FR2982939A1 - Ammunition for e.g. gun, has blades secured to internal surface of passage to allow loading of ammunition with ammunition body during angular acceleration of ammunition around longitudinal axis - Google Patents

Abstract

The ammunition has a spindle (20) in the form of warhead according to a longitudinal axis (XX'), and a cylindrical ammunition body (10) comprising front and rear ends. A truncated base (24) closes the body at the rear end. The body comprises a passage (59) between the ends along a rotation axis (AA'). The passage has ammunition load and blades (AU1, AU3) between the ends around the rotation axis. The blades are secured to an internal surface of the passage to allow loading of ammunition with the ammunition body during an angular acceleration of the ammunition around the longitudinal axis. The ammunition body contains a structural trim made of resin e.g. epoxy charged glass and carbon.

Description

The invention relates to ammunition subjected to firing at significant axial acceleration and roll.

A large number of artillery systems, such as cannons and mortars, use ammunition with a belt. The barrel is provided with internal scratches intended to impart a rotational movement to the ammunition and thus improve its trajectory stability.

Striped ammunition is not only subjected to axial thrust identical to the ammunition smooth, during the activation of their propellant charge, but also, rotated through helical stripes located on the inner wall of the barrel tubes that drive munitions via their belt at a defined helix angle. These belts are generally "striped" type for mortar projectiles or "forcing" type for cannon shells. These munitions are dimensioned such that they are able to withstand the stresses due to the firing environment generated by a propellant charge. This propellant charge is, depending on the ammunition, loaded into a socket or positioned on a tail carrying. The ammunition usually includes a loading, for example a pyrotechnic charge (smoke, explosive, illuminating, etc.), held in the body of the ammunition by internal walls of the ammunition. This loading is, by its chemical composition and according to the ambient temperature, non-solid type, whether pasty, liquid, viscous. During firing, in a so-called "gun-shot" phase, the ammunition is simultaneously subjected to an axial thrust by the propulsive charge and to a rotation by the stripes of the barrel subjecting the body of these ammunition to significant axial acceleration and rolling. . The internal pyrotechnic charge of the ammunition is generally rotated by the forces of adhesion exerted at the interface "loading / ammunition body" during the firing phase.

The internal loading by its nature is not rigid enough to withstand deformations during firing and tends to settle in the rear of its container (body of the ammunition) under the effect of the longitudinal acceleration and to twist (twist) on itself under the effect of angular acceleration. These deformations, which are more or less important depending on the viscosity or hardness of the load, have the effect of degrading the adhesion of the load with its container (ammunition body), to generate stresses greater than the load material resistance. , and thus to create cracks in this material thus degrading the desired end effect and generating possible security problems from the "shotgun phase" to the end of the fire safety distance. Regarding liquid-state loading, the problem is different in the sense that they are not in cohesion with their container (ammunition body) because of their state. In this state and according to the viscosity, this type of loading is rotated more or less rapidly, thus generating a difference in angular velocity more or less important between the load and its container (ammunition body).

After the firing phase follows a phase called "ballistic flight phase" of the ammunition, a pasty loading that is no longer under the effect of angular and axial accelerations, tends to return to its original shape by restoring the potential energy stored during its settlement and torsion. These internal movements of the loading are not in harmony with the kinetics of all the other components of the munition and tend to cause disturbances on the stability of the ammunition in ballistic flight. These disturbances are even more significant for a liquid-type loading which, not being in cohesion with the container, that is to say with the body of the munition and having a difference in angular velocity with respect to its container, tends to harmonize during the "flight phase" with it, which has the consequence of increasing the speed of rotation of the load at the expense of the rotational speed of the ammunition which falls as a function of the masses involved, the coefficient of friction between the load and the body of the munition (adhesion) and the geometry of the container. Internal movements due to loading deformations and reduced gyroscopic effect due to reduced ammunition angular velocity can cause the munition to be less stable during the "flight phase", to be more sensitive to external stresses encountered on its trajectory and eventually miss the target. To overcome the drawbacks of ammunition of the state of the art, the invention proposes a munition comprising along a longitudinal axis XX ', a warhead-shaped rocket, a munition body of cylindrical shape of axis of revolution AA 'coincides with the longitudinal axis XX' having two ends, a front end on the side of the fuze and a rear end, a cap closing the ammunition body at the rear end of the ammunition body, the ammunition body comprising in its axis of revolution AA 'a passage between its two ends having an inner surface of circular section, characterized in that the passage in the ammunition body comprises, between its two ends, a munition load, n blades Aul, Au2, .. Aui, ... Aun around the axis of revolution AA 'integral with the inner surface of the passage to drive the loading of ammunition with the ammunition body during an angular acceleration of the ammunition around its longitudinal axis (1), i being the rank of the blade, n being equal to or greater than 2. In one embodiment, the munition according to the invention comprises between the rocket and the ammunition body a spark gap tube for activation. ammunition load, the circular cylindrical spark tube having an outer portion of spark gap tube connecting the rocket to the ammunition body and a spark gap tube body within the ammunition body. In another embodiment, the ammunition body has an ammunition body wall having, an outer surface, an inner surface of diameter Dpi gradually decreasing toward the front end of the ammunition body to form a circular opening for the passage of the body. of the discharge tube inside the ammunition body.

In another embodiment, the munition body has in the axis AA 'a circular cylindrical section tube of internal diameter D3 integral with its outer surface of diameter Dt ammunition body, the inner surface of the tube forming the passage comprising, between its two ends, the loading of ammunition, the n blades Aul, Au2, .. Aui, ... Aun around the axis of revolution AA '. In another embodiment, the tube is secured to the munition body 10 over the entire outer surface of the tube by a resin filling the space between the outer surface of diameter Dt of the tube and the inner surface of the wall of the ammunition body . In another embodiment, the tube is integral with the base by means of an open bottom having a ring-shaped front body integral with the end of the tube on the base side, of external diameter equal to the external diameter Dt tu tube, said front body extending towards the base by a rear tube portion of diameter D2 less than the outer diameter Dt of the tube having a bottom thread on its outer surface 20 for fixing it by screwing into the base. In another embodiment, the wall of the munition body has a rear opening of diameter D1 having on its inner surface a wall thread for screwing the cap on said rear opening, the cap, closing the rear opening of the ammunition body. , extending, on the side of the munition body, by a ring-shaped base portion, of axis of revolution coincident with the axis AA ', having a circular outer surface of the same diameter D1 having a base thread intended for to be screwed onto the wall threading to make the base of the munition body integral, and a pellet inside surface of diameter D2. In a first variant of the munition, the tube is a profiled tube having a complete geometry including, inter alia, the blades Aul, Au2, .. Aui, ... Aun, each of the blades protruding from the end of the tube face at the base of the munition a length Da forming blade sections to achieve a mechanical connection between the tube and the base. In this first variant, the blade sections of the blades Aul, Au2, Aui, ... Aun are inscribed in a surface of circular cross-section of axis coincident with the axis AA 'and of diameter D1 less than the diameter. D3 of the inner surface of the tube to achieve a rigid mechanical connection between the tube and the base of the type "centering".

In another embodiment of this first variant, the mechanical connection between the blade sections and the base is of the "glued" or "welded" type. In a second variant of the ammunition, the munition body contains a structural resin lining forming in one single block the tube, the resin and the blades Aul, Au2, Aui, ... Aun. the ammunition body being first equipped with the structural resin lining, then closed by the base by screwing the cap at the rear end of the ammunition body.

In this second variant, the structural resin lining comprises the internal surface of internal diameter D3 forming the passage for the loading of ammunition, the blades Aul, Au2, .. Aui, ... Aun protruding by blade sections of Da length to achieve a rigid mechanical connection with the base.

In a third variant, the ammunition body wall and the structural lining forming the tube and the blades Aul, Au2, Aui, ... Aun are made in a single block obtained by casting.

In a fourth variant, the munition body comprises a front part of the ammunition body and a rear part of ammunition body of cylindrical shapes along the axis of revolution AA 'and secured to each other by screwing, the part rear of the ammunition body and the base being in a single block open on the side of the ammunition front portion by a circular body opening having a thread for screwing the front part of the ammunition body on the rear part of the ammunition body the rear part of the ammunition body containing the structural resin packing forming in one single block the tube, the resin and the blades Aul, Au2, Aui, ... Aun, the structural resin packing being deposited at the inside the ammunition body rear part through the circular body opening. In the embodiments of the munition according to the invention, the resins are chosen from resins of glass-filled epoxy type, carbon or others, having sufficient mechanical strength to replace the tube by including in its geometry the internal diameter D3 with the n blades Aul, Au2, .. Aui, ... Aun. In another embodiment of the munition, the blades Aul, Au2, Aui, ... Aun, are inclined with respect to the axis AA 'and of a shape chosen from straight or curved shapes. In another embodiment of the ammunition, the blades consist of portions of vanes distributed linearly discontinuously along the length of the tube. In another embodiment of the munition, at each discontinuity, a determined blade portion has an angular position different from the next or previous blade portion with respect to the axis AA '. In another embodiment of the ammunition, the end of the tube on the base side, inside said inner diameter tube D3, is equipped with a multitude of mini blades of smaller size than the blades Aul, Au2 .. Aui ... Aun. A main objective of the ammunition according to the invention is to increase the adhesion surface of the loading of the ammunition with the ammunition body during angular accelerations in the "cannon" phase, but also to reduce the settlement. loading by the longitudinal acceleration in the rear part of the loading compartment of the munition.

Another objective is to limit the formation of cracks in the material constituting the loading when this material is in the solid state. The invention will be better understood by descriptions of embodiments of ammunition according to the invention with reference to the indexed drawings in which: FIG. 1a shows an axial view of a munition according to the invention; FIG. 1b shows an axial sectional view of the munition of FIG. - Figure I c shows a sectional detail of the front end of the ammunition of Figure 1b; - Figure 1 d shows a sectional detail of the rear end of the ammunition of Figure 1b; FIG. 1e shows a section of the ammunition of FIG. 1a in a plane normal to the ammunition; FIG. 1f shows an exploded perspective view of the ammunition of FIG. 1b; FIG. 2a shows an axial view of a first variant of the ammunition according to the invention; - Figure 2b shows a sectional view of the ammunition of Figure 2a in the plane normal to the munition; FIG. 2c shows a detail in section of the rear end of the ammunition of FIG. 2a; Figure 2d shows an exploded perspective view of the ammunition of Figure 2a; FIG. 2e shows a detailed view of the ammunition of FIG. 2d; - Figure 3a shows an axial view of a second variant of the ammunition according to the invention. ; Figure 3b shows a sectional view of the ammunition of Figure 3a in the plane normal to the ammunition; FIG. 3c represents an axial sectional view of the munition body of the ammunition of FIG. 3a; FIG. 4a shows an axial view of a fourth variant of the munition according to the invention and - Figure 4b shows a sectional view of the ammunition of Figure 4a in the plane normal to the munition. Figure 1a shows an axial view of a munition according to the invention. Figure 1b shows an axial sectional view of the munition of Figure 1a. The ammunition of FIGS. 1a and 1b of a cylindrical shape along a longitudinal axis 0 'comprises a front part intended to be directed towards a target and a rear part, the munition essentially comprising between its front part and its rear part. a warhead-shaped rocket 20, a munition body 10 of cylindrical shape with axis of revolution AA 'coinciding with the longitudinal axis) 0 (' having a front end and a rear end, a base 24 closing the body of The warhead-shaped rocket 20 is connected via a ring 26 and a spark gap tube 22 to the front end of the munition body 10. The adapter ring 26 is optionally available depending on the type The circular cylindrical discharge tube 22 has an outer portion of spark gap tube 28 and a spark gap tube body 30 within the ammunition body 10. The outer portion of the frustoconical shaped spark-gap tube 28 extends continuously. the on outer face of the munition body 10 with the adapter ring 26. The base 24 is of frustoconical shape with a small slope of axis of revolution coincides with the axis AA 'whose smallest diameter forms the rear end of the ammunition. The munition body 10 has a circular cylindrical munition body wall 31 having an outer surface 32 of outer diameter Dpe and an inner surface 33 of inner diameter Dpi forming a compartment 36 for loading the munition. The diameter Dpi of the inner surface 33 of the munition body wall 31 progressively decreases in diameter towards the front end of the munition body to form a circular opening 40 for the passage of the body of the spark gap tube 30 within the housing. ammunition body 10. This opening 40 is used for loading the ammunition with a loading of ammunition liquid or pasty type. The wall 31 has on the side of its end facing the base 24 a rear opening 42 of diameter D1 and on the inner surface 33 of the wall a wall thread 44 for closing the ammunition body 10 on its rear end side by the pellet 24.

Figure 1c shows a sectional detail of the front end of the ammunition of Figure 1b. Figure 1d shows a sectional detail of the rear end of the ammunition of Figure lb. Figure 1c shows the mounting of the spark gap tube 22 in the circular opening 40 closing the munition body 10 on the side of its front end. The compartment 36 of the munition body 10 comprises in the axis of revolution AA 'a tube 50 of circular cylindrical section of external diameter Dt having an outer surface 56 and an inner surface 58 of circular section of internal diameter D3 forming between the two ends of the tube a passage 59 and, according to a main feature of the invention, integral with the inner surface 58 of the tube 50, four vanes Au1, Au2, Au3, Au4 in the form of rectangular flats regularly distributed at angles of 90 ° on the inner surface of the tube. The four blades have two long sides b1, b2 parallel to the axis of revolution AA 'and two small sides b3, b4 perpendicular to the short sides. Each blade is secured by one of the long sides b1 of the inner surface 58 of the tube 50 the other large free sides b2 are inscribed in a circular cylindrical surface axis coinciding with the axis of revolution AA 'and diameter Dau. The tube 50 is integral, on the side of a rear end facing the base 24 of the munition, by an open bottom 60 of circular cylindrical shape of axis of revolution coincident with the axis AA 'having, on the end side rear of the tube, a front body 64 (see FIG. 1d) in the form of a ring of external diameter equal to the outside diameter Dt tu tube, said front body 64 being extended by a rear tube portion 66 of diameter D2 smaller than the diameter D1 of the base having a bottom thread 68 on its outer surface for its fixing by screwing into the base 24. The base 24 closing the rear opening 42 of diameter D1 of the munition body 10 is extended, on the side of the ammunition body 10, by a crown portion 69 in the form of a ring of axis of revolution coincident with the axis AA '35 having a circular external surface 70 of diameter D1 having a base thread 72 intended to be screwed onto the wall thread 44 to make integral the base 24 the ammunition body 10, and an inner surface 73 having another thread 74 for screw fastening the rear tube portion 66 of diameter D2 in the other thread 74 of the base 24.

The outer surface 70 of the base 24 is extended by another outer surface 75 aligned on the outer surface 32 of the munition body 10 forming another base shoulder 76 for blocking the base during its screwing into the munition body. The base 24 is closed on the side of the rear end of the munition body 10 by a bottom wall 80 of conical or other shape closing the compartment 36 for loading the ammunition. In this embodiment of Figures 1a to 1d, the tube 50 is integral on the one hand, the base 24 through the open bottom 60 and on the other hand, the munition body 10 on the entire outer surface 56 of the tube 50 15 by a resin 90 filling the space between the outer surface 56 of outer diameter Dt of the tube 50 and the inner surface 33 of the wall 31 of the ammunition body 10. Figure 1 e shows a section of the ammunition of Figure la in a plane normal to the ammunition. Figure 1f shows an exploded perspective view of the ammunition of Figure 1b. In this assembly state of FIG. 1b, the loading of the ammunition is introduced into the compartment 36 (volume reserved for loading) and in the passage 59 of the tube 50 by circular opening 40 of the ammunition body 10, the loading of The munition is then in contact and adhesively bonded to the inner diameter D3 of the tube 50, embedding the four blades Aul, Au2, Au3, Au4. Thus, during the "gunshot phase" the ammunition body 10 drives in rotation, via the resin 90, the tube 50 which itself rotates the loading thanks to its four blades Aul, Au2, Au3, Au4, those it being dimensioned in such a way as to guarantee an efficient entrainment of the ammunition load on its periphery, taking into account the state of the material to be entrained, whether of the pasty, liquid or viscous type.

The shape, the repartions of the blades is not limited to the embodiment of Figures la to 1f. In other embodiments, the blades could be in a larger or smaller number, of shapes inclined relative to a generatrix of the inner surface 58 of the tube 50, or curved, or other forms. The blades may also be distributed linearly and angularly discontinuously over the length of the tube 50, significantly reducing the difference in angular velocity between the loading of the munition, for example in the liquid state, and its container, that is to say say the tube 50.

The blades cause all of the material located in the periphery in the wake of the blades and most of the material located at its center knowing that the latter puts little weight in play, and therefore generates only minor disturbances, almost without effect on the overall behavior of the ammunition in "flight phase".

The blades in the tube 50 also make it possible to increase the gripping surface (adhesion) of the load with the mechanical structure of the munition and to reduce its settlement in the rear part of its container (ie the tube 50). and thus to limit the formation of possible cracks in its material (especially in solid state). Figure 2a shows an axial view of a first variant of the ammunition according to the invention. Figure 2b shows a sectional view of the ammunition of Figure 2a in the plane normal to the ammunition. Figure 2c shows a detail in section of the rear end of the ammunition of Figure 2a. In this first variant, the tube 50 is made from a profiled tube comprising the complete geometry including, among others, the four blades Aul, Au2, Au3, Au4. The blades protrude from the end of the tube 50 facing the base 24 of the munition by blade sections bl a of length Da to form a rigid connection between the tube 50 and the base 24 of the "centering" type. For this purpose, on the one hand, the sections of blade bl has vanes Aul, Au2, Au3, Au4 are inscribed in a circular cross-section of axis coinciding with the axis AA 'and of diameter D1 less than the diameter internal D3 of the inner surface 58 of the tube 50 and, on the other hand, the circular inner surface of diameter D2 of the ring-shaped base portion 69 being smooth, the diameter D1 is close to and slightly greater than the diameter D2 so to ensure a tight fit of the tube 50 with the cap 24. The skilled person can calculate these diameters Dl and D2 to provide this type of centering type connection. It may be noted that the diameter D2 of the base 24 is a complete diameter, while that of the circular section surface in which are inscribed the connection edges b1a is defined by the four surfaces of the edges 10 of b1a connections machined according to the diameter Dl . A simple mechanical adjustment of the "tight" type between the profiled tube 50 and the base 24 is sufficient for the mechanical strength of the profiled tube 50 in the munition body 10, since the resin 90, filling the gap between the surface outer of the profiled tube 50 and the inner surface 33 of the ammunition body is sufficiently rigid to effectively maintain the profiled tube 50 to the ammunition body 10. The objective of the tight type fit between the tube 50 and the base 24 is maintain in position the profiled tube 50 in the axis of the body of the munition 10 before introduction of the resin 90 between the tube 50 and the wall 31 of the ammunition body 10. FIG. 2d shows an exploded perspective view of the ammunition of Figure 2a. Figure 2e shows a detail view of the ammunition of Figure 2d. Fig. 2e shows the diameter D1 of the blade sections b1a and the diameter D2 of the inner surface of the crown shaped portion 69. In a different way, the "centering" type adjustment of the ammunition of FIG. 2a can be replaced by a "glued" or "welded" type connection. Figure 3a shows an axial view of a second variant of the ammunition according to the invention. Figure 3b shows a sectional view of the ammunition of Figure 3a in the plane normal to the munition. In this second variant of the munition according to the invention, the ammunition body 10 contains a structural lining 100 of resin forming in one single block the tube 50, the resin 90 and the four blades Au1, Au2, Au3, Au4. For this purpose the ammunition body 10 is equipped with the structural lining 100 made of resin then the ammunition is closed by the base 24 by screwing on the wall 31 at the rear part of the ammunition body 10.

The structural lining 100 of resin has the inner surface of internal diameter D3 forming the passage 59 for the loading of ammunition, the blades Au1, Au2, Au3, Au4 protruding by blade sections b1b of length Da inside the crown portion 69 in the form of a crown. Figure 3c shows an axial sectional view of the ammunition body of the ammunition of Figure 3a. FIG. 3c shows the ammunition body 10 alone equipped with the resin structural lining 100 before closing the ammunition at the rear by the base 24.

In a third variant not shown in the figures, the wall 31 of the munition body 10 and the structural lining 100 forming the tube 50 and the four blades Au1, Au2, Au3, Au4 are made in a single block obtained by casting.

Figure 4a shows an axial view of a fourth variant of the ammunition according to the invention. Figure 4b shows a sectional view of the ammunition of Figure 4a in the plane normal to the munition. In this fourth variant of the ammunition according to the invention, the munition comprises a front portion 120 of ammunition body 10 and a rear portion 124 of ammunition body 10 of cylindrical shapes along the axis of revolution AA 'and integral with the ammunition body 10. one of the other by screwing. The rear part 124 of the ammunition body and the base 24 are in a single block open on the side of the front part 120 of ammunition by a circular opening 130 having a thread 132 for screwing on the front part 120 of ammunition body. The rear portion 124 of the ammunition body has the inner circular surface 58 closed on the base 24 side by a semi-spherical surface 140 or other shape. The rear part 124 of the ammunition body contains a structural packing 200 of resin forming in one piece the tube 50, the resin 90 and the four blades Au1, Au2, Au3, Au4. The structural packing 200 made of resin is deposited inside the rear portion 124 of the munition body through the circular opening 130. In another embodiment (not represented by figures) of the fourth variant of FIGS. 4a and 4b, the wall 31 the rear portion 124 of ammunition body and structural lining 200 of resin are made in one piece. In this fourth variant, the rear part 124 of the ammunition body with structural lining 200 may be a casting type embodiment. The resins are, for example, glass-filled epoxy type, carbon or otherwise, having sufficient mechanical strength to replace the tube 50 by including in its geometry the internal diameter D3 with the four blades Au1, Au2, Au3, Au4. The shapes of the blades Au1, Au2, Au3, Au4, which are represented in the figures of straight shapes parallel to the axis XX 'of the munition and in one piece along the length of the tube 50, are not limiting and can be also inclined, curved, or have other shapes and dispositions. The blades may consist of portions of vanes distributed linearly discontinuously along the length of the tube with, in addition, at each discontinuity, taking a different angular position. The end of the tube 50 on the base 24 side, inside said inner diameter tube D3, can also be equipped with a multitude of mini blades of smaller size than the n blades Au1, Au2, .. ,. Has a.

Claims (19)

REVENDICATIONS1. Ammunition comprising along a longitudinal axis XX ', a rocket (20) 5 in the form of a warhead, a munition body (10) of cylindrical shape of axis of revolution AA' coincides with the longitudinal axis XX 'having two ends, a front end of the rocket side and a rear end, a base (24) closing the ammunition body at the rear end of the ammunition body, the ammunition body (10) having in its axis of revolution AA 'a 10 passage (59) between its two ends having an inner surface (33) of circular section, characterized in that the passage (59) in the munition body (10) comprises, between its two ends, a munition load, n blades Au1, Au2, .. Aui, ... Aun about the axis of revolution AA 'integral with the inner surface (58) of the passage for driving the loading of ammunition with the ammunition body (10) at a angular acceleration of the munition about its longitudinal axis XX ', i being the rank of the dawn, n being equal to or greater than 2. Ammunition according to claim 1, characterized in that it comprises between the rocket (20) and the ammunition body (10) a spark gap tube (22) for the activation of the ammunition charge, the spark gap tube Circular cylindrical member (22) having an outer spark gap portion (28) connecting the spindle (20) to the munition body (10) and a gap tube body (30) within the munition body (10). ) 25 3. Ammunition according to one of claims 1 or 2, characterized in that the munition body (10) has a munition body wall (31) having, an outer surface (32), an inner surface (33) of Dpi diameter gradually decreasing towards the front end of the munition body to form a circular opening (40) for the passage of the body of the spark tube (30) inside the ammunition body (10). 4. Ammunition according to claim 3, characterized in that the munition body has in the axis AA 'a tube (50) of circular cylindrical section of internal diameter D3 integral with its outer surface (56) of diameter Dt of the body of ammunition (10), the inner surface (58) of the tube (50) forming the passage (59) having, between its two ends, the ammunition load, the blades Au1, Au2, .. Aui, ... Aun around of the axis of revolution AA '. 5. Munition according to claim 4, characterized in that the tube (50) is secured to the munition body (10) on the entire outer surface (56) of the tube (50) by a resin (90) filling the space between the outer surface (56) of diameter Dt of the tube and the inner surface (33) of the wall (31) of the munition body (10). 6. Ammunition according to one of claims 4 or 5, characterized in that the tube (50) is integral with the base (24) via an open bottom (60) having a front body (64) shaped secured to the end of the tube on the base side, of external diameter equal to the outer diameter Dt tu tube, said front body (64) extending towards the base (24) by a rear tube portion (66) of diameter D2 less than the outer diameter Dt of the tube having a bottom thread (68) on its outer surface for fixing it by screwing into the base (24). 7. Ammunition according to one of claims 3 or 4, characterized in that the wall of the munition body (31) has a rear opening (42) of diameter D1 having on its inner surface a wall thread (44) for the screwing the cap on said rear opening (42), the base (24), closing the rear opening (42) of the ammunition body (10), extending, on the side of the ammunition body, by a base portion (69) ) in the shape of a ring, of axis of revolution coincident with the axis AA ', having a circular outer surface (70) of the same diameter D1 comprising a base thread (72) intended to be screwed onto the wall thread (44). ) to make integral the base (24) of the munition body (10), and an inner surface of base (73) of diameter D2.35 8. Ammunition according to claim 4, characterized in that the tube (50) is a profiled tube having a complete geometry including, inter alia, the blades Au1, Au2, .. Aui, ... Aun, each of the blades exceeding the end of the tube (50) facing the base (24) of the munition a length Da forming blade sections (b1a) to achieve a mechanical connection between the tube and the base (24). 9. Ammunition according to claim 8, characterized in that the blade sections (b1a) of the blades Au1, Au2, .. Aui, ... Aun are inscribed in a circular cross section of axis coincides with the AA 'axis and of diameter Dl less than the internal diameter D3 of the inner surface (58) of the tube (50) to achieve a rigid mechanical connection between the tube (50) and the base (24) of type "centering". 10. Ammunition according to claim 8, characterized in that the mechanical connection between the blade sections (b1a) and the base is of the type "glued" or "welded". 11. Ammunition according to claim 5, characterized in that the munition body (10) contains a structural lining (100) of resin forming in one single block the tube (50), the resin (90) and the Au1 blades, au2 .. Aui ... Aun. the munition body (10) being first equipped with the resin structural lining (100) and then closed by the base by screwing the cap to the rear end of the munition body. 12. Ammunition according to claim 11, characterized in that the structural lining (100) of resin has the internal surface (33) of internal diameter D3 forming the passage (59) for the loading of ammunition, the blades Au1, Au2, ..Aui, ... Aun protruding by blade sections of length Da to achieve a rigid mechanical connection with the base (24). 13. Ammunition according to claim 11, characterized in that the wall (31) of ammunition body (10) and the structural lining (100) forming tube (50) and the blades Au1, Au2, .. Aui, .. .Aun are made in a single block obtained by foundry. 14. Ammunition according to claim 4, characterized in that the munition body comprises a front portion (120) of ammunition body (10) and a rear portion (124) of ammunition body (10) of cylindrical shapes according to the axis of revolution AA 'and secured to each other by screwing, the rear portion (124) of ammunition body and the base (24) being in a single block open on the side of the front part (120) of ammunition by a circular body opening (130) having a thread (132) for screwing the ammunition body forward portion (120) onto the ammunition body rear portion, the ammunition body rear portion (124) containing the ammunition body structural resin lining (200) integrally forming the tube (50), the resin (90) and the Au1, Au2, Auil, ... Aun blades, the resin structural liner (200) being deposited inside the rear body portion (124) of the ammunition body through the circular body opening (130). 15. Ammunition according to one of claims 4 to 14, characterized in that the resins are chosen from epoxy type glass filled resins, carbon or other, having sufficient mechanical strength to replace the tube (50) including in its geometry, the internal diameter D3 with the blades Au1, Au2, .. Aui, ... Aun. 16. Munition according to one of claims 1 to 15, characterized in that the blades Au1, Au2, .. Aui, ... Aun, are inclined relative to the axis AA 'and of a shape selected from the forms straight or curved. 17. Ammunition according to one of claims 1 to 16, characterized in that the blades consist of portions of vanes distributed linearly discontinuously along the length of the tube 50. 18. Ammunition according to claim 17, characterized in that, at each discontinuity, a blade portion determined has an angular position different from the next or previous blade portion relative to the axis AA '. 35 19. Ammunition according to claim 4 to 18 characterized in that the end of the tube (50) of the base (24) side, inside said inner diameter tube D3, is equipped with a multitude of mini blades of smaller than the Au1, Au2, .. Aui, ... Aun. 10