| WO/2012/163966 | ENERGY PRODUCING DEVICE AND METHOD |
| WO/1991/006103 | ELEMENT AND ENERGY PRODUCTION DEVICE |
| JPH03160396 | INITIATION OF FUSION REACTION IN SOLID SUBSTANCE |
| US4759894A | 1988-07-26 | |||
| US3437862A | 1969-04-08 | |||
| US2728877A | 1955-12-27 | |||
| US4836972A | 1989-06-06 | |||
| US4793961A | 1988-12-27 | |||
| US4853173A | 1989-08-01 |
L Recherche, Vol. 20, June 1989 C'RISTIAN AMATORE: "La fusion froide aura-t-elle lieu?", ; figure 1.
| 1. | Method of generating energy from fusion of light atomic nuclei, preferably hydrogen isotopes, characterized in that a process comprises several unit processes, each fullfilling at least one of the following functions: generating a plasma containing protons, deuterons or tritons, generating an electrical field to accelerate said ions onto a target containing or covered by a layer of atomic or chemically bound hydrogen isotopes continuously renewing the hydrogen layer on the radiation tar¬ get, and transforming the heat generated by the nuclear fusion reac tions to pressurized water for use in known heat power pro¬ cesses . |
| 2. | Method according to claim 1, characterized in that during the acceleration the plasma is encased in a magnetic fluid. |
| 3. | Method according to claim 1 or 2, characterized in that a high voltage of preferably more than 20 kV is discharged through an electrical arc or spark between two electrodes constituting a cathode and an anode immersed in heavy water, D20, and that the discharge is continuous or intermittent. ,. |
| 4. | Method according to any of the claims 1 3, characteri¬ zed in that the heavy water is pressurized, preferably to about 10 MPa. |
| 5. | Method according to any of the preceeding claims, charac¬ terized in that the heavy water contains a supension of solid particles of a ferromagnetic material with a diameter of about 10 nm. |
| 6. | Method according to any of the preceeding claims, charac¬ terized in that the discharge occurs in an electrolysis cell for decomposition of heavy water, and that the cathode thereby also is cathode for the discharge. |
| 7. | Apparatus for use of the method according to the preceeding claims, characterized in that it comprises a tank (1) for electrolyte (4) with inlet (5) for electrolyte, outlet (8) for steam and valves (6,9), a central electrode (2) shaped as a rod or a tube functioning as cathode for the electrical discharge and provided with flanges or short projections, and a surround¬ ing outer electrode, anode, (3) in the shape of a net or a per forated plate, and connections (7,14) to a high voltage source. |
| 8. | Apparatus according to claim 7, characterized in that the central electrode (2) consists of palladium or titan, the outer electrode (3) of platinum and the electrolyte (4) of heavy wa ter, D20, or an alkali metal deuteroxide or D2S0 dissolved in heavy water. |
| 9. | Apparatus according to claim 7 or 8, characterized in that a further tubular electrode (13) is arranged as anode for the decomposition electrolysis having connections (17,18) between the respective electrodes (13,2) and a low voltage source, and that a diaphragm (15) with an outlet pipe (16) for D2 is surrounding the electrode (2) . |
| 10. | Apparatus according to any of the claims 7 9, charac¬ terized in that particles of a ferromagnetic material with a diameter of about 10 nm are suspended in the electrolyte (4) , and that the tank (1) is surrounded by a magnetic field (12) . |
This invention relates to a method of generating energy from the fusion of light atomic nuclei, preferably isotopes of hydrogen, and an apparatus for performing the method.
Since many years considerable research has been pursued with the purpose of obtaining fusion of light nuclei, such as deuterons, d, protons, p, and tritons, t, to generate energy in a manage¬ able form for industrial and other use.
This fusion research has primarily been concentrated on methods to obtain a magnetic containment of a plasma at a high enough temperature and with such a deuteron density, that a fusion reaction will occur according to the well-known reaction:
d + d = 3 He (0,82 MeV) + n ( 2,45 MeV)
In spite of very considerable efforts this line of research has not yet definitively proved that it may result in an industrial process of energy conversion, primarily due to the fact that the necessary temperature and density of the plasma cannot be main- tained for a sufficiently long time.
The probability that a fusion will occur in a plasma usually is described as a quotient, T x n x τ, of the prevailing tempera¬ ture, T°K, deuteron density, n q/m- , and time τ in seconds. In a preferred apparatus according to the invention, the value of T x n x τ can be calculated to be high enough for fusion reactions to occur at a rate of interest for practical use.
Recently a possibility to obtain so-called "cold fusion", prin- cipally an electrolysis of heavy water with a palladium cathode and an anode of platinum or gold, has been proposed and tested - so far without conclusive results. Theoretically it was specu¬ lated that fusion reactions under such circumstances, after ab-
sorption of the heavy hydrogen gas in the Pd-metal and formation of D 2 _ molecules, might occur through the intermediation of so- called quasi-particles (muons) with one negative electron charge but with bigger mass than the electron mass. A muon with larger mass than the electron mass m~ has the ability to bind deuterons d more close in the molecule D 2 . It has been calculated that a muon with the mass 5 me would decrease the distance between the d nuclei to about 0.15 A. In this distance the repellant Coulomb potential is about 95 eV and the probability for a penetration through the potential barrier because of quantum mechanical tun¬ nel effects is still low. The probability of tunnel effects would however increase considerably if the deuterons could be given a higher kinetic energy.
The method according to the invention is characterized in that it comprises a number of unit processes each complying with at least one of the following f nctions:
- generating a plasma containing protons, deuterons, or tri- tons, - generating an electrical field for acceleration of said ions towards a target containing or covered with a layer of free or chemically bound heavy hydrogen isotopes,
- continuously regenerating the hydrogen layer on the radiation target, and - transferring the heat released by the nuclei fusion to pressu¬ rized water for use in known heat power processes .
The apparatus according to the invention comprises a tank with electrolyte inlet and damp outlet with valves, a central tube or rod electrode with flanges or short projections, a surrounding electrode in the shape of a net or a perforated plate, and cab¬ les to a high voltage source.
The principle of the method to obtain nuclear fusion according to the invention is to combine mentioned unit processes and there included physical effects to maximize the probability of reactions d + d or p + d to such an extent that industrial energy production is feasible.
The process will be described in detail below with reference to the accompanying drawings, in which:
Figure 1 shows an apparatus according to the invention, and
Figure 2 shows an alternatively designed apparatus according to the invention.
In a tank (1) is provided an electrode system comprising a cen- tral electrode 2 in the shape of a rod or a pipe closed at its lower end and made of Pd, Ti or a metal alloy with great capa¬ city of adsorbing hydrogen gas, and an outer electrode 3 in the shape of a tubular net or a perforated plate of platinum. The tank is filled with an electrolyte 4, such as heavy water, D 2 0, pure or mixed with H 2 0, which is supplied by the conduit 5 with the valve 6.
The outer electrode 3 is connected to the positive pole of a high voltage source by an electrical cable 5 and the central electrode 2 is connected to the negative pole by a cable 14. The high voltage source, e.g. a condenser is discharged by an elec¬ tric arc between the electrodes 2 and 3. The time of duration, energy delivery and frequency of the spark should be variable within wide limits . Depending of the geometry of the electro- lytic cell an optimum adjustment of these variables is done at the same time as the neutron density in the environment of the tank is an indicator that fusion reactions occur.
The water will be heated and vaporized by the supplied energy and the fusion energy. At a suitable steam pressure the steam is led out through a conduit 8 with a valve 9 and led to the heat exchanger and condenser. Thereafter the water is returned to the tank through the conduit 5 with the valve 6.
The central electrode, the tubular cathode 2, is preferably provided with short projections or flanges so that the increased field strength there will promote the formation of discharge si¬ tes. The pipe 2 may first be evacuated and then closed by a
valve 10. By coupling a branch pipe 11 to a vacuumeter penetra¬ ted deuterium is measured.
In an application of the invention the electrolyte consists of a 2 - 10 % by weight suspension in heavy water of magnetic par¬ ticles e.g. magnetite, Fe 3 0 , of about 10 nm size. When a current flows through the plasma created by a spark or an electric arc in a high voltage discharge a magnetic "field is formed which will considerably increase the apparent density around the plasma track. Thus the current itself will create a magnetic enclosure of the generated deuterons and other charged par¬ ticles . This effect may be strengthened by surrounding the tank with a magnetic field, whereby the internal fluid pressure in the whole suspension E) 2 0 - Fe 3 0 4 can be substantially increased. Of course this effect cannot resist the pressure from the gene¬ rated steam, which rapidly escapes, but after that the deuteron generating reactions in the spark has occured.
In a preferred embodiment of the invention the tank 1 is pro- vided with a further electrode 13, functioning as the anode in an electrolytic cell wherein 2 is the cathode for the electroly¬ tic decomposition of D2O. The electrolyte 4 consists of D 2 O and an added acid e.g. D S0 4 , or an alkalideuteroxide, e.g. LiOD or KOD. The anode material can be Pt, Ni, or any other material ge- nerally used in electrolytic cells for water electrolysis.
The cell voltage can be between 2 and 12 V and the concentration of dissolved substances in the heavy water is about 0,1 M , but both higher and lower concentrations may work. The apparent den- sity can also in this case be increased by the addition of sus¬ pended magnetic particles of a chemical composition which does not react with the electrolyte.
By the continuous electrolysis the cathode 2 is always saturated with D 2 thereby increasing the probability of fusion reactions by incoming high energy deuterons generated by the high voltage discharge between the electrodes 2 and 3. In this embodiment of the electrode system a diaphragm 15 is inserted to collect and
lead away the generated D 2 through the pipe 16.
High voltage for the electrical discharge in the fluid is applied through the conduit 7 and low voltage for the electro- lysis is applied through the conduit 17 to the anode 13.
List of details:
1. Tank
2. Central electrode, cathode 3. Outer electrode for high voltage discharge
4. Electrolyte
5. Conduit
6. Valve
7. High voltage condμit 8. Steam conduit
9. Valve
10. Valve
11. Branch pipe
12. Magnetic field 13. Electrode
14. Low voltage conduit
15. Diaphragm.
16. Pipe for D 2
17. Low voltaσe conduit