FR2942346A1 - Waste i.e. radioactive waste, eliminating method, involves launching waste protected thermally beyond atmosphere at destination of sun with specific speed allowing waste to escape at terrestrial attraction - Google Patents

Abstract

The method involves thermally protecting waste such as radioactive waste (2), by a superconductive coating after cooling the waste at a very low temperature that is lower than 1 degree Kelvin. The waste protected thermally beyond an atmosphere at a destination of the sun is launched with a specific speed allowing the waste to escape at terrestrial attraction. An isolated coating of a reflective final coating is covered. An independent claim is also included for an installation for elimination of waste, comprising a horizontal tube.

Description

The present invention relates to a method and a waste disposal facility, in a definitive manner, such as in particular radioactive, toxic waste, etc. It is known that waste management has become an important social issue because of risks to the population and environmental nuisances. If the waste described as usual is now treated by technical fields more and more controlled without real major risk, while respecting the environment and population, on the other hand, it is not the same when it comes to wastes classified as ultimate (radioactive, toxic, chemical, ...) defined as not being recyclable or recoverable in an energetic way from currently known techniques. In fact, these ultimate wastes are brought to strictly regulated storage sites in which they are generally buried directly or indirectly after arrangement in specific containers and / or particular prior treatments, such as vitrification for certain nuclear waste, and this, to great depths and in adequate stable soils. However, while these storage sites provide a relatively short-term and relatively safe solution to the storage problems of these hazardous materials (at least for short-lived ones), in the medium and long-term integrity of site facilities and structures can not be fully guaranteed and, therefore, that of ultimate waste stored with consequences for future populations. It is also important to consider the potential risks of natural disasters (earthquakes, floods, etc.) that may occur and damage sites even if they are currently in protected areas. In addition, as the quantities of this final waste products are increasing, the search for new sites is inevitable, which poses problems vis-à-vis the local populations who do not want to have such facilities nearby. Also, there is a real need to find other complementary solutions to these storage sites, at least with regard to highly toxic hazardous waste, including radioactive type.

Of course, we have also thought of sending radioactive waste into space. But if the idea is attractive, it involves the use and possible loss of a rocket containing the waste at each mission, which is an unthinkable risk. The present invention aims to overcome the above disadvantages related to the shipment of waste in space. For this purpose, the process for eliminating waste, such as radioactive waste, by launching them in space, is remarkable, according to the invention, in that it consists in thermally protecting said waste and in launching said thermally protected waste beyond the atmosphere, with a speed allowing them to escape the terrestrial attraction. Thus, as the waste is thermally protected, they cross the different layers of the atmosphere while maintaining their integrity, without risk of heating by avoiding their vaporization or disintegration and pollution of the environment. In addition, the method of the invention overcomes the above problems related to the sending of a rocket or other spacecraft to take the waste into space, since only the latter are launched from the ground into the ground. the space where they are favorably and naturally incinerated, in the sun, which is, in fact, because of gravitation, their final destination. Preferably, the thermal protection of said waste consists in cooling them to a very low temperature of less than 1 ° K.

Thus, by cooling the waste to be removed at such a temperature, it is advantageously within the range of application of the third principle of thermodynamics which states, briefly, that the entropy of a system tends to zero when the absolute temperature tends to zero, which results in a mass heat tending to zero with temperature. In this way, a very cold body (waste), cooled to a temperature below the Kelvin degree, does not heat up even if it moves at a very high speed (greater than the speed of release of the Earth's gravitational attraction). at least 11 km / s) in the more or less dense atmospheric layers, generating temperatures of several thousand ° K upon contact. According to the third principle of thermodynamics, this body will be subject neither to conduction nor to convection, but, on the other hand, it will be subjected to radiation. It is also noted that, at very high speeds, the passage time of the atmosphere through the waste is less than a few seconds (of the order of 3 to 4 seconds) so that, even if the thermal exchanges established between the waste at such a speed and air are different from those in usual conditions, the waste will not melt and no vaporization will occur.

Preferably, said waste is cooled to a temperature of the order of 1 ° mK. Thus, one is very close to the absolute zero optimizing the integrity of the waste cooled to eliminate launched in the space towards the sun.

And, to obtain a total safety of the launch of the waste during the passage of the atmospheric layers without risk of polluting the environment, the thermal protection of said waste by bringing them to a temperature lower than 1 ° K consists, moreover, to coat them with a thermally insulating coating having a lower specific heat than said waste. Indeed, it is known that the specific heat C of a conductive body (like metal waste) at constant pressure, is written in the form C = aT3 + bT where a and b are measurable coefficients and T the temperature while for an insulating body (like the thermally insulating coating), the specific heat C is written as C = aT3. Thus, when the temperature T is less than 1 ° K (0 <T <1), we have T3 <T. Thus, the specific heat of the insulating coating is even lower than that of the waste, the insulating coating not heating up. and preventing waste from warming up.

To avoid the problems due to the radiation generated by the passage of waste in the air, the method consists in covering said insulating coating with a reflective final coating. In addition, depending on the launching device used, as will be seen below, it is possible to cover said thermally protected waste with a superconducting coating. The invention also relates to a waste disposal facility, particularly radioactive, for implementing the method defined above. To this end, the waste disposal installation is remarkable, according to the invention, in that it comprises a device of the barrel type, inside which are placed said thermally protected waste and which is capable of electromagnetically impressing them with a speed enabling them to escape from the earth's gravitational attraction, following a path directed towards the sun.

Thus, the use of a gun launch device makes the installation, on the one hand, financially possible since it avoids the loss of a space launcher with each shot of waste and, on the other hand, technical- reliable with almost total security since its only mode of failure will be to not be able to pull the waste in case of malfunction, which does not cause environmental pollution. Of course, one can not completely rule out a failure where the waste would not be sent by the gun at the appropriate speed, but the probability of occurrence of this event is close to zero because the waste sent has a relatively low mass. (for example, less than 20 g) at each shot, limiting the potential release of radioactive material into the atmosphere and that, for this, it would still be necessary that the output speed of the gun is extremely low for this material to fall on Earth. The installation of the invention with a gun launching device thus achieves its objectives, such as optimum safety with functional reliability and an absence of terrestrial pollution. Preferably, said waste is in the form of spherical pellets, each shot of said barrel corresponding to the launching of a spherical pellet.

In a particular embodiment, said gun comprises a horizontal tube with a magnetic wall, inside which the vacuum prevails, said waste thermally protected at very low temperature and covered with a superconductive coating is electrically charged so as to float-ter within said tube by Meissner effect, and a movable electric field is generated to accelerate said waste as it moves in said tube. As the length of the gun can be large (several tens of meters to a few kilometers long depending on the applied electric field), its horizontal disposition is preferable and, to avoid problems of resistance to air, the vacuum is made in the barrel, and to overcome problems of friction, the spherical waste loaded, cooled to a temperature below 1 ° K and coated with the superconductive coating, can then float in the magnetic wall tube by Meissner effect. In this particular embodiment, the outlet end of said horizontal tube is arranged vertically, facing upwards, and comprises a curved transition zone subjected to a magnetic field for progressively directing said accelerated waste vertically.

In another particular embodiment, said gun comprises a vertical tube inside which the vacuum prevails, said cooled and thermally protected waste is electrically charged, and a movable electric field is generated to accelerate said waste as and when required. sure of its displacement in said tube. The use of such a vertical tube gun eliminates the Meissner effect (removal of the superconductive coating) and the magnetic character of the tube. In these embodiments, the installation comprises an instrument for measuring the electrical charge of said waste. Thus, if it is lower than the desired value, shooting is prohibited and the waste reloaded.

According to yet another embodiment, the launcher may be a parallel rail gun, connected to a current source and brought into contact with each other by a movable conductive transverse bar having at its center said thermally protected waste to be eliminated. , so as to induce a magnetic field perpendicular to the plane of the current flowing between the rails and said bar and thus to generate a Laplace force parallel to said rails and accelerating said crossbar. Such rail guns are known and can launch projectiles at speeds higher than that required to overcome the land attraction when the mass of the body to be cast is low (a few tens of grams at most), which is the case of the waste in question. Furthermore, the installation further comprises a device for measuring the output speed of said waste. Thus, if this is lower than the desired speed, the next shot is prohibited until the maintenance operations have been performed. However, as previously stated, the dangerousness of the waste drawn, (low mass) is almost zero, since the probability of fallout on earth is almost zero. According to another characteristic, the installation may also comprise a laser device for ionizing or heating the air lying on the path followed by said launched waste so as to improve its penetration into the atmosphere. The figures of the appended drawing will make it clear how the invention can be realized. In these figures, identical references designate similar elements. Figure 1 shows schematically an embodiment of the waste disposal installation implementing the method of the invention, using a gun launching means. Figure 2 is a section of a waste to be removed by said installation in spherical form. Figure 3 shows schematically another embodiment of a waste disposal facility. In the schematic embodiment illustrated in FIG. 1, the disposal installation 1 of the waste 2 by sending them into the space destined for the sun comprises a launch device 3 of the barrel type 4, the tube 5 of which the constituent is arranged horizontally with a vertical outlet 6 upwards preceded by a curved transition zone 7 in a circular arc of 90 °. Given the length of the barrel to send the waste at a speed sufficient to overcome the gravitational attraction and some examples will be donated later, the term tube means a set of tubes as-semblées. In the vicinity of the closed horizontal inlet 8 of the tube, opposite its vertical outlet 6, is the waste to be eliminated 2 which is an ultimate waste and which is in the form of a spherical pellet 10. An embodiment of this is shown in FIG. 2 in relation to the launch device 3 with horizontal barrel 4. To print the desired speed at the spherical pellet 10, such as a speed greater than that required to escape the earth's gravity, that is to say at least 1 1 km / s in the vacuum, and prevent it from vaporizing or disintegrating by its heating in contact with the atmospheric layers, the installation 1, in this case with horizontal barrel 4, and the pellet itself have specific physical characteristics. Thus, as shown in FIG. 2, the spherical pellet 10 of radioactive material is, according to the invention, thermally protected because of its frictional contact with the dense atmospheric layers at such a launching speed. For this, the pellet is cooled to a very low temperature of less than 1 ° K and, preferably, substantially at 1 ° mK for the reasons mentioned above, for the implementation of the third principle of thermodynamics, and is covered with a metal coating 11 which, at this temperature, will become superconducting.

This is particularly advantageous since, as the tube 5 is horizontal, with the exception of its vertical outlet, and to avoid its friction in it, the pellet can be suspended inside the tube and float in it. this by the Meissner effect. In order to implement the latter, the at least internal wall 12 of the tube is obviously made magnetic, so that, under the action of the magnetic field of the tube and the superconducting nature of the cooled pellet, the Meissner effect is produces and puts the latter in levitation. Furthermore, the vacuum is made inside the tube 5 of the barrel 4 by means of an external device (not shown) having, at the vertical outlet of the tube, a diaphragm or other mechanism with a controllable opening and closing symbolized in FIG. 14 in Figure 1, and the pellet 10 is electrically charged. One way to charge the pellet is to consider it as one of the armatures of a spherical capacitor and isolate it, during charging, with a ceramic, so as to increase the dielectric constant between the plates. Thus, suitable electrical charges are obtained at acceptable voltages (a few hundred thousand volts to a few million). Around the superconducting metal coating 11, there is disposed a thermally insulating coating 15 with a minimum specific heat, lower than that of the waste pellet, in the manner specified above, thus actively participating in the thermal protection of the cooled pellet during its crossing. in the air. And said thermally insulating coating 15 is in turn covered by a final heat radiation reflective coating 16. The launch of the radioactive spherical pellet from the described installation 1 proceeds as follows. The pellet 10 is placed inside the tube 5 of the barrel 4, near its inlet 8. It also has a temperature of 1 ° mK and is electrically charged. A measuring device or instrument 17 controls the load thereof. The vacuum is made in the tube. By the magnetic field generated by the tube 5 and the superconducting character of the coating 11, the pellet 10 floats in the tube by the Meissner effect thus generated. It is then subjected to an electric field which will accelerate it more and more along the tube without air resistance as indicated by the arrows F. This electric field is local and moves synchronously with the pellet. At the end of the horizontal phase, the accelerated pellet 10 enters a region with a strong external magnetic field so as to curve its trajectory along the curved transition zone 7 and then to move vertically upwards and out of the end 6 barrel tube at the desired speed. At the outlet of the tube, a measuring device 18 controls the speed of the waste. By way of example, the spherical pellet 10 has a diameter of 1.5 cm and its mass is of the order of about twenty grams. The waste 2 may be actinides with a density of 104 kg / m3. The electric field can vary between 104 V / m and 106 V / m with an electric charge of the pellets from 0.01 C to 0.1 C depending on the length of the tube envisaged. For example, with a charge of 0.1 C and an electric field of 105 V / m, the tube has a length of the order of six kilometers. The speed reached by the spherical pellet is 27 km / s. This speed could of course be lower, the main one being to reach space by directing the dumpling towards the sun to be incinerated. The crossing of the atmosphere can be carried out in a time of about 6 to 7 seconds with temperatures around 3500 ° K. Although it is not shown in the figures, there can be provided a laser device whose beam is placed on the path or part of the path taken by the spherical pellets, especially in the dense layers of the atmosphere. This beam is used to ionize or heat the targeted air to improve the penetration of the atmosphere of the spherical pellets and thus reduce the friction with said layers and thus the output speeds. Another embodiment of the installation, not shown, consists in vertically arranging the launch device 3 to gun 4.

The tube 5 of the barrel is then rectilinear and vertical and this vertical arrangement no longer involves friction between the spherical pellets and the tube. In this way, the Meissner effect does not occur, leading to the suppression of the superconducting metal coating and the magnetization of the tube wall. With an electric field of 106 V / m and an electric charge of 0.01 C, the vertical tube has a height of 650 m, and with an electric charge of 0.1 C and an identical electric field, its height reaches 65 m . The launching device 3 of the installation 1 shown in FIG. 3 is a rail gun 20. The two parallel rails 21 are connected to an electric generator 22 and a transverse conducting bar 23 connects the two rails 21 perpendicularly by forming thus the electric circuit. The conducting bar 23 is movable along the rails and carries at its center the waste to be sent 2, namely the radioactive spherical ball 10 thermally protected by its cooling at a very low temperature and its coating of the thermally insulating coating. Briefly, when the current flows in the circuit thus closed, simultaneously an orthogonal magnetic field is induced, which results in a propulsion force F (Laplace force), parallel to the rails, which is exerted on the crossbar 23 and This is then accelerated continuously along the rails to achieve ejection speeds sufficient to overcome the earth's gravity and be sent into space, to the sun.

Claims (11)

REVENDICATIONS1. A method for removing waste, such as radioactive waste, by launching it in space, characterized in that it consists in thermally protecting said waste (2) and in launching said thermally protected waste beyond the atmosphere to the sun, with a speed to escape the gravitational pull. 2. Method according to claim 1, characterized in that the thermal protection of said waste (2) is to cool them to a very low temperature, less than 1 0K. 3. Method according to claim 2, characterized in that said waste (2) is cooled to a temperature of the order of 1 ° mK. 4. Method according to one of claims 2 and 3, characterized in that the thermal protection of said waste (2) by bringing them to a temperature below 1 ° K is, in addition, to coat with a thermally insulating coating (1 5) having a lower specific heat than said waste. 5. Method according to the preceding claim, characterized in that it consists in covering said insulating coating (15) with a reflective final coating (16). 6. Method according to one of claims 1 to 5, characterized in that it consists in covering said waste (2) thermally protected with a superconductive coating (II). 7. Installation for disposal of waste, especially radioactive, intended for the implementation of the method as defined in one of claims 1 to 6, characterized in that it comprises a launching device (3) of the barrel type. (4), inside which said thermally protected waste (2) is placed and which is capable of electromagnetically impressing them with a speed enabling them to escape the earth's gravity, according to a trajectory to the sun. 8. Installation according to the preceding claim, characterized in that said waste is in the form of spherical pellets (10), each shot of said barrel corresponding to the launching of a spherical pellet. 9. Installation according to one of claims 7 and 8, characterized in that said barrel (4) comprises a horizontal tube (5) with a magnetic wall inside which the vacuum prevails, in that said waste (2) thermally protected at very low temperature and covered with a superconductive coating (II) is electrically charged so as to float inside said tube by Meissner effect, and in that a movable electric field is generated to accelerate said waste (2) as it moves in said tube (5). 10. Installation according to the preceding claim, characterized in that the outlet end (6) of said horizontal tube (5) is arranged vertically and comprises a curved transition zone (7) subjected to a magnetic field for progressively directing said accelerated waste. vertically. 11. Installation according to one of claims 7 and 8, characterized in that said barrel (4) comprises a vertical tube (5) inside which the vacuum prevails, in that said waste (2) cooled and thermally protected is electrically charged, and in that a movable electric field is generated to accelerate said waste as it moves in said tube. 1 2. Installation according to one of claims 7 to 1 1, characterized in that it comprises a measuring instrument (17) of the electric charge of said waste (2). 13. Installation according to one of claims 7 and 8, characterized in that said launching device (3) is a gun (20) with parallel rails (21), connected to a current source (22) and brought into contact between them by a movable conductive transverse bar (23) having at its center said thermally protected waste to be removed (2), so as to induce a magnetic field perpendicular to the plane of the current flowing between the rails and said bar and to thereby generate a force Laplace parallel to said rails and accelerating said crossbar. 14. Installation according to one of claims 7 to 13, 1 o characterized in that it further comprises a device for measuring the output speed (18) of said waste. 15. Installation according to any one of the preceding claims, characterized in that it further comprises a laser device for ionizing or heating air in the path followed by said waste.