FR2636729A1 - Method and device for triggering an avalanche - Google Patents

Abstract

The present invention relates to a method for triggering an avalanche, in which one or more explosions of an explosive material are caused in a predetermined zone where the avalanche is to be triggered. The device is composed essentially of a gun 10 having a closed bottom 11 and a front muzzle 12, of a circuit 16 for supplying oxidant gas coming from a source 17 and of a circuit 19 for supplying fuel gas coming from a source 20. An ignition device 26 is mounted at, for example, the rear of the gun. Filling nozzles 22 can be arranged in various zones distributed over some of the length of this gun. The purpose of this gun is to generate a blast which sweeps across the surface of the mantle of snow in the avalanche zone and a shock wave which shakes the base of this mantle.

Description

METHOD AND DEVICE FOR TRIGGERING AN AVALANCHE
The present invention relates to a method for triggering an avalanche, in which one or more explosions of an explosive material are caused in a predetermined area where it is desired to trigger the avalanche.

It also relates to a device for implementing this method for triggering an avalanche, comprising means for causing at least one explosion of an explosive material in a predetermined area where it is desired to trigger this avalanche.

The system marketed under the name is well known
CATEX. which consists of cables carrying explosives for the preventive triggering of avalanches. This system transports loads of dynamite by cable which, arriving over the avalanche corridor to be treated, explode causing a snowfall. A shot made after each heavy snowfall avoids an accumulation which could be dangerous. This system essentially consists of a set of pylons which support a closed loop of a transport cable which passes over one or more avalanche corridors. A power station fixed to the ground or on a pylon makes it possible to drive this cable and to transport a device carrying the explosive charge above one of the avalanche corridors. This device consists of a device descender of charge which can be of the slow wicking descender, timer descender, winch descender with microprocessor or radio control descender.

In all cases, the explosive charge is brought to a substantially constant distance above the upper surface of the layer of snow whose sliding is to be caused and explodes, generating a shock wave which propagates in all directions. In general, the part of this shock wave which is oriented towards the layer of snow triggers its displacement and causes the avalanche. Although this system has demonstrated its effectiveness through the numerous installations carried out over the past fifteen years, it nevertheless has several shortcomings. The installation of the cable circuit which requires the installation of numerous pylons supporting this cable is a difficult and very expensive operation, which greatly limits the possibilities of installation of this system. Moreover, during the explosion, only a relatively limited part of the energy released by the charge acts on the snow layer, since the breath and the shock wave propagate like spherical waves in all directions of space. As a result, the efficiency of the system is relatively modest and the explosive charges must be high in view of the results to be obtained.

Finally, handling explosive charges remains a dangerous operation regardless of the precautions taken by the operators.

The present invention proposes to remedy all of the drawbacks mentioned above and to provide a simple and effective method for triggering avalanches in all the sites to be protected.

This object is achieved by the method according to the invention characterized in that at least one explosion of a mixture of fuel and gaseous oxidant is caused inside a barrel having a closed bottom and a frontal mouth and in that the breath and / or the shock wave caused by this explosion are diffused in said predetermined area, above the layer of snow to be evacuated by said avalanche.

According to one embodiment of the method, a combustible gas is used as the gaseous fuel. This combustible gas is preferably chosen from the group of substances comprising hydrogen, tetraine, acetylene, propane, methane and a mixture of these substances, and it is possible to use oxygen or ozone as oxidizer gas. Air or air enriched with oxygen or ozone can also be used as the oxidizer gas.

In the process according to the invention, it is possible to use a gas mixture composed of lt6 by volume of propane and 516 by volume of oxygen. This mixture is advantageously carried out at atmospheric pressure.

Preferably, the gaseous fuel and the gaseous oxidant are simultaneously introduced into the barrel, through a mixing device arranged to form a homogeneous mixture. The mixture is advantageously caused to explode by means of a spark generated inside the barrel, in an area arranged near the closed bottom of this barrel.

According to an advantageous variant, the mixture is caused to explode by means of a spark generated in the barrel, in an intermediate zone located between the closed bottom and the front mouth.

According to a first embodiment, the explosive mixture is prepared by passing the fuel gas and the oxidant gas respectively from sources of these gases under pressure through buffer tanks where they are at a pressure close to atmospheric pressure.

According to a second embodiment, the explosive mixture is prepared by passing the fuel gas and the oxidant gas respectively from sources of these gases under pressure through flow meters to define the respective volumes of the components.

Advantageously, the spark is produced by means of a piezoelectric device. The spark can also be produced by means of a lighter stone activated by a controlled drive mechanism.

For this purpose also, the device for implementing this method is characterized in that it comprises a barrel provided with a closed bottom and a frontal mouth, said mouth being located in said predetermined zone, above of the layer of snow to be evacuated by said avalanche, means for filling this gun with a gaseous mixture of a fuel and an oxidizer and means for triggering the explosion of this mixture inside this gun.

The explosion of this mixture inside this barrel.

The device preferably comprises at least one tank containing the fuel and a tank containing the oxidant, a first circuit connecting the fuel tank to said barrel, and a second circuit connecting the oxidant tank to said barrel.

The barrel is preferably equipped with mixing means arranged to ensure the homogeneity of the gas mixture in this barrel. It also includes means for generating a spark, arranged near its closed bottom.

Said means for generating a spark can be arranged in an intermediate zone between its closed bottom and its front loop.

In a preferred embodiment, the bottom of the closed barrel is anchored to the ground and its frontal mouth is oriented towards the surface of the snowpack.

Said front muzzle of the barrel is advantageously equipped with means for ensuring the diffusion of the breath and of the shock wave caused by the explosion.

According to a particularly convenient embodiment, said means for diffusing the breath and the shock wave comprise a flare defining said front mouth.

The barrel preferably has an elongated shape and comprises a gradual narrowing of the section in the direction of the frontal mouth.

The ignition device can be of the piezoelectric type. It can also include a lighter stone, or an electric explosive igniter, or firing electrodes associated with a high voltage source to create an arc between said electrodes.

The present invention will be better understood with reference to the description of exemplary embodiments and the attached drawing in which FIG. I represents a schematic overview of an embodiment of the device according to the invention, FIG. 2 shows a variant of the device of FIG. 1, fig. 3 shows a view of another embodiment of the device of the invention, FIG. 4 shows a schematic view of a variant of the device of the invention as shown in FIG. 3, FIG. 5 illustrates another embodiment of the device according to the invention, and FIG. 6 shows a schematic view of another embodiment of this device.

With reference to fig. 1, the device shown essentially consists of an elongated barrel 10 having a closed bottom 11 and a front mouth 12 formed at its opposite end from the closed bottom II. The barrel 10 is fixed to its base by anchoring in a rigid rigid construction 13 consisting for example of a concrete block secured to the wall of the mountain, and in the vicinity of its anterior end by a carrying arm 14 supported by a block d anchor 15, for example made of concrete.

The barrel 10 is connected to a first circuit 16 which ensures the supply of oxidizing gas which is preferably oxygen coming from reservoirs 17 of liquid oxygen and passing through a buffer tank 18 which can be replaced by a flow meter and other part in a second circuit 19 of fuel gas from a source 20 constituted for example by a bottle of propane or another combustible gas, and passing through a buffer tank 21 which can also be replaced by a flow meter. The two circuits 16 and 19 open into the interior of the barrel 10 by injection nozzles which are designed to simultaneously inject the fuel gas and the oxidant gas in the proportions required to obtain an explosive mixture.

As shown in the figure, the sources of oxidizing gas 17 and fuel 20, as well as the buffer tanks 18 and 21 and a remote control unit schematically represented by the housing 23, are advantageously housed inside a construction 24 arranged in a protected place upstream of the barrel 10.

The barrel 10 has, in this embodiment, a shape which narrows in the direction of its frontal mouth. The latter is equipped with a deflector cap 25 whose purpose is to return the breath caused by the explosion inside the barrel towards the snowpack whose surface is preferably located a few meters below the front mouth of this cannon and diffuse this breath over as wide a surface as possible. It will be noted that the height of the carrying arm 14 is calculated such that the front mouth 25 is always approximately 2 m above the upper surface of the snowpack when it is decided to fire to trigger an avalanche .

In the example shown, the ignition is done by means of a spark plug 26 or any other electrical, piezoelectric, explosive, mechanical, etc. device capable of causing a spark. In this embodiment, the spark plug is mounted on the closed bottom 11 of the barrel 10. In this case, the explosion begins in this zone and propagates at an increasing speed in the direction of the front mouth 25.

The breath, caused by the explosion and diffused by the deflector cap 25, destabilizes the snowpack and triggers the avalanche. Furthermore, the shock wave due to the explosion acts on the anchor block 13 and propagates through the rock wall, which constitutes the base of the slope supporting the snowpack which one wants to detach, and generates a cracking of this mantle at its base. The combined effects of the shock wave and the blast are generally sufficient to trigger the avalanche following an explosion. If a first explosion is insufficient to achieve the desired objective, a new filling of the tank can be controlled remotely and a second, or even a third or fourth shot, can be triggered to generate the desired effect.

Fig. I describes a device corresponding to an advantageous embodiment usable in certain contexts well defined by the geographic site of their establishment. Many variants can be imagined depending on the local context of implementation of the system.

The variants illustrated in FIGS. 2 to 6 each meet certain specific needs but all respect the basic principle of the device of FIG. 1.

Fig. 2 shows a device which differs from that of FIG. 1 by the fact that the barrel is adjustable in height. To this end, the closed bottom 11 of this barrel is placed on a pivoting seat 30, articulated on a fixed axis 31 carried by a support 32 made integral with the anchoring block 13. For this purpose also, the support arm 14 of the device of fig. I has been replaced by a telescopic arm 33 which is articulated by means of an axis 34 on a connecting piece 35 connected to the barrel and by an axis 36 on a flange 37 secured to the base or to the column 15.

This variant allows the installation of the device in a site where the snow depth can be variable, the height of the front end of the barrel 10 being then adjusted at the start of the winter season according to the average heights of the snowpack at the location of the implementation of the system observed in previous years.

Fig. 3 shows another embodiment of the device in which the barrel 10 comprises a rear cylindrical section 40 and a front section 41 in the form of an elbow which ends in a deflector 42 defining the front mouth 12 of this barrel. The closed bottom 11 of the barrel 10 consists of a thick sheet metal plate 43 which is fixed directly to the anchoring block 13, the base of which, as before, is made integral with the blank of the mountain. The filling circuits 16 and 19, respectively associated with controlled valves 44 and 45, make it possible to inject the oxidizing gas and the fuel gas respectively by an injector 22 mounted in the rear part of the barrel 10. In this embodiment, the ignition means 46 are mounted in a part of the barrel situated approximately at the rear third of its length. Thanks to this position, the explosion is initialized at this location and propagates in both directions, that is to say towards the closed bottom of the barrel where it causes a shock wave which is transmitted to the anchoring block 13 and shakes the base of the snowpack, and towards the frontal mouth where it generates a breath which disturbs the snowpack represented by line 47, at its surface in the area below said front mouth 12. The barrel is as previously supported by an arm 14 fixed on a column or a support block 15. In the case where the ignition takes place in the central part of the barrel, there are fairly complex phenomena of reflection of the rear wave and double explosion in the open area of the barrel.

Fig. 4 illustrates a variant of the device of FIG. 3 in which the injection nozzle, disposed at the rear of the barrel 10, has been replaced by a series of injection nozzles 22 mounted at the base of the cylindrical section 40 of this barrel. The ignition device 46 has been moved forward, substantially at the junction of the section 40 and the elbow 41. This embodiment makes it possible to reinforce the rear wave and to generate a double explosion at the front of the barrel in due to a reflection which occurs on the closed bottom 11 of the barrel. In this case, this closed bottom 11 has a rounded shape 50 which allows better transmission of the shock wave to the anchor block 13 and good reflection of this wave towards the front muzzle of the barrel.

Fig. 5 illustrates another embodiment in which the barrel 10 has a flared shape and an increasing section from the closed bottom 11 to the front mouth 12. The supply circuits of the oxidizing gases 16 and fuel 19 open out at the rear of the barrel at level of the closed bottom which has the smallest section, and the ignition point 60 is arranged in the vicinity of this closed bottom. In this case, the explosion propagates from the rear to the front to create a breath acting on the upper surface of the snowpack.

Fig. 6 illustrates another embodiment which in a way constitutes a combination between the embodiments of FIGS. 3 and 5. The barrel 10 consists of a tapered rear section 70 which narrows from the rear to the front, a central section 71 of frustoconical shape which widens from the rear to the front, an elbow 72 which extends the central section 71 and a deflector 73 which defines the front mouth 12. The closed bottom II of the barrel 10 is constituted by a thick sheet metal or steel plate 74 which is made integral with the anchoring block 13. The filling of the fuel and oxidizer gases respectively takes place through an injection nozzle 22 connected to the circuits 16 and 19 by means of valves 44 and 45 identical to those shown in FIG. 3.

The ignition device 75 is mounted at the junction of the two sections 70 and 71.

This device has the advantage of causing an explosion which propagates in both directions, which has the effect of causing both a surface action and an action of depth on the snowpack.

 It is obvious that the present invention is not limited to the embodiments described but can undergo different modifications and come in various variants obvious to those skilled in the art. This is how the single barrel can be replaced by a range of barrels secured to the same anchor block. Furthermore the shape and dimensions of the barrel can be modified according to the needs linked to the site. The position of the ignition point is chosen according to the effects which one wishes to obtain. Furthermore, the fuel gas used can be propane or any other gas making it possible to produce an explosive mixture either with pure oxygen, or with air, or with a mixture of oxygen and air.

Claims (27)

Claims I. Method for triggering an avalanche, in which one or more explosions of an explosive material are caused in a predetermined zone where it is desired to trigger the avalanche, characterized in that at least one explosion is caused by an mixture of fuel and gaseous oxidizer inside a barrel having a closed bottom and a frontal mouth and in that the breath and / or the shock wave caused by this explosion are diffused in said predetermined zone, above the layer of snow to be evacuated by said avalanche. 2. Method according to claim 1, characterized in that a combustible gas is used as gaseous fuel. 3. Method according to claim 2, characterized in that the combustible gas is chosen from the group of substances comprising hydrogen, tetraine, acetylene, propane, methane, and a mixture of these substances. 4. Method according to claim 1, characterized in that one uses oxygen or ozone as gaseous oxidizer. 5. Method according to claim 1, characterized in that air or air enriched with oxygen or ozone is used as the gaseous oxidant. 6. Method according to claims 3 and 4, characterized in that one uses a gas mixture composed of 1/6 by volume of propane and 5/6 by volume of oxygen. 7. Method according to claim 6, characterized in that this mixing is carried out at atmospheric pressure. 8. Method according to claim 1, characterized in that the gaseous fuel and the gaseous oxidant are simultaneously introduced into the barrel, through a mixing device arranged to form a homogeneous mixture. 9. Method according to claim 1, characterized in that one causes the explosion of the mixture by means of a spark generated inside the barrel, in an area arranged near the closed bottom of this barrel. 10. Method according to claim 1, characterized in that one causes the explosion of the mixture by means of a spark generated in the barrel, in an intermediate zone located between the closed bottom and the frontal mouth. 11. Method according to claim 1, characterized in that the explosive mixture is prepared by passing respectively the fuel gas and the oxidant gas from sources of these gases under pressure through buffer tanks where they are at a pressure close to of atmospheric pressure. 12. Method according to claim 1, characterized in that the explosive mixture is prepared by passing the fuel gas and the oxidant gas respectively from sources of these gases under pressure through flowmeters to define the respective volumes of the components. 13. Method according to any one of claims 9 or 10, characterized in that the spark is produced by means of a piezoelectric device. 14. Method according to any one of claims 9 or 10, characterized in that the spark is produced by means of a lighter stone actuated by a controlled drive mechanism. 15. Device for implementing the method of claim 1, comprising means for causing at least one explosion of an explosive material in a predetermined area where it is desired to trigger the avalanche, characterized in that it comprises a cannon provided with a closed bottom and a frontal mouth, said mouth being located in said predetermined zone, above the layer of snow to be evacuated by said avalanche, means for filling this cannon with a gaseous mixture of 'A fuel and an oxidizer and means to trigger the explosion of this mixture inside this barrel. 16. Device according to claim 15, characterized in that it comprises at least one tank containing the fuel and a tank containing the oxidant, a first circuit connecting the fuel tank to said barrel, and a second circuit connecting the oxidant tank to said cannon. 17. Device according to claim 15, characterized in that the barrel is equipped with mixing means arranged to ensure the homogeneity of the gas mixture in this barrel. 18. Device according to claim 15, characterized in that the barrel comprises means for generating a spark, arranged near its closed bottom. 19. Device according to claim 15, characterized in that the barrel comprises means for generating a spark, arranged in an intermediate zone between its closed bottom and its front loop. 20. Device according to claim 15, characterized in that its closed bottom is anchored to the ground and that its frontal mouth is oriented towards the surface of the snowpack. 21. Device according to claim 20, characterized in that said front muzzle of the barrel is equipped with means for ensuring the diffusion of the breath and of the shock wave caused by the explosion. 22. Device according to claim 21, characterized in that said means for diffusing the breath and the shock wave comprise a flare defining said front mouth. 23. Device according to claim 15, characterized in that the barrel has an elongated shape and comprises a progressive narrowing of the section in the direction of the frontal mouth. 24. Device according to any one of claims 18 or 19, characterized in that the ignition device is of the piezoelectric type. 25. Device according to any one of claims 18 or 19, characterized in that the ignition device comprises a lighter stone. 26. Device according to any one of claims 18 or 19, characterized in that the ignition device comprises an electric explosive igniter. 27. Device according to any one of claims 18 or 19, characterized in that the ignition device comprises ignition electrodes associated with a high voltage source to create an arc between said electrodes.