ES2588018A1 - Definitive disposal system for nuclear waste (Machine-translation by Google Translate, not legally binding) - Google Patents

Abstract

Definitive disposal system for nuclear waste. System of elimination of the nuclear waste by means of its expulsion of the earth orbit, sending them to the sun or to planets where the conditions of gravity, pressure and temperature will absorb them destroying them of definitive form. The ejection is done using aerostats and recoverable ships, in addition to the rockets of expulsion and control outside the earth's orbit. (Machine-translation by Google Translate, not legally binding)

Description

System of definitive disposal of nuclear waste.

Technical Sector

The invention is in the technical sector of nuclear energy production and specifically in the treatment of nuclear waste, together with the aerospace sector.

State of the Art

Nuclear waste is currently stored in special silos, but not disposed of, so the risk remains for life. Safety with respect to the still existing contaminating effects of waste depends primarily on the containers that store them and the stores that house them.

This implies storage costs that last for an indeterminate time. The capitalization of these expenses, since time is undetermined, is very large.

Object of the invention: technical problem - proposed solution

The object of the invention consists of a system for the elimination of nuclear waste by means of its expulsion from the Earth's orbit, sending them to planets where the conditions of gravity, pressure and temperature will absorb them definitively, or even to the sun where they will be eliminated in a way definitive or at least the problem that can be considered eliminated will be removed so much.

The technical problem is the storage of fuel waste from depleted nuclear power plants for energy production, but with a radioactivity that constitutes a danger to life and requires storage conditions and an indefinite maintenance over time. Waste is increasingly increasing and, logically, its quantity will increase if the activity of energy production continues by this method, which requires the increase of the warehouses that must grow indefinitely to the compass of the energy production by the power plants nuclear. The increase in waste would stop at the time when the production system was changed by other methods, but the problem of waste stored up to that point will persist indefinitely.

The proposed solution consists of a cheap system of elevating the waste by aerostats to heights near the stratosphere, in a first phase. By means of the same system, the ship, the rocket and fuel that provide the waste with sufficient speed to put it into orbit in a second phase and provide the escape velocity of the earth's attraction in a third phase are elevated.

These fundamental phases can be increased by increasing the number of rocket or glider ships similar to the ferries that can be attached to the

set. This will be in such a way that the ships used to give momentum will intervene in each phase that will correspond to an increase in speed and will be recoverable by wings to be able to plan, or any other method that allows them to land, while those used to drive more beyond escape speed, they will be unrecoverable.

The aerostats will have the appropriate form to allow the assembly of the different elements that will intervene. The elements that will intervene will rise to a certain height at which the density of the atmosphere is sufficient to achieve the necessary momentum to reach the speeds needed.

The fundamental elements that will intervene in addition to the ascent aerostats will be:

‐A glider ship capable of reaching high speeds, similar to those

Current ferries, which will be recoverable and will serve multiple

operations.

‐A rocket that reached certain speeds and heights will provide the waste with

escape velocity needed to overcome the force of land attraction

expelling him You can allow the redirection of your path in space

outside or in case of emergency when re-entering the Earth's orbit. This in a

principle is linked to the previous glider ship, but at some point in

that the speed is sufficient, it would come off to continue increasing its

speed and increasing its height.

‐The necessary fuel that will be high performance, such as liquid hydrogen

or similar, it will be encapsulated. ‐The waste that is intended to be removed goes into the previous rocket mentioned.

The aerostates raise the different elements to the necessary heights, where they are assembled and from where they are released so that in the initial fall the set takes speed. Immediately, the engines start running at full speed. Before the descent is excessive, due to the effect of gliding and the increase in speed, an elevation is produced up to the optimum height and at speeds close to the escape velocity, to achieve the greatest possible thrust with the least atmospheric friction. Subsequently, the rocket that is attached to the glider ship, similar to a ferry, would take off from it, carrying as a load the waste to be removed, along with the fuel necessary to continue it alone, increasing the speed and height until leaving the outer space and take the desired course to reach the planet chosen for its conditions for self-destruction. Meanwhile the glider or ferry will gradually lose speed and height, to land again and begin a new operation.

Description of the drawings.

The system, as can be seen in the images, consists of sending nuclear waste from the production of energy to the sun or to planets with the conditions of gravity and temperature sufficient to eliminate them definitively, so that their attractive power collaborates in the transfer ( Figure 1)

The shipping process will be done in 3 phases (Figure 2)

‐The 1st in which the elements that will provide the necessary velocities for the exit of the Earth's orbit together with the waste itself are raised vertically. In this, aerostats will be used to save the fuel from the lift. At the end of this phase the different elements are coupled once promoted.

‐The 2nd is to drop the assembly while ignition of the engines of a winged ship, so that the height is recovered and rises with increasing speed, even the necessary speed is printed before the set escape from Earth's orbit. This ship similar to a ferry is reusable so the cost is minimized.

‐The 3rd is to print the waste at a speed greater than that considered to be an escape and to provide a path that will lead to the sun or the planet that absorbs it. In this phase the rocket in which the waste goes is put into operation by taking off from the shuttle to leave the Earth's orbit.

The fundamental elements to send, as indicated in Figure 3, are the following:

‐Aerostats (1) joined in such a way that the elements to be lifted can be hung from the assembly and will subsequently acquire the necessary speeds for the expulsion of waste. The size will be adequate to lift the loads and the number and arrangement will be as indicated (3) so that they can load and allow the coupling of the different pieces that are climbed by gravity. The aerostats will be based on Helium to provide sufficient safety, but may have hydrogen-accelerating balloons (2), separated from the set to ensure safety in case of fire and that will collaborate by increasing the speed due to its lower density regarding Helium. The speed provided by these floats will be controlled by compressors that will compress the Hydrogen gas by increasing its reduced density and therefore decreasing its buoyancy, or by letting it escape into the air in a controlled manner. These aerostats will have the necessary mechanisms for their governance and positioning by means of control propellers and by internal chambers that will control the density of the assembly to make it ascend or descend, according to the needs. The first load that will ascend will be the one that must remain at the top of the assembly once assembled (4) and which in this case will be the winged apparatus similar to the ferry

(4) which will be recoverable and will intervene in the greatest possible number of promotions. The second load that will ascend will be the rocket (5), which will transport the radioactive waste and the necessary fuel, as well as the elements of government and remote control. This order could be changed according to the planning needs.

The coupling or assembly of the elements will be done as indicated in figure 4, placing a set of aerostats on the other, allowing the lowering of the elements, first for their union and then to be released and begin to fly by the action of their own engines. (8), (9), (10) and (11).

The wings of the ferry along with its thrust power will prevent the set from falling at the beginning and will cause the lift at a later time, increasing the speed to a certain point called escape velocity, in which the rocket that carries the waste will be released and that it will continue to increase the speed to get rid of the gravitational attraction of the earth.

Embodiment

The realization will be done taking into account the existing studies for the orbiting of satellites and the sending of objects beyond the points affected by the gravitational terrestrial attraction.

The ascent by aerostats will be carried out in latitudes where, due to the action of the terrestrial rotation, the rotation speed is greater, or from different latitudes, but taking them by air navigation to these optimum latitudes.

10 The assembly of the modules above will be done using the propellers that allow the displacement of the aerostats horizontally and vertically with the compressors that achieve the ascent or descent of the ship by varying its density with respect to the air. The precision of the union will be achieved by means of mooring ropes that will hold some inflatables with respect to others. Once the aerostate assemblies have been positioned and fixed to each other, the cables that will then be released for self-propelling will be assembled using cables such as those of a crane.

The glider may be placed at the top or bottom so that the aerodynamics of the same propitiate gliding and decrease the descent speed once the assembly has detached from the aerostats.

The starting of the engines of the glider ship, once it has detached from the aerostats, will be immediate, but always once loose so that the heat of the combustion does not harm the aerostats.

Industrial application

30 This system has its application in the nuclear energy production process, in the final part corresponding to the treatment of the radioactive waste that is generated. Although the system could be used for other types of waste of high toxicity and very complicated treatment such as nuclear waste.

Claims (3)

5 1. Nuclear waste disposal system characterized in that it is carried out by means of its expulsion from the Earth's orbit, sending them to the sun or planets where the conditions of gravity, pressure and temperature will absorb them, destroying them permanently. The expulsion is carried out using aerostats, recoverable ships and ejection and control rockets outside the Earth's orbit. 2. The nuclear waste disposal system according to claim 1, characterized in that the ascent of the aerostats is carried out with the help of hydrogen-based balloons as accelerators and aids in the ascent of the loads to be lifted.

3. The nuclear waste disposal system according to claim 1, characterized in that several recoverable propeller ships and / or several unrecoverable rockets are used in the different launch phases in which they intervene as propellants.

A system for the disposal of nuclear waste according to claim 1, characterized in that the order of placement of the different propellant elements is opposite from top to bottom.

5. Nuclear waste disposal system according to claim 1 25 characterized in that in addition to nuclear waste other types of waste can be eliminated, including replacing nuclear waste with these. FIGURE 1 FIGURE 2 FIGURE 3 FIGURE 4