FR2964732A1 - PROJECTILE FOR AVALANCHE TRAPPING - Google Patents

Abstract

The invention relates to an avalanche release projectile to be released vertically above a terrestrial target (3) from a drop point (8) of an air station (2). The avalanche release projectile (1) is formed by an envelope (4) containing an explosive charge (5) and is provided with a pyrotechnic primer (6). The projectile for avalanche release (1) comprises a rangefinder (7) connected to a control module (14) for firing the pyrotechnic primer (6) and arranged on a lower part (12) of the envelope (4) so as to face the earth target (3) in the release and / or detection position. The control module (14) is parameterized so as to trigger the ignition of the explosive charge (5) at a predetermined distance, di, from the terrestrial target (3) detected by the range finder (7).

Description

TECHNICAL FIELD OF THE INVENTION The invention relates to an avalanche release projectile intended to be dropped vertically above a terrestrial target from a drop point of an air station, formed by an envelope containing an explosive charge and provided with a pyrotechnic primer. 10

State of the art

Several devices are currently used to artificially trigger avalanches at risk sites such as winter sports resorts where ski areas and private and public infrastructures must be periodically secured.

Sites likely to constitute an avalanche departure zone 20 are generally avalanche corridors where the snow has accumulated. The avalanche triggering then makes it possible to dislocate the snowpack of the valleys and to minimize the risks of avalanches.

The known avalanche triggering devices generally use explosive charges and are distinguished according to whether they are grounded or mobile.

Mobile avalanche trigger devices require the manipulation of an explosive projectile by an operator. Known explosive projectiles are hand grenades consisting of a dynamite stick initiated by a slow wicking pyrotechnic detonator or an electric detonator. The hand grenades are put in place on the 5

sites to be secured or launched from a fixed or mobile launch platform.

The mobile launch platform is, conventionally, a helicopter flying over the site to be secured, to allow a vertical drop of the explosive charge over the avalanche corridor.

These mobile avalanche triggering devices present significant risks for operators who are usually either fireworks or trackers. Indeed, handling explosive charges is the main cause of accidents during these operations because the handling of explosive charges is often performed in unstable climatic conditions and in dangerous areas.

Other remote avalanche triggering devices have been proposed from launch platform to reduce such risks. US-A-5872326 discloses an air gun which launches an explosive projectile fired by an impact rocket. The launch is carried out by a pneumatic launching tube delivering a gas under pressure to project the projectile which explodes in the vicinity or the impact of the snow.

Document FR-A-2771168 proposes to constitute the explosive projectiles before firing, by producing a two-component explosive charge. The device inflates a balloon with an explosive oxidant / fuel mixture just before firing.

There may also be mentioned a fixed avalanche triggering device described in document FR-A-2765321. The avalanche triggering device comprises a base anchored to the ground and a gun which

propels a detonating gas directed towards the area of the snowy corridor to be secured.

Although these fixed avalanche triggering devices exhibit good performance, they require a heavy installation and maintenance infrastructure and remain extremely expensive.

OBJECT OF THE INVENTION The object of the invention is to overcome the drawbacks of the prior art. In particular, the object of the present invention is to propose an effective avalanche projectile, easy to use, economically viable and ensuring an optimum level of safety both in terms of the manipulation of the projectile by the operator and during his transport. and its storage.

According to the invention, this object is achieved by the fact that the projectile for avalanche triggering comprises a range finder connected to a firing control module of the pyrotechnic primer and arranged on a lower part of the envelope in such a way that to be facing the terrestrial target in the release and / or detection position and in that the control module is parameterized so as to trigger the ignition of the explosive charge at a predetermined distance, di, from the detected terrestrial target by the rangefinder.

According to a preferred embodiment, the projectile for avalanche triggering is provided with means for delaying the start-up of the control module and / or the rangefinder. Brief description of the drawings

Other advantages and features will emerge more clearly from the following description of particular embodiments of the invention given by way of non-limiting example and represented in the accompanying drawings, in which:

- Figures 1 to 3 show, schematically and in side view, the various steps of the method of using a projectile for triggering avalanche according to a particular embodiment of the invention. - Figures 4 to 6 show, schematically and in section, the various steps of the method of using a projectile for triggering avalanche according to a particular embodiment of the invention.

Description of particular embodiments.

With reference to FIGS. 1 to 3, the projectile for avalanche release 1 is intended to be released, vertically, from an airdrop station 2, above a terrestrial target 3.

By terrestrial target 3 is meant an area of the territory likely to constitute an avalanche departure zone and to be secured by elimination of at least a portion of the snowpack. The terrestrial target 3 can be delimited beforehand according to the detonating power of the avalanche triggering projectile 1 used.

The airdrop station 2 can advantageously be a piloted or unmanned aircraft (in English "unmanned aerial vehicle", UAV)

commonly called drone. The aerial station 2 is preferably a helicopter.

According to a particular embodiment shown in FIG. 4, the projectile for avalanche triggering 1 is formed by a casing 4 containing an explosive charge 5 and provided with a pyrotechnic primer 6. The pyrotechnic primer 6 is preferably an electric primer head.

The projectile for triggering avalanche 1 also includes a rangefinder 7. The function of the rangefinder 7 is to detect the terrestrial target 3 at a predetermined distance, di, corresponding to the range of detection of the rangefinder 7.

The rangefinder 7 may consist of one or more telemetric optical, acoustic or radio sensors. The rangefinder 7 is preferably an infrared (IR) rangefinder.

As shown in FIG. 1, the use of the projectile for triggering avalanche 1 consists of putting the projectile 1 in the release position and then jettisoning it in this position, vertically, above the terrestrial target 3 so that that the rangefinder 7 and, more precisely, the sensors of the rangefinder are oriented facing the terrestrial target 3. The projectile for triggering avalanche 1 is released from a drop point 8 of the air station 2.

As shown in FIG. 1, the projectile 1 falls towards the terrestrial target 3. During the fall, the avalanche triggering projectile 1 is held in a detection position corresponding to a position where the rangefinder 7 is directed towards the terrestrial target 3.

When the rangefinder 7 detects the terrestrial target 3 at the distance di (FIG. 2), the projectile for triggering avalanche 1 explodes above the snowpack (FIG. 3). The explosion creates a shock wave that causes a snowfall in the avalanche corridor. As shown in FIG. 4, the envelope 4 preferably has a necked balloon shape. The envelope 4 may, for example, be constituted by a neck 9 attached to a balloon 10 having an upper portion 11 and a lower portion 12. The neck 9 has a tubular shape and opens at the bottom (at the bottom in the figure 4) on the upper part 11 of the balloon 10 (at the top in FIG. 4). The lower portion 12 of the balloon 10 is fixed integrally to the upper part 11 according to any known method, for example, by gluing or with the aid of an adhesive. The upper and lower portions, respectively 11 and 12, of the balloon 10 thus provide a housing 13.

The casing 4 is advantageously formed by a rigid material having a thickness that can vary between 1 mm and 5 mm, preferably between 20 mm and 5 mm. The envelope 4 is preferably made of at least one rigid biodegradable material such as cardboard, card stock or corn material. The neck 9 and the upper and lower parts, respectively 11 and 12, may be constituted by the same material or by different materials. The rangefinder 7 is integral with the envelope 4 and is advantageously arranged on the lower part 12 of the envelope 4 so as to face the terrestrial target 3 in the release position and / or in the detection position. As shown in FIG. 4, the projectile for avalanche release 1 comprises a firing control module 14 of 30.

the pyrotechnic primer 6 and power supply means 15 placed in the housing 13 of the casing 4. The explosive charge 5 is also placed in the housing 13.

The explosive charge 5 is advantageously packaged in a rigid, semi-rigid or flexible packaging and placed under this packaging in the housing 13. By way of example, the explosive charge 5 is in the form of a plastic bag containing the pyrotechnic composition marketed by the applicant.

The control module 14 for firing the pyrotechnic primer 6 is connected to the rangefinder 7 and the pyrotechnic primer 6 by a communication circuit 16. In addition, the control module 14 is electrically connected to the power supply means The control module 14 may be a microcontroller which interprets and processes the data coming from the rangefinder 7 and manages the firing of the pyrotechnic primer 6. The control module 14 is parameterized to transmit an order of firing towards the pyrotechnic primer 6 as soon as a terrestrial target 3 is detected by the rangefinder 7.

The rangefinder 7 is electrically connected to the power supply means 15 by a second electric circuit 18.

The power supply means 15 are connected to an electrical connector 19 provided with a light indicator 20 indicating the level of charge of the power supply means 15. The electrical connector 19 is fixed to the wall of the casing 4 in such a way that to be able to be connected to a source of electrical energy (not shown). The electrical connector 19 connects the power supply means 15 to a source of electrical energy and allows the electrical charging of the power supply means 15. The indicator light 20 indicates

when the maximum load of the power supply means 15 is reached.

The power supply means 15 are preferably constituted by one or more electrical capacitors or supercapacitors, for example, by three capacitors 2,3V having an electrical capacitance of 10 farads, marketed by Goldcap.

As shown in FIG. 4, the pyrotechnic primer 6 can be placed outside the envelope 4, possibly fixed to the wall of the envelope 4 according to any known method. An orifice 21 passing through the wall of the balloon 10, preferably the lower part 12 of the balloon 10, allows the introduction of the pyrotechnic primer 6 for putting it in contact with the explosive charge 5.

The projectile for triggering avalanche 1 is preferably provided with a delaying means 22 for putting the control module 14 and / or the rangefinder 7 into operation. The delaying means 22 is initiated during the release of the projectile 1 to 2. The delay means 22 constitutes a safety which delays the activation of the control module 14 and / or the rangefinder 7. The delay means 22 is preferably mechanical and comprises at least one power switch 23 intended to close the first electrical circuit 17 connecting the power supply means 15 and the control module 14.

The power switch 23 is actuated when the projectile for avalanche release 1 is at a predetermined distance, d2, from the release point 8. The delaying means 22 advantageously comprises an additional power switch 24 intended to close the second electrical circuit 18 connecting the power supply means 15 and the rangefinder 7. The additional power switch 24 is actuated when the projectile for avalanche release 1 is at a predetermined distance, d3, from the release point 8 (FIG. ).

According to a preferred embodiment shown in FIG. 4, the delaying means 22 comprises a three-strand wound wire 25 having first, second and third ends, respectively, 26, 27 and 28.

The first end 26 of the coiled wire 25 is provided with anchoring means 29 intended to be fixed to a fixed release point 8 located in the air station 2. The anchoring means 29 are, for example, ~ o constituted by a loop made at the end of the wound wire 25 and the release point 8 by a hook in which the loop can be crooked.

The second and third ends, 27 and 28, are respectively provided with the power switch 23 and the additional power switch 24.

As shown in FIG. 4, the retarding means 22 is arranged inside the envelope 4 so as to place the majority of the wound thread 20 in the neck 9 while passing the anchoring means 29 of the neck 9 and the second and third ends, 27 and 28, in the housing 13. The second and third ends, 27 and 28, opening into the upper portion 11 of the balloon 10 actuate, respectively, the power switch 23 and the additional power switch 24. Starting from the first end 26, the coiled wire 25 is uniformly and circularly wound inside the neck 9. The wire 25 separates into two strands from a certain length of the wire 25 at a fork. The two strands have different lengths and end respectively at the second and third ends 27 and 28. The length d2 of the wound wire 25 between the first end 26 and the second end 27 is less than the length d3 of the coiled wire 25

between the first end 26 and the third end 28. By way of example, the length di is preferably between 6m and 8m and d3 between 7m and 9m.

The method of using an avalanche trigger projectile 1 according to the particular embodiment described above comprises a first charging step. This step consists in charging the power supply means 15 until the indicator light 20 comes on, guaranteeing the presence of a sufficient energy reserve for the operation of the projectile 1.

As shown in FIG. 5, the pyrotechnic primer 6 is then brought into contact with the explosive charge 5 by introducing the pyrotechnic primer 6 into the orifice 21. The projectile for triggering avalanche 1 is stowed by the means of FIG. anchoring 29 at the release point 8 of the air station 2. This operation can be carried out indifferently, before or after, the steps of charging and setting up the pyrotechnic primer 6. Before the release, the power switch 23 and the additional power switch 24 maintain, respectively, the first and second electrical circuits, 17 and 18, in open circuit position. The control module 14 and the rangefinder 7 are not electrically powered and, therefore, are inactive.

The next step is to drop the projectile for avalanche release 1 in the release position. Ditch position means a position in which the lower portion 12 is oriented towards the terrestrial target 3 and the neck 9 to the air station 2 drop.

The center of gravity of the envelope 4 is situated at the lower part 12 of the envelope 4 because of its wider shape at the level of the upper part 11 and the lower part 12 than at the neck 9 The particular shape of the envelope 4 promotes the holding of the projectile 1 in the detection position. In the detection position, the rangefinder 7 is oriented facing the terrestrial target 3 and the neck 9 to the air station 2 drop. This stabilizing effect is accentuated by the aerodynamic shape of the projectile for triggering avalanche 1 and by the presence of the explosive charge 5 in the housing 13. The explosive charge 5 weighs the lower part 12 of the envelope 4 and creates a difference of weight between the balloon 10 and the neck 9, promoting the setting detection position during the fall of the projectile for triggering avalanche 1.

The projectile for triggering avalanche 1 may also include stabilizers 30 which aim to stabilize the projectile 1 in the detection position, during its fall. The stabilizers 30 are preferably tapes attached to the inner wall of the neck 9 of the envelope 4 and regularly distributed around the neck 9. After the drop and during the fall of the projectile 1, the tapes 30 unfold towards the outside the neck 9 by the effect of gravity. During the entire fall, the ribbons 30 thus stabilize the projectile for triggering avalanche 1, to maintain it in a suitable detection position.

As shown in FIG. 6, the wire 25 coiled in the neck 9 takes place during the fall of the projectile for triggering avalanche 1. When the distance traveled by the projectile 1 is equal to the length d2 of the wire 25 between the first 26 end and the second end 27, the second end 27 is detached from the first electrical circuit 17, releasing the power switch 23. The power switch 23 is thus actuated and closes the first electrical circuit 17. The module

command 14 is then powered and active while the rangefinder 7 remains inactive.

As shown in FIGS. 7 and 2, the fall continuing, the second strand of the wire 25 in turn runs to the third end 28. When the distance traveled by the projectile 1 is equal to the length d3 of the wire 25 between the first end 26 and the third end 28, the wire 25 is stretched and the third end 28 is detached from the second electric circuit 18, releasing the additional power switch 24.

The additional power switch 24 is thus actuated and closes the second electrical circuit 18. The control module 14 and the rangefinder 7 are then powered and active. The wire 25 is released from the projectile 1 at a distance d3 from the release point 8. The projectile 1 is then no longer connected to the release point 8 (Figure 2).

As shown in FIG. 3, the control module 14 is parameterized so as to trigger the ignition of the explosive charge 5 at a predetermined distance, d 1, from the terrestrial target 3 detected by the rangefinder 7. Thus, when the projectile for avalanche release 1 is at a distance d ,, preferably between 0.6m and 1.5m, advantageously 0.8m, from the terrestrial target 3, the rangefinder 7 transmits the information via the communication circuit 16 to the control module 14 which triggers the ignition of the explosive charge 5 by activation of the pyrotechnic primer 6 (Figure 7). A rangefinder 7 having, advantageously, a detection range of between 0.6m to 1.5m, preferably 0.8m, is chosen. For example, the rangefinder 7 is an IR rangefinder marketed by the company under the name Sharp.

According to a variant not shown, the upper part 11 and the neck 9 of the balloon 10 are constituted by the same material thicker than the material constituting the lower part 12 of the balloon 10. By way of example, the upper part 11 can be made with a material having a

5mm thickness and the lower part 12 with the same material having a thickness of 2mm. Thus, the upper portion 11 opposes a greater resistance to the explosion than the lower part 12. The blast of the explosion is thus oriented, advantageously, downwards, that is to say towards the terrestrial target 3. L the shock wave then propagates mainly in the direction of the terrestrial target 3, thus optimizing the detonating power of the explosive charge 5.

According to a particular preferred embodiment, the control module 14 may, advantageously, comprise a safety relay 31 provided with diagnostic means for providing a state on the integrity of the energy reserve of the power supply means 15 Thus, if the power supply means 15 are discharged until reaching a predefined threshold electric capacitance value Cs without the projectile 1 having exploded, the safety relay 31 is self-destructing by welding, causing the triggering of the explosion of the projectile 1. For example, the safety relay 31 is an AX100M 5V relay marketed by Sharp. The safety relay 31 is activated when the additional power switch 24 is actuated and the second electric circuit 18 closed. This operation is an additional security ensuring the neutralization of the projectile for triggering avalanche 1 in case, for example, of failure of the detection of the rangefinder 7.

According to another particular embodiment not shown, the aerial station 2 is a drone dropping. Several projectiles for avalanche release 1 can be stored in a rack and connected to an automated remote controlled release device according to any known method. The method of using the projectiles for avalanche release 1 differs from the method of use described above in that the contacting of the pyrotechnic primers 6 with the explosive charge 5 by introduction into the orifice 21 and the loading of the power supply means 15 are made before the release.

Although the avalanche release projectiles 1 described have a collar-shaped envelope 4, the invention is not limited to these particular embodiments which are given for illustrative purposes only. In particular, it is possible to envisage other forms of aerodynamic envelope ensuring the holding of the projectile for avalanche release 1 in the release position and / or in the detection position. Unlike the devices of the prior art, the avalanche release projectile according to the invention is efficient and economically profitable while guaranteeing the safety of the operators and the environment. The avalanche triggering device according to the invention is remarkable in that it comprises at least four safety devices. Indeed, the risk of explosion during the storage and transport of explosive projectiles is minimized or non-existent, because prior to any use, the steps of loading and contacting the pyrotechnic primer with the explosive charge are 20 mandatory steps to operate the projectile.

In addition, the projectile for avalanche release has a delaying means that activates the projectile only when a safety distance separates the operator of the projectile. This characteristic constitutes a second safety preventing any risk of explosion when handling the projectile before release.

Finally, the projectile for avalanche release according to the invention self-destructs in case of malfunction, which avoids the presence of explosive projectile activated in the field.

In addition, the projectile for avalanche release according to the invention respects the environment because it can be made in part of biodegradable material.

Claims (10)

REVENDICATIONS1. Avalanche release projectile, intended to be dropped vertically above a terrestrial target (3) from a drop point (8) of an air station (2), formed by an envelope (4) containing an explosive charge (5) and provided with a pyrotechnic primer (6), characterized in that it comprises a rangefinder (7) connected to a control module (14) for firing the pyrotechnic primer (6). ) and arranged on a lower part (12) of the envelope (4) so as to face the terrestrial target (3) in the release and / or detection position and in that the control module (14) is set to trigger the ignition of the explosive charge (5) at a predetermined distance, di, from the terrestrial target (3) detected by the range finder (7). 2. Projectile according to claim 1, characterized in that it comprises power supply means (15) connected to the control module (14) by a first electrical circuit (17) and the rangefinder (7) by a second circuit electric (18). 3. Projectile according to claim 2, characterized in that the power supply means (15) are connected to an electrical connector (19) provided with a light indicator (20) indicating the charge level of the power supply means (15). 4. Projectile according to any one of claims 1 to 3, characterized in that it is provided with a delay means (22) for putting into operation the control module (14) and / or the rangefinder (7) . 5. Projectile according to claim 4, characterized in that it comprises power supply means (15) connected to the control module (14) by a first electrical circuit (17) and the rangefinder (7) by a second electric circuit (18) and in that the delay means (22) comprises at least one power switch (23) for closing the first electric circuit (17), said power switch (23) being actuated when the projectile for triggering avalanche system (1) is at a predetermined distance, d2, from the release point (8). 6. Projectile according to one of claims 4 and 5, characterized in that it comprises power supply means (15) connected to the control module (14) by a first electrical circuit (17) and the rangefinder (7). ) by a second electric circuit (18) and that the delay means (22) comprises an additional power switch (24) for closing the second electric circuit (18), said additional power switch (24) being actuated when the avalanche release projectile (1) is at a predetermined distance, d3, from the release point (8). 7. Projectile according to any one of claims 4 to 6, characterized in that the delay means (22) comprises a thread (25) wound, three-strand, having first (26), second (27) and third ends (28), in that the first end (26) of the coiled wire (25) is provided with anchoring means (29) for attachment to the release point (8) and in that the second end (27) and the third end (28) are provided, respectively, with the power switch (23) and the additional power switch (24). 8. Projectile according to any one of claims 1 to 7, characterized in that the casing (4) is constituted by at least one biodegradable rigid material. 9. Projectile according to any one of claims 1 to 8, characterized in that it comprises stabilizers (30) .30 10. Projectile according to any one of claims 1 to 9, characterized in that the control means (14) comprise a safety relay (31) adapted to neutralize the control module (14) causing the explosion of the projectile (1).