile which for example supports, via a spring under tension, on shear pins inserted into the wall of the acceleration tube, and which rests against a trigger device The end of the acceleration tube is

  closed by the piston mounted on the base of the projectile.

  This arrangement does not require a pre-accelerator,

  neither ejection device of a propulsion pellet.

  When the chambers are filled with the gas mixture, at the prescribed pressure, the dynamic accelerator tube thus configured is

shooting.

  It is obvious that such accelerator tubes with dynamic effect can be implemented in various ways on the military level, for example on the support armament of a helicopter, and for the fight against mobile targets that can also be combated by means of unguided projectiles, because of the exceptionally high initial velocity achieved by such an accelerator tube

  dynamic, despite its low weight.

  Depending on the type of material used for the acceleration tube, the accelerator tube with dynamic effect according to the invention can, after the launch, like a gun, be loaded again and

make a new shot.

  The accelerator tube with dynamic effect according to the invention can however also be used as a laboratory accelerator for very high speed tests; what is particularly interesting in this case is the fact that it is unnecessary to provide devices for evacuating the gases produced by a pre-accelerator, as in the case of the known installation, and to intercept the chips of the

propeller base.

  The object of the invention will now be described in more detail with reference to exemplary embodiments shown in the accompanying drawings which show: FIG. 1 is a diagrammatic longitudinal section of the rear part of an accelerator tube with dynamic effect in accordance with FIG. the invention, which is based on a first embodiment of the method according to the invention, Fig lb a schematic longitudinal section of the rear part of a dynamic accelerator tube according to the invention, which is based on a second embodiment of the method according to the invention, Fig 2 a view of a projectile for this accelerator tube dynamic effect, Fig 3 a view similar to Figure 2, however shortly after firing, Fig 4 has a schematic longitudinal section of a sub-calibrated projectile in the accelerator tube with dynamic effect, Fig 4 b a schematic longitudinal section of a hollow projectile, with a gauge, in the tube dynamic effect accelerator, Fig 5 a view of a firing device, in the direction of the axis of the dynamic accelerator tube core, and Fig 6 a view of another firing device , according to a representation similar to that of the

figure 5.

  FIG. 1 is a longitudinal cross-section showing a dynamic accelerator tube comprising an acceleration tube (1) made by assembling several sections. Between each pair of adjacent sections, a membrane (2) is inserted each time. so that between two adjacent membranes (2) is formed each time a chamber (3). The dynamic accelerator tube shown in Figs. 1a and 1b has two chambers, but may, however, be suitably extended to the right in the drawing when a higher initial velocity for the accelerator tube is to be achieved.

dynamic effect.

  The rearmostmost tube section, on the left in the figure, forms a support housing (10) which is arranged to receive a projectile (4). The support housing (10) and the projectile it is housed, are, in the case of the embodiment according to Figure la, outside the chamber (3), directly behind the membrane (2) located at the rear, and in the case of embodiment according to Figure lb, inside the chamber (3) and directly in front of the membrane (2) located at the rear, referring in each case to the direction of fire, namely

the direction of acceleration.

  This projectile is shown in more detail in FIGS. 2 and 3, and comprises a projectile body provided with guide surfaces (9). The outer ends of the guide surfaces (9) are in slight sliding contact with the inner wall of the tube (FIG. 1) and the support housing (10), and maintain the body of the projectile (4) in a precise coaxial orientation by

  relative to the acceleration tube (1).

  At the base of the projectile (4) of the embodiment shown in FIG. 1a, a piston (6) is connected in a tear-off manner which has a peripheral groove (5a) in which is housed a clamping ring (5) which holds the projectile (4) in a fixed manner in the support housing (10) when in its initial position

shown in Figure 1.

  Between the piston (6) and the base of the projectile is disposed a rupture cord (7) (see Figure 3), which terminates in a pyrotechnic firing cartridge (8) disposed on the outer surface of the piston ( 6) directed towards the projectile (4), and may be triggered by the rupture cord (7), when the latter

is tense.

  At launch, the membrane (2) closest to the projectile (4) is destroyed, so that the gas mixture in the chamber (3) corresponding, can relax against the projectile. On this occasion, the gas mixture meets the projectile with a speedupersonic, flows around the body of the projectile, between the guiding surfaces (9), and collides, between them, the surface of the

  piston (6) directed towards the projectile.

  This piston is torn from the base of the projectile and moves rearwards, an extension end of the support housing (10), projecting rearwardly and

  visible in Figure 1, serving as a guide to the piston.

  Simultaneously, the gases striking the surface of the piston heat up, and the rupture cord (7), which is fixed at its ends, to the firing device (8) on the piston (6) and the base of the projectile. At the same time, when the rupture cord (7) is tight, it triggers the firing device (8), and the gas reaching the rear of the projectile ignites. Now, the piston (6) is expelled backwards out of the support housing (10), however with a not very high speed, and the combustion gases can flow unhindered backwards, without generating At the same time, the projectile (4) starts to move under the effect of

  pressure generated by the combustion of gases.

  Since the pressure and the quantity of the gas mixture in the chamber (3) have been appropriately selected, the expansion flow around the projectile (4) continues, the latter being increasingly

more accelerated.

  In principle, the relative speed between the projectile (4) and the gas mixture flowing against it, must never fall below the speed of sound, so that the projectile (4), when it reaches the following membrane (2) and that it has thus crossed the first chamber (3), must present a speed already

greater than the speed of sound.

  But it is also possible to imagine that inside the first chamber, this speed is not yet reached; in this case, further acceleration does not take place, when the relative speed

  between the projectile (4) and the gas mixture is

  below the speed of sound, because the speed of relaxation drops when the chamber (3) is practically emptied. Further firing is advantageous, for example in the form of a known plotting load, which is attached to the base of the projectile and which has been activated by the rupture cord (7), during the initial firing. The charge, whose combustion continues on the accelerated projectile, ensures reliable and rapid firing, even in the case of irregular flow at

against the projectile.

  FIG. 4a shows a sub-calibrated projectile (4) which, according to the embodiment of FIG. 1b, is not located outside, but on the contrary inside the chamber (3) However, the latter is not sealed backwards by a diaphragm (2) as shown in FIG. 1b, but by a sealing plug (6 '), which is removably attached to the rear end of the projectile (4), which is sealingly and slidably housed in the acceleration tube (1) The closure cap (6 ') is supported at the rear against a triggering device (15). ) Furthermore, the closure cap (6 ') may be provided with a firing device (7, 8)

  as shown in Figure 3.

  FIG. 4b shows a hollow projectile (4 ') which is essentially of circular cylindrical shape and which, by its external surface, is sealingly and slidably applied against the wall

  inside of the acceleration tube (1).

  The hollow projectile (4 ') is traversed in the center by a dynamic effect channel (16) which acts as a dynamic nozzle and which can be traversed by the gas mixture (from right to left on the

Figure 4 b).

  In the drawing, the hollow projectile (4 ') is shown in its launching position, before the launch; the projectile relies for this purpose sealingly, via its base, against a closure element (14) of annular shape, simply

sketched on the drawing.

  The base end of the dynamic effect channel (16) is sealingly closed by a sealing plug (6 ') which bears backwards against the closure element (14), by intermediate of a trigger device (15) simply sketched. To the right of the hollow projectile (4 '), is the gas mixture strongly compressed in the tube

acceleration (1).

  Alternatively, it is possible, in place of the triggering device (15) and the sealing plug (6 '), to have at the rear of the projectile (4, 4') of Figures 4a and 4b the rearmost membrane (2) of the chamber (3) as shown in Fig. 1b. After the release of the sealing plug (6 '), or after the destruction of the membrane (2), the mixture of gas escaping backwards, flows at the front part of the projectile (4, 4 '), around the projectile (Figure 4a) or through it (Figure 4b), with a speed lower than the speed of sound in the gas mixture The speed of sound is reached in the most narrow channel dynamic effect channel (16) In the rear part of the projectile (4, 4 '), the flow velocity is greater than the speed of the sound The combustible gas mixture is ignited in the rear area of the projectile, for example by

  firing device (8) already mentioned (Figure 3).

  When the triggering device (15) is actuated, it releases the shutter cap (6 ') which is blown, by the mixture of strongly compressed gas, to the rear (in the drawing to the left), out of the channel dynamic effect (16), which is then traversed by the gas mixture which relaxes It undergoes, because of an independent firing, a combustion behind the base of the projectile which is practically not covered by the closing element, and exerts on it, an action accelerating the projectile (to the right on the

drawing).

  Figures 5 and 6 each represent a cross section of the acceleration tube (1), at a location behind the projectile at rest, before the

launch.

  According to FIG. 5, electric heating filaments (11) are stretched through the free inner section of the acceleration tube (1) and are incandescent at launching, causing the gas mixture exiting out of the air to ignite. channel to

  dynamic effect (16) at launch.

  The filaments can also be without electrical connection, and improve the ignition by the fact that they are heated and brought to

  incandescence by the flow of gases.

  In the case of Figure 6, a firing device (12) is fixed centrally on radial ribs (13); this firing device may be constituted by an electric heating element, a heating element without connection, a pyrotechnic ignition device ignited electrically or chemically, or a pyrotechnic ignition device initiated by the still low temperature of the mixture of gas initially escaping, or also by a catalyst or a reagent, which ignites the gas mixture

  by contact or reaction with it.

  The firing device shown in Figures 5 or 6, is located behind the projectile, but at the front of the piston (6) or the closure cap (6 '), and can be attached thereto or on the wall of the tube

acceleration (1).

Claims (13)

  A method for accelerating a projectile in a tube having a closed chamber filled with a mixture of flammable gas under pressure, establishing a relative speed between the projectile which forms in the tube a dynamic effect channel of the nozzle type, wherein flowing the gas mixture, and the gas mixture, and producing the combustion of the gas mixture behind the narrowest section of the dynamic effect channel, the projectile forming a ramjet moving against the gas mixture , characterized in that the projectile is arranged at least approximately in a fixed position in the tube, the chamber is open at its rear end, so that the gas mixture therein is forced to escape from the tube to the rear, and on this occasion, to move relative to the projectile, and the gas mixture is fired behind the narrowest section of the dynamic effect channel, from   so that the projectile is accelerated relative to the tube.   2 Process according to claim 1, characterized in that the projectile 'is disposed behind a membrane closing the chamber towards the rear, and outside the chamber, by destruction or perforation of the membrane, the gas mixture is constrained to flowing against the projectile, and the pressure of the gas mixture is adjusted so that the flow against the projectile   is carried out with a supersonic relative speed.   according to claim 1, 3 characterized in that the projectile is disposed at the rear end of the chamber, inside thereof, the outlet of the gas mixture out of the chamber is caused behind the projectile, and the gases of the mixture then flow against this projectile first with a speed relative subsonic.   4 accelerator tube with dynamic effect for implementing the method according to claim 1 and / or 2, comprising an acceleration tube and a projectile forming therein a dynamic effect channel of the nozzle type which extends continuously; from its front side to its rear side, at least one chamber closed on each side by a membrane and which can be filled with a mixture of flammable gas, under pressure, being formed in the acceleration tube, the assembly also comprising a support housing disposed behind the chamber and coaxially with the acceleration tube, and intended to receive the projectile at rest, before its acceleration, characterized in that the support housing (10) directly adjoins the chamber (3) or the chamber (3) located at the rear, and that a device is provided for   destroy the membrane (2) directed towards the projectile (4).   Dynamically accelerating accelerator tube for carrying out the method according to claim 1 and / or 3, comprising an acceleration tube and a projectile forming therein a dynamic effect channel of the nozzle type which extends continuously from its front side to its rear side, at least one closed chamber on each side preferably by a membrane and can be filled with a mixture of flammable gas under pressure, being formed in the acceleration tube, the assembly also comprising a suppcrt housing disposed coaxially with the acceleration tube, and intended to receive the projectile at rest, before its acceleration, characterized in that the support housing is disposed inside the chamber (3), or the chamber (3) located at the rear, and at the rear end of this chamber, and in that there is provided a device for opening the rear end of this chamber, behind the projectile. Dynamic accelerator tube according to claim 4, characterized in that the support housing (10) is essentially open on the rear side. 7 Accelerator tube with dynamic effect according to   one of claims 4 to 6, characterized in that   behind the projectile (4) is a piston slide (6).   8 accelerator tube dynamic effect according to claim 7, characterized in that the piston (6) is fixed so as to be torn off, on the base of the projectile. 9 accelerator tube dynamic effect according to claim 7, characterized in that the piston is formed in the form of a closure plug (6 ') removably disposed in the outlet of the channel to dynamic effect (16).   10 Accelerator tube with dynamic effect according to   one of claims 4 to 9, characterized in that the   support housing (10) is disposed in the rear part of the acceleration tube (1), and in that the acceleration tube (1) preferably extends further beyond   from the back of the support housing (10).   11 Accelerator tube with dynamic effect according to   one of claims 4 to 10, characterized in that   chamber (3) and the corresponding membranes (2) are designed to absorb a higher internal pressure   to, and preferably equal to about 100 to 105 Pa.   12 Accelerator tube with dynamic effect according to   one of claims 4 or 6, characterized in that   the projectile warhead has a device for   perforate the membrane (2) nearest.   Dynamically accelerating tube according to claim 10, characterized in that the projectile ogive is formed as a firing pin, and in that a percussion device is provided with which the projectile (4) can to be pushed back against the membrane (2).   14 Accelerator tube with dynamic effect according to   one of claims 4 to 11, characterized in that   there is provided a device separated from the projectile (4; 4 '), for the perforation of the membrane (2) closest to the projectile (4; 4 ').   Dynamically accelerating tube according to Claim 14, characterized in that the perforating device is designed as a striker device. 16 Accelerator tube with dynamic effect according to   one of claims 7 to 15, characterized in that   outer surface of the piston (6), directed towards the projectile (4; 4 '), is carried out in such a way as to trigger a spontaneous firing of the gas mixture striking this outer surface.   17 Accelerator tube with dynamic effect according to   one of claims 7 to 15, characterized in that   outer surface of the piston (6), directed towards the projectile (4; 4 '), carries a firing device   (8), preferably of the pyrotechnic type.   Dynamic accelerator tube according to claim 17, characterized in that between the rear of the projectile and the piston (6) is arranged a delay release system, preferably a rupture cord (7), by means of which the firing device (8) can be triggered when a predetermined interval is   reached between the rear of the projectile and the piston (6).   19 Accelerator tube with dynamic effect according to   one of claims 4 to 15, characterized in that   in the zone of the base of the projectile, electric heating filaments (11) are arranged for firing gas mixture.   Dynamic accelerator tube according to   one of claims 4 to 19, characterized in that   is preferably made in the form of a piece of recoilless gun.