FR2688302A1 - FURTIVE PROJECTILE LAUNCHER. - Google Patents

Abstract

The projectile launcher of the invention comprises a launcher tube (4) comprising at its base a spring-loaded energy storage device (5). During the launch, the device 5, which was in the compressed state, is unlocked, and makes it possible to launch the projectile (7) vertically, then the projectile tilts (firing of impellers) and its conventional thrusters are fired. .

Description

i

FURTIVE PROJECTILE LAUNCHER

  The present invention relates to a launcher of

stealth projectiles.

  To launch projectiles such as rockets, rockets or missiles, powder launchers are generally used which produce a flame when the projectile leaves. This flame makes it easy to identify the place of launch, and therefore

  to easily direct enemy fire in order to destroy the launcher.

  Furthermore, gas launching devices are known which are much more discreet, but require transport on the

  place for launching heavy and bulky gas cylinders.

  The subject of the present invention is a device for launching projectiles which is stealthy, visually and

  acoustically, very inexpensive, light and space-saving.

  The projectile launching device according to the invention comprises a launching base that can be oriented in deposit and / or in elevation, and supporting a launching tube comprising a

  energy accumulator with spring launcher adjustable in deposit.

  The present invention will be better understood on reading

  the detailed description of an embodiment, taken as

  of nonlimiting example and illustrated by the appended drawing, in which: FIG. 1 is a sectional view of a launching device according to the invention with its projectile ready to be launched; Figure 2 is a top view of the device of Figure 1 Figure 3 is a sectional view of the locking and tripping device of the device of Figure 1; Figure 4 is a schematic view explaining the launching of projectiles using the device of Figure 1, with rotation of 90 in elevation of the projectile; Figure 5 is a top view of the support of Figure 4; FIG. 6 is a schematic view explaining the launching of projectiles using the device of FIG. 1, with rotation of any angle in elevation of the projectile, and

  FIG. 7 is a top view of the support of FIG. 6.

  The device described below makes it possible to launch a projectile, guided or not, self-propelled, according to a fairly precise initial trajectory For this purpose, the projectile is launched vertically with

  a determined initial speed, without any noticeable noise or flames.

  When this projectile reaches its peak, it is tipped over and its self-propelling system is turned on to make it then follow

a determined trajectory.

  The projectile launcher making it possible to obtain said initial speed is schematically represented in FIG. 1 It comprises a base 1 provided with adjustable feet (not shown, or similar device, making it possible to orient vertically or according to a

  determined angle) the longitudinal axis 2 of its launch tube.

  The base 1 supports, by means of a bearing or a bearing 3, a launching tube 4 The bearing 3 makes it possible to orient the tube 4 in bearing. A buffer 1 A is interposed between the tube 4 and the base 1 energy absorber, for example rubber The tube 4 contains, at its lower part, a spring energy storage device According to the preferred embodiment shown in the drawing, the device 5 consists of a stack of Belleville washers ( These Belleville washers are preferably made of composite material (for example epoxy and reinforcement based on carbon or glass fibers, or KEVLAR based). The Belleville washers are kept compressed in the tube 4 using 'a locking device 6 described in more detail below with reference to Figure 3 This compression can be performed either in the factory during the manufacture of the base, or before use, using a mechanical device ical, pneumatic or hydraulic suitable The

  Lock 6 also serves to fix a projectile 7 in the tube 4.

  The tube 4 is closed at its upper end by a cover 8.

  The base 1 has a mark 9 allowing it to be oriented geographically with respect to the terrain on which it will be installed for shooting For example, this mark will have to be oriented to the North The tube 4 also has a mark 9 A, which is for example aligned with the reference mark 9 in the initial position When the target deposit has been designated, the tube 4 is rotated by the desired angular value around its axis 2 The base 1 having a very precise orientation, it is therefore easy to '' orient the tube 4 (by rotating it around the axis 2) so that the projectile 7 is sent in the desired direction, the projectile itself having a determined orientation relative to the tube 4 (depending on the impellers of

  used, and described below).

  The orientation of the tube 4 can be carried out either manually or automatically. In the first case, the tube 4 also carries a mark, corresponding to the direction in which the rocking of the projectile takes place (as described in more detail below). The base 1 then has graduations

  angular on one of which it suffices to align the reference of the tube 4.

  In the second case, the tube 4 is driven by a motor (not shown) controlled by a servo device (not shown), and is integral with an angular measurement device connected to this servo device, which is by elsewhere connected to a data entry device (for example a keyboard)

  providing the desired angular value of the objective bearing.

  The energy absorbing device 1 A can be a simple rubber washer of the VIBTENE type (of density between 1.2 and 1.5 for example) which has a thickness of approximately 10 mm for

  a projectile weighing approximately 10 kg mass.

  The roles of the locking device 6 shown in detail in FIG. 3 are to lock the projectile 7 in place in the tube 4, to retain the energy stored in the spring devices 5 as soon as they are compressed, and, at the time launching projectile 7, unlocking the projectile and releasing

  suddenly said stored energy.

  According to the embodiment of Figure 3, the device 6 comprises a tube 10 whose axis coincides with the axis 2, which is fixed to the bottom 4 A of the tube 4, and which is closed by a cover A to its upper end This tube 10 passes through the axial bore 11 of a retaining plate 12, the outside diameter of the tube 10 being practically equal to the diameter of the bore of the plate 11 The bore 11 comprises, approximately mid-thickness of the plate 12, a groove 13 with semicircular section This groove 13 extends perpendicular to the axis 2, and the radius of its section is

  substantially equal to the radius of the retaining balls described above

below.

  The length of the tube 10 is approximately equal to or slightly greater than the thickness of the stack of uncompressed Belleville washers 5 and of the plate 12 Thus, as shown in FIG. 3, when the washers 5 are compressed against the lower wall plane of the tube 4, the upper end of the tube 10 protrudes from the plate 12, and it is this end which is introduced into an axial housing 14 of corresponding dimensions formed at the lower part of the projectile 7 In the housing 14, a groove 15, identical to groove 13, for example approximately one third of the depth of housing 14 from the rear face of the projectile (that applied against the plate 12).

  It is practiced in the cylindrical wall of the tube 10 opposite

  screws of the grooves 13 and 15 when the washers 5 are compressed and the projectile 7 pressed against the plate 12, two series of through holes 1 OB These holes, for example three or four for each series, are regularly distributed around the periphery

of tube 10.

  A solid cylindrical core 16 is housed in the tube 10.

  Its diameter is practically equal to the inside diameter of the tube 10 in which it can move axially with gentle friction The core 16 is actuated by an axial rod 17 which is integral therewith and which crosses the bottom 4 A of the tube 4 The rod 17 is it -even

  operated, not shown, either manually or automatically

  matically, and can be locked axially in position.

  The core 16 has at its periphery a first wide groove with flared edges 18, the depth of which is substantially equal to the radius of the locking balls 20 and the

  width slightly greater than twice the diameter of these balls.

  The core 16 has a second flared groove 19 of the same depth as the groove 18, but of width substantially equal to the diameter of said balls. These grooves 18, 19 are formed so as to be located opposite the holes 1 OB when the core 16 is in the high unlocking position, that is to say in abutment against the cover 10 A of the tube 10 and so that only the groove 18 is in front of the upper holes 10 B when the core 16 is in position "medium" In FIG. 3, the core 16 is shown on the left of the axis 2 in the high position, and on the right in the medium position.  To lock the launcher device,  we put the core 16 in the high position,  and the balls 20 are introduced into the corresponding holes 10 B of the tube 10 Because the grooves 18 and 19 are opposite the holes 1 OB,  the balls 20 arrive flush with the outer surface of the tube 10 They can be held in place during the arming of the launcher using an appropriate paste The Belleville washers and the plate 12 are placed on which the pressure required,  and lower the core 16 to the middle position,  for which the balls 20 of the lower holes B are driven by the core into the groove 13,  thus locking the plate 12 in the position for which it keeps the washers 5 compressed. The upper part of the tube 10 is then capped with the projectile 7,  and lower the core 6 to the low position,  which drives the balls 20 from the upper holes 10 B in the groove 15,  thus locking in place the projectile 7 against the plate 12 Because in the low position,  the core 6 does not have a groove facing the grooves 13 and 15,  the two series of balls 20 then lock both the washers 5 and the projectile 7 in the "ready to launch" position. Of course,  in the low or middle position of the core 6,  the rod 17 can be blocked using an appropriate means,  for example by a locking screw,  which makes it possible to transport the launcher device with or without a projectile from the place where the washers 5 have been compressed with appropriate tools,  and even to put the projectile in the launcher shortly before its launch while keeping the washers 5

  compressed (core 6 in the middle position).

  Schematically shown in Figures 4 and 5 the first phase of the trajectory of the projectile 7 The base 1 being adjusted in the firing position, that is to say that the axis 2 of the tube 4 is for example vertical, and the mark 9 of the base 1 as well as mark 9 A of the tube 4 are oriented geographically, for example to the North The deposit G of the target then being determined in a manner known per se, the tube 4 is turned by the value G and it is locks in this position (mark 9 'A in the direction D of the target, in the figure) When firing, the rod 17 of the core 6 is pushed in the middle position to release the projectile, then in the high position to release the plate 12 , which allows the washers 5 to suddenly relax and vertically launch the projectile 7 The projectile 7 rises to a climax, at a height H, which is a function of the characteristics of the washers 5 and the weight of the projectile For example , for a 10 Kg mass projectile, with a stack ement of steel washers with an outside diameter, at rest of 0.12 m, with a thickness of 6 mm, this stack having a height of 34 cm at rest and 21 cm in the compressed state, a climax is obtained of a height of approximately 50 m The position of the projectile 7 at this apex, the speed of which is then zero, is shown in solid lines in FIG. 4 At this instant, a measuring device with which the projectile is provided (measurement of the speed of the projectile or of the distance traveled by the projectile, or of time for example) triggers one or more impellers 21 arranged on the projectile and oriented so as to cause it to rock substantially around its center of gravity 22 These impellers, for example pyrotechnic , do not need to be powerful, because their action is exerted when the projectile has a practically zero speed The position of the projectile after rotation of 900 is represented in broken lines in 1 S figure 4 As soon as this rotation is carried out the autonomous propulsion device of the projectile 7 is fired, and this projectile heads in the direction D towards the designated target Since the propulsion device of the projectile 7 is only fired when this projectile is at an altitude relatively high, it is very difficult for an observer in the target area to determine the place of launching of the projectile, especially since if it is based on the trajectory of the projectile after rotation of 90, it is brought usually determine a launch location

  theoretical which can be very far from the actual launch site.

  The explanatory diagrams of FIGS. 6 and 7 are similar to those of FIGS. 4 and 5, the difference being that after reaching its peak, the projectile 7 performs, under the thrust of

  its impellers 21 'a rotation of a site angle other than 90.

  S + for a rotation less than 90 or S for a rotation greater than 900 The rotation S + can for example allow to reach flying targets, while the rotation S can for example allow to reach relatively close targets, but hidden by high obstacles (buildings, rocks) lying between them and the launching site. It is therefore sufficient for the apogee to be at a height H greater than that of these obstacles. According to a variant of the invention, an additional propulsion can be applied to the projectile when it reaches its peak, before it tips over. According to yet another variant, the tube 4 can contain several "stages" each comprising a projectile and its

  stack of washers 5 (or equivalent spring device).

Claims (8)

  1 Stealth projectile launcher, characterized in that it comprises a launching base (1) orientable in deposit and / or in site and supporting a launcher tube (4) comprising an accumulator   spring energy (5), directional launcher.   2 Launcher according to claim 1, characterized in that the spring energy accumulator comprises a stack of Belleville washers.   3 Launcher according to claim 2, characterized in that   that the Belleville washers are made of composite material.   4 Launcher according to one of the preceding claims,   characterized by the fact that the base is arranged on the ground, and oriented in   deposit on a reference direction (9).   Launcher according to one of claims 1 or 2,   characterized by the fact that the base is arranged on a flying machine.   6 Launcher according to one of the preceding claims,   characterized in that the projectile (7) has impellers   which rotate it at its peak.   7 Launcher according to claim 6, characterized in that the projectile undergoes an additional thrust before undergoing a rotation.   8 Launcher according to one of the preceding claims,   characterized by the fact that it comprises propellants which are   activated when it reaches its peak.   9 Launcher according to one of the preceding claims,   characterized by the fact that it includes a locking device (6)   of the energy storage device.