CA1339284C - Process and devices for masking targets using a smoke generating material - Google Patents

Abstract

Method and device for masking a target, using a smoke material, against observations in the field of electromagnetic radiation. The device comprises a sealed enclosure which houses a powder with a particle size chosen to be a contrast absorber at least in the infrared and / or visible range after dispersion in the ambient air, and propulsion means capable of propelling the powder outside. of the enclosure to develop it between the target and the observation post, as well as actuation means capable of initiating the operation of the propulsion means.

Description

1: ~ 3 ~ 284 The invention relates to the masking of a target, in particular but not exclusively of a tank, or again, for example, helicopter-type flying machines tere, or surface buildings, ~ against observing-vations in the field of ~ electromagnetic radiation ~ -ticks in particular visible and / or infrared, even distant and the case ~ ch ~ ant ultraviolet.
The purpose of the present invention is in particular to develop a contrast absorbing cloud quickly (in less than a second) and sustainably (several tens of seconds) while not only masking the target itself, but also a large area around this one.

~ ~ 3 ~ 9284 An important object of the present invention is to develop a contrast absorbing cloud whose characteristics are little influenced by clr-atmospheric constants.
For this, the invention provides a device and a masking process ~ using smoke materials individuals.
The device for masking a target, form ~ the present invention, includes an enclosure waterproof which houses a granulom ~ sorted powder chosen for be absorbent of contrast at least in the field ' infrared and / or visible after dispersion in air ambient, the powder comprising different constituents each covering a specific wavelength range, and propulsion means capable of propelling the powder outside the enclosure to develop it between the target and the post ~ observation as well as actuation means capable of initiating operation means of propulsion.
The powder is advantageously of particle size varied but controlled, less than about 10 microns, and preferably situated in the range from 0.3 mi crons to 5 microns, or better from 0.5 microns to 3 microns.
Very advantageously, the powder is developed in combination with a gaseous propellant (freon and / or carbon dioxide in particular).
You can also choose a propellant gaseous containing one or more gases which are themselves same opacifiers in the infrared and / or visible. An interesting example is ammonia.
The powder preferably consists of one or many of the following materials:

1 ~ 32 ~

. metals in powder form of the transition metal series (Group IVB ~ IIB of the Mendeleiev Table as well as Aluminum, Boron, Silicon, Antimony, Tin, Lead, Bismuth, and alloys of these metals), . o ~ ydes of transition metals as well as Boron, Barium Oxide, Strontium Oxide, Oxide Copper, . carbon in the form of graphite.
According to an advantageous characteristic, the powder contains aluminum, brass, copper or iron.
According to another advantageous characteristic, the powder contains a copper or boron oxide.
According to another advantageous characteristic, the thumb contains graphite.
Preferably, the powder also contains fine silica particles to improve flow powder.
Advantageously, the enclosure is housed in a envelope of generally cylindrical shape, the bottom of socket includes an impeller capable of causing ejection this the enclosure.
Preferably, the enclosure is then provided with stabilizing means, of the fin type, foldable between the enclosure and the envelope and adapted to be deployed after ejection, to control the powder emission direction.
According to another advantageous characteristic of the present invention, the actuation means are taking pyrotechnic delays.
Advantageously, the means of propulsion include a pressurized gas propellant.
According to a first variant, the propellant gas is mixed with the powder. The means of propulsion moreover include means capable of expelling a plug initially closing an orifice which connects the t ~ rieur of the enclosure and the outside.

3 ~ 284 According to a second variant, the enclosure comprises:
- a gas cartridge under pressure, and suitable organs - to release the gas under pressure at a selected point of the enclosure, - a dip tube having an open end in the enclosure, substantially opposite the point chosen, and another end which communicates with a capa-ble to lead to the outside of the enclosure.
Advantageously, the bottom of the powder housing is V-shaped with a concavity turned towards this housing, and a dip tube has a first end open in the enclosure, at the hollow of this V-shaped, while its second end communicates with a nozzle capable of opening outside the enclosure.
According to a third alternative embodiment, the gaseous propellant is released during the explosion an explosive charge housed in the enclosure. This third variant relates in particular to the case of moving targets, such as helicopters, buildings of surface. It also allows in the case of tanks get faster complete masking of an area given geometric.
Preferably, the enclosure and the explosive charge are then generally cylindrical, and the load explosive is housed inside the powder, coaxial-lying at the precinct.
In addition, preferably, the enclosure is adapted to release the powder at its middle part transverse in order to develop the powder substantially according to a disc.
According to another aspect of the invention, the two first variants of the above mentioned are adapted to emit the powder when the enclosure rests on the ground and, at least when ejected, the enclosure I 33928 ~

fits in an outer envelope substantially spherical, relative to which the nozzle region is more domed, and the opposite area less domed, the latter being closest to the center of gravity of the device.
According to the present invention, there is also provided a method of masking a target using a material smoke, contrary to observations in the field of electromagnetic radiation, characterized in that it consists in developing thanks to the device described above a lo powder of particle size chosen to be absorbent of contrast at least in the visible and / or infrared range after dispersion in the ambient air.
Preferably, the method consists in drawing from the target, a bundle of these devices, with a low site which preferably is less than 15 ~.
According to the present invention, there is also provided a method of masking a target, using a material smoke, contrary to observations in the field of electromagnetic radiation, characterized in that it includes the steps of:
- develop a powder in an enclosure particle size chosen to be absorbent in contrast to less in the infrared and / or visible range after dispersion in ambient air, the powder comprising different constituents each covering a range of wavelengths specific, - propel the powder outside the enclosure to develop this between the target and the position observations, and - initiate the propulsion of said powder.
Preferably, actuation means are adapted to initiate propulsion of the powder when said enclosure rests on the floor.
Other features and benefits of the invention will appear on reading the description detailed which will follow, as well as on the attached drawings.

13 ~ 284 5a The detailed description and the drawings are intended to give by way of nonlimiting example, different modes of realization of the present invention which are currently considered preferential. In the drawings:
- Figure 1 shows a schematic axial section view of a first variant embodiment of a device in accordance with the present invention for the development of a powder, and - Figure 2 shows a schematic axial section view of a second alternative embodiment of a compliant device (9 13 ~ 9284 We will first describe the device shown in figure 1.
In Figure 1, an envelope of general shape cylindrical, open at one end and defined by a wall 12, is associated with its other extremit ~ with a socket base 11, in the form of a disc.
The wall 12 provided with a collar in ~ erne 12A
is secured to the bottom of the socket 11 thanks to a round 70 and an associated screw 71.
The socket bottom 11 houses an impeller 13 taking an ejection charge whose role will be explicit ~
thereafter, which is advantageously initiated electric-ment by a primer 13A. On the periphery, the socket bottom 11 forms a crown 16 to which a terminal is connected primer to form a power contact. This crown 16 is surrounded externally by a material insulator 15 itself entou ~ é of a crown 14 on which a pin is attached to the second terminal of the primer 13A. The electrical circuit of the initiator of the impeller 13 is therefore caught between the mass of the bottom of socket 11 and this power contact 14.
The ejection charge 13 is maintained in the socket bottom 11 by a transverse grid 72 immo-stabilized using a threaded ring 73.
Internally, the envelope houses an enclosure forming the active device itself. This pregnant-te, ~ tight, is defined by a bottom bottom 21 provided a radial projection 27 with seal 27A. On this background is fixed, by threading or other, a side wall cylindrical 22, closed in turn at the other end by a cap 23 with seal 23A. When the enclosure is in its envelope, figure 1 shows that the edges ends of the cylindrical wall 12 of the envelope comes nent crimp on suitable housing of the cost fe 23.

The initiation of the ejection charge by the primer 13A causes gas to expand in a chamber 28 pr ~ view between the socket bottom 11 and the bottom 21 of the enclosure, for ~ jecting the enclosure 22, the envelope 12 remaining in the mortar.
It will be noted in FIG. 1 that the cap 23 is fitted with a recessed cell, flat bottom and section circular for example. This alv ~ ole is normally closed ~
by a plug 25 provided with sealing means 26.
A cartridge 50 of gas under pressure is pr ~ view inside the enclosure. This cartridge is provided with means of link and tent illustrated in 51. These means are ter-undermine in 52 by a closing flake, susceptible to be pierced. Extremity 51 of the cartridge will come screw into a support sleeve, designated ~ generally by 42. This support sleeve defines opposite the straw 52 a bore, in which c ~ ulisse a piston 44 provided with ~ sealing means 45, as well as a bevel point ~ e 46 able to pierce the straw 52. Between the surface of the piston and the flake 52, the al ~ sage defined in the int ~ -laughing sleeve 42 communicates through an orifice 47 with a tube 48, which ends at point 49, at the top of the enclosure, just under the cover 23. This therefore makes it possible to release gas under pressure under the cap (pressure 4 ~ 60 bars, for example).
The enclosure also includes a dip tube, d ~ signed g ~ generally by 56. This dip tube ends by an open end, at 59, in the lower part of the enclosure, substantially opposite ~ from point 49 where is released the gas under pressure.

133,928 ~

The other end of the tube 56 communicates with a nozzle 57, which opens towards the outside of the enclosure, under the cap 25.
In the rest of the enclosure, is placed a powder 55, of controlled and selected particle size. We immediately understands that the gas released in 49 will produce re pressurization (of the powder, and walk in its breast to the bottom at 59 where the tube opening is located plunger 56. The gas will then invade the plunger tube, cause the expulsion of the plug 25 and cause the powder through nozzle 57 in a violent jet towards the outside.
As previously indicated, the powder is of particle size chosen to be absorbent of contrast at least in the infrared range and preferably in the visible and ultraviolet range. AT
as an example the powder is absorbent of contrast in a long wavelength range from 0.2 ~ to 15 ~.
The device also includes means 41 actuation to trigger the release of gas under pressure acting as a means of propelling the powder.
In the preferred embodiment, the trigger means 41 (load 41A and delay 41B) are pyrotechnic means.
More specifically, the aforementioned sleeve 42 is assembled by thread in the center of the bottom 21.
The sleeve 42 houses a load 41A adjacent to the piston 44 and adapted to cause the displacement of this one, as well as a 41B fire transmission delay in contact with load 41A.
This 41B fire transmission delay communicates with a recess 28 provided between the lower bottom 21 of the enclosure and the socket bottom 11. The delay 41B is initiated by the gases produced by the ejection charge 13 which expand into room 28.

13 ~ 3 ~ 8 ~
As shown in Figure 1, preferably the bottom 21 of the powder housing has a structure 21A in V shape with concavity turned towards this housing. Furthermore, the end 59 of the dip tube 56, open in the enclosure-5 te, leads to this V-shaped structure.
On the other hand, advantageously, the device also includes fins (at least 6) integral of the outer surface of the wall 22 of the enclosure.
These fins are initially housed between the wall 22 10 of the aforementioned enclosure and the envelope wall 12, at 18.
The fins are deployed during ejection of the enclosure as we will see later. On the face 1, a fin in the deployed state has been schematically represented by broken lines referenced 1A.
We will now describe the variant of reali-sation shown in Figure 2.
Many elements of this variant are similar to those of the variant shown on the fiaure 1, although with slightly different shapes.
20 For this reason, similar elements in Figure 2 which carry numerical references increased by 100 units, for the most part, will not be described again.
In this figure 2, the primer 113A is housed in the end wall of the socket base 111. This 25 primer 113A is accessible from the outside while providing with the ejection charge 113.
A block 174 is secured to the bottom 121 of the girdle on the side of the initiator 113. this block 174 is crossed axially by a sleeve 175. The latter is itself 30 provided with an axial bore which houses on the one hand a delay pyrotechnic 176 communicating fire transmission with the chamber 128 for expansion of the eection gases, be part of a set 177 comprising a reinforcing relay associated with a detonator, disposed on the bottom side 121 35 enclosure. A drawer 178 provided with a through bore lg 9 ~ 84 179 is, in a classic way in itself, interspersed between the bottom 121 and the block 174.
Again the envelope 112 remains in the mortar during the ejection of the enclosure 122.
The drawer 178 is initially axially lateral and immobilized in this position thanks to the at least one rod 180 bearing against the wall 112 envelope or the like, so that bore 179 is not initially aligned with the set 177, to prohibit safely ~ ity the passage of fire.
After the ejection the rod 180 has no more support and the drawer 178 biased by springs (not shown) is d ~ placed to align the bore 179 and the assembly 177.
In this position, the assembly 177 can to set fire to an explosive charge 186, contained in a 187 cylindrical rod, which is housed inside powder 155, coaxially to the wall 122 of the enclosure.
The filling of the cane 187 in charge 186 is made at an extreme opening later closed using an assembled closure cap 125 centrally on the cap 123.
Preferably, the extremit ~ s of the wall 122 so that the charge explosion explosive initiated by the chain ~ ne: ejection impeller 1t3 - delay 176 - set 177 - drawer 180 aligned ~ -causes the powder 155 to disperse in the form of a cloud substantially disc-shaped, coaxial to the cylinder dre of the explosive cane 187, by releasing the powder at the level of the transverse midline of the enclosure.
Again, we have schematically represented a fin A, in broken lines, in the deployed state, on Figure 2. In this case, the height of the fin 1A is limited to the height of the pyrotechnic block 174.

To avoid friction between the fins 1A and in ~ eloppe 112, during the ~ ejection, it is advan-tageux to place the fins in a fragmented hoof ~
183 sliding in the envelope.
By way of example, the wall 122 of the enclosure can be bakelite, coated with varnish to avoid imp ~ gnation with water, or hard alloys, for example-full of light alloys containing silicon.
You can also use materials posites wound in fiberglass, Kevlar or carbon impr ~ gnées of epoxy resins.
On the other hand, in order to develop the powder according to a full disc (and above all avoid formation of a central hole in the cloud) we can consider a non-uniform distribution of load 186 along the axis of the cane 187.
We can thus interrupt the charge 186 before reach the ends of the cane 187 in order to limit the development of the powder contained in ends of the enclosure 122.
We can still provide a cane 187 of shape tapered general tapered towards at least one end of the enclosure 122, so again to limit the development of the powder to this level.
The center of ~ delight is ~ rov ~ the most us - ~ c ~ he possible from, ~ nd 21.
In addition, the fins ~ the deployed state determine an outer envelope of sensitive contour-spherical, the center of gravity of the device being located below the vertical tangent point of fins when these are deployed, that is to say ~
on the side of the impeller.

~ 133 ~ 28 ~

The device can thus be launched by a mortar, in a relatively short trajectory, then fall on the ground where it will naturally tend ~ se stabilize on its bottom 21. (The position of the center of gra-vity and the presence of fins give it a "somersault" property).
The preferential mode of implementation of the device positive of Figure 1 is to shoot it from a tank, at low low site ~ 15 ~ and at low speed (15 to 25 ms ~, and of course in the form of a beam of devices pulled substantially at the same time, so obtain an almost continuous cloud, completely masking a large area behind which the tank is housed.
In all embodiments, the powder is important first of all by its particle size, for which numeric values have already been specified upper.
It can be a metallic powder.
Aluminum has interesting properties, provided the cloud is cold enough or the proportion of aluminum sufficiently diluted in other ma ~ ériaux to avoid the pyrophoric effects observed with this metal. In this sense, the use of a propellant able to relax with strong cooling, particular of freon or carbon dioxide, is likely to cool the cloud enough to allow consider using an aluminum-based powder.
Likewise, mixing with powders based of brass, copper and / or iron, much less sensitive bles ~ temperature and very effective by them-memes, also allows the use of aluminum. We can naturally consider other powders in the families already mentioned.

~ l 13 ~ 4 On the other hand, it has proven beneficial for some applications to make up the powder graphite, at least in part, as well as another side of copper, Boron, Barium or Stron-tium. Mixtures can be made.
We also found in particular for the mode embodiment of Figure 1 that it was advantageous add fine silica particles to the mixture to facilitate the flow of the powder.
In the case of the embodiment represented ~ sent ~
on fault 2, delay 176 is adapted to cause the firing of the set 177 and the explosion of the load 186 before the device falls to the ground.
The fins 1A then aim to stabilize the enclosure 122 on its path ~ unlike the case previous, where they were used mainly for stabilization ground reading.
The dispersion is moreover preferably carried out at the peak of the trajectory so that the clouds absorbers of contrasts then generated in the form of discs have a substantially horizontal axis.
It is therefore advantageous to control the path roof of the device and the characteristics of the exploration sion so that the intersection of two clouds successive exists from ground level. We obtain thus optimum homogeneous masking.
The embodiment shown in the figure

2 is particularly adapted to allow a response quick .
The bundles of devices are advantageously arranged in respective mortars integrated in a suitcase. Each mortar defines azimuth and elevation of shoot.

133 ~ 284 Successive departures can be delayed a few milliseconds using a pyro-appropriate technique to avoid the coincidence of recoil efforts.
Ejection speed and trajectory delay of each of the devices can be associated ~ the position occupied by the device in the suitcase so that the global cloud formed is generated in an ideal position with the appropriate dimensions.
Shot elevations remain below 15 ~ and speeds can reach 200 ~ 300 m.sec 1, especially for surface buildings and possible-ment for helicopters.

Claims (33)

The embodiments of the invention, about which an exclusive right of property or privilege is claimed, are defined as follows: 1. Device for masking a target, using smoke material, against observations in the field of electromagnetic radiation, characterized by the fact that it includes:
- a sealed enclosure (22) which houses:
~ a powder (55) of particle size chosen for be absorbent of contrast at least in the infrared and / or visible range after dispersion in ambient air, powder comprising different constituents covering each a range of wavelengths specific, and ~ propulsion means (50, 186) suitable for propel the powder (55) outside of the enclosure (22) to develop it between the target and the observation post, as well as ~ actuation means (41-46; 175-177) able to initiate the operation of the means propulsion. 2. Device according to claim 1, characterized in that the powder (55) is varied particle size, less than about 10 microns. 3. Device according to claim 2, characterized in that the powder (55) is varied particle size in the range from 0.3 microns to 5 microns. 4. Device according to one of claims 1 to 3, characterized in that the powder (55) is associated with at least one propellant (50). 5. Device according to claim 4, characterized in that the propellant (50) comprises freon. 6. Device according to claim 4, characterized in that the propellant (50) comprises carbon dioxide. 7. Device according to claim 4, characterized in that the propellant (50) comprises ammonia. 8. Device according to claim 1, 2, 3, 4, 5, 6 or 7, characterized in that the powder (55) contains at least one of the following materials:
- powder metals of the metals series transition (Group IVB to IIB of the Mendeleïv Table as well as Aluminum, Boron, Silicon, Antimony, Tin, Lead, Bismuth and alloys of these metals), - oxides of transition metals as well as oxide of Boron, Barium oxide, Strontium oxide, Copper oxide, - carbon in the form of graphite. 9. Device according to claim 8, characterized in that the powder (55) contains Aluminum, Brass, Copper or Iron. 10. Device according to claim 1, 2, 3, 4, 5, 6 or 7, characterized in that the powder (55) contains fine silica particles. 11. Device according to claim 1, 2, 3, 4, 5, 6, 7 or 9, characterized in that the enclosure (22) is housed in a generally cylindrical envelope (12) the socket bottom (11) of which comprises an impeller capable of cause the speaker to eject. 12. Device according to claim 11, characterized in that the enclosure (22) is provided with stabilization means, of the fin type (1A), foldable between the enclosure (22) and the envelope (12) and adapted to be deployed after ejection. 13. Device according to claim 1, 2, 3, 4, 5, 6, 7, 9 or 12, characterized in that the means actuators include pyrotechnic delays (41B;
176). 14. Device according to claim 1, characterized by the fact that the means of propulsion include a pressurized gas propellant (50). 15. Device according to claim 14, characterized by the fact that the gaseous propellant is mixed with powder. 16. Device according to claim 15, characterized by the fact that the means of propulsion comprise means capable of expelling a plug (25) initially closing a hole which connects the interior of the enclosure and the exterior. 17. Device according to claim 14, characterized by the fact that the enclosure comprises:
- a cartridge (50-51) of pressurized gas, and organs (41 to 49) capable of releasing the pressurized gas in one selected point (49) of the enclosure, - a dip tube (56) having one end open (59) in the enclosure, substantially opposite the point chosen (49), and another end which communicates with a nozzle (57) capable of opening outside the enclosure. 18. Device according to claim 14, 15, 16 or 17, characterized in that the bottom of the housing powder (55) is V-shaped (21A) with concavity facing this housing, and that a dip tube (56) has a first end (59) open in the enclosure, at the hollow of this V shape (21A), while its second end communicates with a nozzle (57) capable of opening at outside the enclosure. 19. Device according to claim 12, taken into account combination with claim 14, 15, 16 or 17, characterized in that at least when the fins are deployed, the enclosure is part of an outer envelope substantially spherical, in which the region (23) powder expulsion is furthest from the center of gravity of the device. . 20. Device according to claim 1, 2, 3, 4, 5, 6, 7, 9, 12, or 14, characterized in that an agent gas propellant is released when a charge explodes explosive (186) housed in the enclosure. 21. Device according to claim 20, characterized in that the enclosure (122) and the load explosive (186) are generally cylindrical in shape, and that the explosive charge (186) is housed inside the powder, coaxially to the enclosure. 22. Device according to claim 20, characterized by the fact that the explosive charge (186) is unevenly distributed along the axis of the enclosure (122) in order to limit the development of the powder contained at the ends of it. 23. Device according to claim 21, characterized in that the enclosure (122) is adapted for release the powder at its transverse middle part, in order to develop the powder substantially according to a disc. 24. Method for masking a target using a smoke material, contrary to observations in the field electromagnetic radiation, characterized by the fact that it consists of developing thanks to the device conforming to the claim 1, 2, 3, 4, 5, 6, 7, 9, 12, 14, 15, 17, 19, 21, 22 or 23, a powder with a particle size chosen to be contrast absorber at least in the visible range and / or infrared after dispersion in ambient air. 25. Masking method according to claim 24, characterized by the fact that it consists in firing from the target, at low site, a bundle of devices according to the claim 1, 2, 3, 4, 5, 6, 7, 9, 12, 14, 15, 16, 17, 19, 21, 22 or 23. 26. The masking method according to claim 24, characterized in that the actuating means are adapted to initiate the means of propulsion when the device rests on the ground. 27. Masking method according to claim 24, characterized in that the actuating means are adapted to initiate the means of propulsion during displacement of the enclosure on its ejection path. 28. Masking method according to claim 24, characterized by modulation of the ejection speed and trajectory delay of each device according to its position in the beam. 29. Method for masking a target, using a smoke material, contrary to observations in the field electromagnetic radiation, characterized by the fact that it includes the steps of:

- developing in a chamber a powder (55) of particle size chosen to be absorbent in contrast to less in the infrared and / or visible range after dispersion in ambient air, the powder comprising different constituents each covering a range of wavelengths specific, and - propel the powder outside the enclosure to develop this between the target and the position observations, and - initiate the propulsion of said powder. 30. Masking method according to claim 29, characterized by the fact that it consists in firing from the target, at a low site, a beam of said speakers. 31. The masking method according to claim 29, or 31, characterized in that means are adapted to initiate the propulsion of the powder when said enclosure rests on the ground. 32. masking method according to claim 30, characterized by the fact that the low site is less than 15 °. 33. Masking method according to claim 32, characterized by the fact that it consists in firing from the target at a speed of about 15 to 25 ms-1.