FR2519784A1 - Multichannel transmission assembly for pyrotechnic firing signal - uses shock generator to detonate explosive to force metal strips against multiple output relay elements - Google Patents

Abstract

A donor component (2) comprising a shock generates triggers the detonation of an explosive strip (12). This explosive is sandwiched between metallic plates (10) in which strips (30) are presheared to release the energy towards out put relay assemblies (4) mounted in the walls of the metal housing.The explosive is confined laterally by a U shaped steel strip (36). The housing is formed to contain the effects of the detonation and to minimise the effects of lateral detents on the presheared strips in the central cavity (20). This cavity has inclined side walls in which the output relays are mounted while the donor component is mounted in the base. This shape ensures that each output relay is triggered at approx. the same instant.

Description

 The subject of the present invention is a multi-channel transmission device for a pyrotechnic order comprising a relay assembly for lifting parts. It applies in particular in the field of pyrotechnics.

 The realization of future ballistic missile programs will impose, in all areas, increasingly strict reliability and safety specifications, which will affect all the components that make up these missiles.

 Compliance with these specifications for each component requires long and costly test programs. This is particularly true in the field of pyrotechnics where the proper functioning and required reliability of the components can most often only be verified after the fact and only by means of all-or-nothing type controls ", implying a large number of tests to cover all types of atmospheres encountered and to have suitable, if not perfect, statistical bases.

 This is the reason why it seems interesting to move towards components of which the basic operating mechanisms are known so as to be able, from the design stage, to take best account of the objectives of performance, reliability and safety, and to limit the number of tests, therefore their cost and duration.

 However, one of the main aspects of the operation of pyrotechnic chains is the transmission of shocks at the interfaces of the components, this transmission most often taking place, for current components, either by impact of particles, or by projection of a metal plate.

 The first mode of transfer by impact of particles has never been the subject of a realistic modeling, as well as regards the mechanism of formation of particles as that of the shock transmitted during the impact of these.

 On the other hand, the mechanism of plate projection and energy transfer by impact of this allows a much better analysis and physical control of the operating parameters. In fact, the impact of plaque is used to obtain quantitative results on the sensitivity to shock of exifives. This is why, it seems interesting to generalize this mode of operation to the transmission of shocks wherever possible.

 Minimizing the volume and mass of the entire pyrotechnic system on board ballistic missiles, as well as improving operating reliability, also involves reducing the total number of components. This implies, in particular, to centralize the triggering of the pyrotechnic signal and then to distribute this signal to the different pyrotechnic functions by means of detonating multi-channel transmission devices.

 However, the study of the different solutions of existing multi-channel transmission devices shows that these do not meet the objectives of understanding and controlling the shock transmission mechanisms involved in the search for better reliability and better security.

 In these multi-channel devices, the transmission of a pyrotechnic command, from a donor component to several receiver components such as relays, is carried out either by a shock, induced by the impact of particles from the donor component, on the receiver components , or by using the shaped charge effect of a detonating cutting cord to prime the receiving components.

 The subject of the invention is precisely a device for multichannel transmission of a pyrotechnic order meeting the objectives of analysis and verification of shock transmission mechanisms. This device uses the principle of projecting a room and transferring energy by impact of it.

More specifically, the invention relates to a multi-channel transmission device allowing the transmission of a pyrotechnic order of a donor component to several output relays, and comprising a frame on which are mounted the donor component and the relays of output, and a relay assembly ensuring the transmission of said order from the donor component to the output relays, this device is characterized in that the relay assembly comprises at least one moving part attached to a strip of explosive that can be initiated in detonating regime, at one of its ends, by the donor component so that the detonation of the explosive strip causes the moving part to be raised at an angle e, and in that the output relays are mounted on the frame so that their end to receive the pyrotechnic order, transmitted by the raising of the moving part, forms with said moving part, before raising it, said angle e
This device allows an analysis and a physical control of the main parameters related in particular to the lifting of the moving part and to the priming of the output relays under the effect of the impact of the part. Consequently, this transmission device allows '' obtain an evaluation of the reliability and an optimization of the dimensions, better than those obtained with the transmission devices of the prior art whose operation is only verifiable by statistics on test results of the
n type "all or nothing
According to a preferred embodiment of the invention, the donor component is a shock generator comprising percussion means which can generate a shock in the longitudinal axis of the slidable piece, before the lifting thereof.

 According to another preferred embodiment of the invention, the movable part has the shape of a flat plate.

 According to a first variant of this embodiment, the relay assembly comprises a single movable part and a fixed part, integral with the frame and attached to the strip of explosive so that the movable part and the fixed part are located on one side and on the other side of the explosive strip.

 According to a second variant of this embodiment, the relay assembly comprises two moving parts placed side by side on the explosive strip and the output relays consist of two series of relays arranged on either side of said relay assembly.

 According to another preferred embodiment of the invention, the moving part has the form of a hollow tube in which is housed said strip of explosive, which in this case is a cylinder, and the output relays consist of several series of relays arranged symmetrically and all around said tube.

Other characteristics and advantages of the invention will emerge more clearly from the description which follows, given by way of illustration but not limitation, with reference to the appended figures, in which: - Figure 1 shows, schematically, a sectional view of a first embodiment of the transmission device according to the invention; - Figure 2 shows schematically a view in
section along line II-II of Figure 1 - Figure 3 shows an exploded perspective view
tee of the device of FIG. 1, with a part
enlarged; - Figure 4 shows a view comparable to the figu
re 1 illustrating a variant of the first mode of sheave
implementation of the invention transmission device
tion ;; - Figure 5 shows a perspective view of
the relay assembly of the device of FIG. 4 there
buffing the raising of one of the moving parts - FIG. 6 schematically represents a view in
section along line VI-VI of Figure 4; and - Figure 7 shows, schematically, a view in
cutaway of a second embodiment of the
transmission device according to the invention.

 Referring to the different figures, the multi-channel transmission device, in accordance with the invention, allows the transmission of a pyrotechnic command from a donor component 2 to several receiver or output relays 4 whose operating mode is normally normal. detonation. The donor component 2 and the various output relays 4 are mounted on a frame 6, for example metallic, which serves both as a mounting support and for positioning the various elements constituting the multi-channel transmission device. This transmission device also comprises a relay assembly, bearing the general reference 8, ensuring the transmission of the pyrotechnic order from the donor component 2 to the various output relay 4.

 According to the invention, the relay assembly 8 comprises at least one moving part 10, of low thickness and made for example of metal, attached to a strip of explosive 12 which can be started in detonating mode. The initiation in a detonating regime takes place via the donor component 2 and at one of the ends 12a of the strip of explosive. The detonation of this strip of explosive 12, added to the thrust of the detonation products behind the detonation front, causes the moving part 10 to rise with a given speed and angle which can be evaluated theoretically and controlled experimentally. This angle is called the lifting angle of the moving part.

 The moving part 10 then meets the ends 4a of the receiving relays 4 obliquely disposed so as to take account of the angle of lifting. The transmission device of the invention is dimensioned so that the impact speed is sufficient for the receiver relays 4 to be started almost instantaneously in stable detonation regime.

 The plate raising theory shows that, for a given explosive, the speed limit reached by the plate only depends on the ratio of the mass of the plate to the mass of explosive. The operating principle, well mastered on the experimental and theoretical level, is often used to project at high speeds (several thousand m / s) flat metal plates of all thicknesses, so as to obtain calibrated plane shocks.

In Figures 1 to 3 there is shown, schematically, a first embodiment of the multi-channel transmission device according to the invention, comprising a relay assembly of the type with raising of a moving part 10, having the shape of a plate plane of small dimensions apart from the longitudinal dimension. The strip of explosive 12 attached to this plate 10 is also attached to a fixed part 14 having a U-shape (FIG. 3) so that the strip of explosive is sandwiched between the plate 10 and the bottom 14a of said part 14. This part 14 is positioned and fixed by its base 16 on the frame 6 by means of screws such as 15. This part made for example of metal serves as rear confinement to the multi-channel transmission device. This part 14 determines, with the groove made in the frame 6, a sealed cavity 20 (FIGS. 1 and 3) which makes it possible to keep the detonation products of the explosive 12 confined so as, on the one hand, to reduce the effects of the detents lateral on the propulsion of the metal plate 10, and, on the other hand, to contain most of the effects of the detonation in order to avoid external pollution by detonation products. This cavity 20 has, in section, the shape of a right triangle having an angle at the top e
The frame 6 is made so as to contain the effects of the detonation of the explosive strip 12 and to minimize the effect of the lateral detents on the propulsion efficiency of the metal plate 10.

The angle of inclination e of the bottom of the cavity 20 is taken equal to that obtained during the raising of the metal plate 10 caused by the detonation of the explosive 12. In the example given below, concerning the dimensioning of the various elements constituting the device of the invention and the nature of the explosive, the frame 6 is made of light alloy. The walls 22 and 24, constituting this frame (FIG. 2) are about ten mm thick and the angle of inclination B of the bottom of the cavity 20 is of the order of 150.

As mentioned above, the fixed part
14, serving as rear containment for the explosive allows
to contain the effects of the detonation. She permits
also, due to its U shape, to provide part of the lateral confinement of the explosive strip 12. In
the given example of embodiment, this part 14 is
made of steel and its mass is twenty times that of plate 10.

According to the invention the donor component 2 is
a shock generating device which is used to trigger
the detonation of the explosive 12 of the relay assembly 8
raising the plate 10, by its end 12a.

This donor component 2 is preferably a device
tif projecting a metallic lid of dimensions fi
nies, whose operating regime may be the
detonation or deflagration, so that the priming
in stable detonation regime of the explosive-if band
12 is obtained almost instantly on all its ex
end 12a (in less than a few l / lOth of ms), when
of the impact at a given speed of this seal. This o
percule moves in a direction identical to that of the longitudinal axis of the plate 10, before the
raising it.

In addition, the output relays 4, or re
lais receptors 4, operating in detonating regime
are based on secondary explosives of the pentrite type,
hexogen or hexanitrostilbene. They are fixed on the
frame 6 so that their ends or ends 4a
penetrate several tenths of a mm into the cavity
20. The plane 26 in which their ends 4a are situated is parallel to the plane 28 (FIG. 1) of the bottom of
the cavity 20. In other words, their end pieces 4a form
with plate 10, before raising it, a
angle of inclination e which is equal to the angle of rele
vement of the plate 10. In the embodiment
given, the receiver relays 4 are 4 in number and are loaded with compressed hexogen (1.6 g / cm3) in a thin envelope of aluminum alloy.

 The metal plate 10 placed in contact with the explosive 12, only a few tenths of a mm thick, is made, for example, from a material suitable for the explosive used. In the example given below, the material used is a steel 2 / 10th of a mm thick. Furthermore, so as to ensure the projection of a plate 10 adapted exactly to the section of the cavity 20, there is formed on said plate 10 a precision groove 30 corresponding to the dimensions of the cavity (FIG. 3).

 The strip of explosive 12 required to lift and project the metal plate 10 can be a pure cast or compressed explosive, such as pentrite, hexogen or hexanitrostilbene, or a composite explosive of the same type to which added an organic binder of the polybutadiene type, for example injected directly or precut into a plate or sheet of explosive. In the example given, the explosive is pentrite to which a plastic binder has been added, precut in a sheet of flexible explosive 2 mm thick.

 In Figures 4 to 6, there is shown a variant of the embodiment described above.

In this variant, the fixed plate 14 serving for the rear confinement of the explosive is replaced by a second plate identical to the plate 10 described above. The operating principle of this multi-channel transmission device is identical to that described above.

 In this variant, the strip of explosive 12 is sandwiched between the two plates 10a and 10b. The detonation of the explosive 12 then induces the raising of the two plates symmetrically with respect to the axis of the detonation which coincides with that of the relay assembly 8a. The advantage of this multi-channel transmission device, compared with that described above, is that it makes it possible to double, for the same longitudinal size, the number of detonating outputs and to propose a new organization of these outputs.

 In this variant, the metal frame 6 (Figures 4 and 6) is composed of two half-shells 6a and 6b fixed to each other by means of screws 32 at their flange 34, ensuring the seal of the device after operation. The two half-shells 6a and 6b made of light alloy each have a recess. They delimit with the relay assembly 8a with double plate raising 10a and 10b two cavities 20a and 20b symmetrical and inclined with respect to the plane of the relay assembly 8 by an angle e equal to that of the raising of the metal plates îOa and lob. Lateral packaging of the explosive strip 12 is ensured by a metal part 36 in the shape of a U (FIG. 5), made for example of steel.

 The other elements constituting this multi-channel transmission arrangement are identical to those described above, both in terms of their shape and arrangement and in their constitution. For this reason, we have kept the same references.

 As before, the plates 10a and 10b can be made of steel 2 / 10th of a mm thick. They each have a precision groove 30a and 30b so as to ensure a clean cutting of these plates, cutting corresponding to the dimensions of the cavities 20a and 20b.

In order to obtain bearing angles
e neighbors of 150, as before, one can use a strip of explosive 12 precut in a sheet of flexible explosive having a thickness of 3 mm and consisting of pentrite and a plastic binder.

 In FIG. 7 another embodiment of the multi-channel transmission device has been shown, in accordance with the invention. In this embodiment, the relay assembly bearing the reference 38 consists of a moving part having the form of a hollow tube 40 in which is housed the strip of cylindrical explosive 12. Consequently, the transmission of a pyrotechnic order from the donor component 2 to the output relays 4 is ensured by the burstless inflation of the hollow tube 40 caused, as previously by the detonation of the explosive strip 12.

 The theory of cylindrical bearing is similar to that of '. raising of flat plate. It shows that the final speed and the bearing angle depend, for a given explosive, only on the ratio of the mass of the tube to the mass of explosive.

 This mode of transmission of shocks by cylindrical raising makes it possible to propose a new type of organization of the outputs of the multi-channel transmission device which, due to the possibility of a radial distribution of the receiver relays, is clearly more compact than the two previous organizations. .

 In this embodiment, the metal frame 42, made for example of light alloy has a cylindrical shape. On this frame 42 are mounted, in addition to the output relays 4, a first metal plug 44, serving as a support for the donor component 2 as well as a stop for the relay assembly 38, and a second metal plug 46, ensuring in particular the positioning of the relay assembly 38 with cylindrical raising. These plugs can be made of light alloy.

 In addition to the two cavities which serve to receive and fix the two metal plugs 44 and 46, the frame 42 includes another cavity 47, cylindrical, which opens onto the previous two. The latter receives, along its axis, the cylindrical raising relay assembly 38, and allows the metal tube 40 of this relay assembly to swell. The closure of this relay resemblance 38 is ensured by a metal flake 48 welded to the end 40a of the metal tube 40.

 In this embodiment, the receiver relays 4, of which there are 12 for example, are arranged in "fir" around the relay assembly with cylindrical raising 38. The clearance between these receiving relays and the relay assembly with cylindrical raising 38 is such that the speed reached by the wall of the tube 40 is maximum and that the wall of the tube, at the time of impact on the flat faces of the end pieces 4a of the output relays, is still intact. In addition, to ensure the most planar impact possible (although in all rigor a plan impact is ipp possible, due to the curvature of the wall of the tube), the output relays 4 are inclined so that the angle made by the flat faces of the end pieces 4a of the output relays 4 and the axis of the cylindrical raising relay assembly 38 is equal to the lifting angle of the metal tube 40.

 In this embodiment, the metal tube 40 can be made of aluminum alloy.

In an exemplary embodiment, it has an outside diameter of 4.5 mm and a thickness of 0.5 mm. It can be filled with a compressed explosive such as hexogen.

 Furthermore, the clearance between the relay assembly and the ends 4a of the receiver relays is 3.5 mm and the angle of inclination between the planar faces of said ends, relative to the axis of the raising relay assembly cylindrical, is close to 180.

 The other elements constituting this multi-channel transmission device are identical to those described above, and in particular with regard to their shape and their constitution.

Claims (7)

 1. Multichannel transmission device allowing the transmission of a pyrotechnic order, from a donor component (2) to several output relays (4), and comprising a frame (6, 42), on which the donor component is mounted and the output relays, and a relay assembly (8, 8a, 38) ensuring the transmission of said order from the donor component (2) to the output relay (4), characterized in that the relay assembly (8, 8a, 38) comprises at least one moving part (10, 40) attached to an explosive strip (12) which can be initiated in detonating mode, at one of its ends (12a), by the donor component so that the detonation of the explosive strip (12) causes the moving part (10, 40) to be raised at an angle e, and in that the output relays (4) are mounted on the frame (6) so that their end (4a) to receive the pyrotechnic order, transmitted by the raising of the moving part, forms with said moving part, before raising it, said angle O  2. Transmission device according to claim 1, characterized in that the donor component (2) is a shock generator comprising percussion means which can generate a shock in the longitudinal axis of the moving part (10, 40), before raising it.  3. Transmission device according to any one of claims 1 and 2, characterized in that the relay assembly (10,40) comprises means (14, 36, 40) for laterally containing the strip of explosive in said together.  4. Transmission device according to any one of claims 1 to 3, characterized in that the movable part (10) has the shape of a flat plate.  5. Transmission device according to claim 4, characterized in that the relay assembly (8) comprises a single movable part, and in that it comprises a fixed part (14), integral with the frame (6) and attached to the explosive strip (12) so that the moving part and the fixed part are located on either side of the explosive strip.  6. Transmission device according to claim 4, characterized in that the relay assembly (8a) comprises two moving parts (lOa, lOb) placed on either side of the explosive strip (12) and in that the output relays (4) consist of two series of relays arranged on either side of said relay assembly.  7. Transmission device according to any one of claims 1 to 3, characterized in that the moving part (40) has the shape of a hollow tube in which is housed said strip of explosive (12) then having a shape cylindrical, and in that. the output relays (4) consist of several series of relays arranged symmetrically and all around said tube.