JPH06167585A - Heat generation device - Google Patents

Abstract

PURPOSE:To obtain high heat value, stability and repeatability by absorbing heavy hydrogen in hydrogen absorbing metal and striping charged particles against this metal surface. CONSTITUTION:A complex structure plate 3 contacts metal thin film such as molibdenum on the vacuum vessel 2 side surface of a hydrogen absorbing metal plate. Below this structure plate 3, an electrolysis vessel 1 with sealed structure having a positive electrode 4 of such a metal as platinum surrounded by iron ring 5, is provided, and an electrolyte solution of heavy water solving metal salt is filled. If electric potential is applied between the structure plate 3 and the positive electrode 4, the heavy water is electrolyzed and heavy hydrogen and oxygen are generated. Heavy hydrogen is continuously absorbed by the hydrogen absorbing metal of the structure plate 3 and excess heat due to Freishman-Ponds effect is generated. oxygen is adsorbed to the iron of the ring 5 to make oxidized iron. As the absorbed hydrogen hardly permeates into the vessel 2, a plenty of heavy hydrogen is stored in the hydrogen absorbing metal. On the other hand, high speed charged particles are emitted from a charged particle source 6 in the vessel 2 and colide the structure plate 2. And thus, the colision location becomes high temperature and generates excess heat again.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a heat generating device utilizing the so-called Fleishman-Ponds effect.

[0002]

2. Description of the Related Art Currently, there are the following methods (or devices) for generating heat (excess heat) that are expected to be related to cold fusion. One of them is the so-called Fleischmann-Ponds effect (M. Fleschmenn, S. Pons: Electroanal. Chem.
261,301 (1989) erratum 263,187 (1989)),
In this method, a platinum or nickel positive electrode and palladium (pal) are added to an electrolyte solution prepared by dissolving a metal salt in heavy water.
Ladium) or titanium negative electrode is inserted and 5 between both electrodes
By applying a voltage of about 30 volts and electrolyzing it,
The deuterium nuclei enter the inside of the palladium metal, the D-D fusion reaction between deuteriums occurs in the metal crystal, and excess heat is obtained. Whether or not cold fusion is actually occurring has not yet been concluded, but excess heat generation is a fact.

The other one is a method of heating a hydrogen-sucking alloy in which deuterium has been sucked by some method, such as palladium being sucked and confined by deuterium, in a vacuum (N
Announced by TT Basic Research Laboratories (Eiichi Yamaguchi): Hereinafter, this method is tentatively referred to as the Yamaguchi method.) Similarly, excessive heat is generated.

[0004]

Although neither the Fleishmann-Ponds effect nor the Yamaguchi method has been sufficiently confirmed as to whether cold fusion is occurring at present, excess heat is not generated. Exists as a fact.
However, the generation of heat due to the above-mentioned Fleischmann-Ponds effect is still only about 50% reproducible at present, and even if a heat generating device is used, even if the Fleischmann-Ponds effect occurs and heat is generated. However, most of the heavy water evaporates during operation, which is wasteful and inefficient. Further, when the Yamaguchi method is used as a heat generator, there is a problem that heat cannot be continuously generated.

The present invention has been made to solve the above problems, and an object of the present invention is to provide a heat generator having high efficiency and reproducibility and capable of continuously generating heat.

[0006]

A heat generator according to the present invention comprises a composite structure plate in which a thin metal film having a small diffusion coefficient for hydrogen and a high melting point is bonded to only one surface of a hydrogen-absorbing metal plate. By using an electrolysis vessel having a sealed surface and an oxygen adsorption structure with this surface as a cathode on the surface side of the base body of this composite structure plate, the charged particles accelerated on this surface collide with the surface side where the thin film is bonded. A vacuum container is provided, and heavy water is electrolyzed to absorb deuterium in the hydrogen-sucking metal, and charged particles collide with the surface on which the thin film is formed. In this case, oxygen generated in the closed electrolysis vessel is adsorbed by the oxygen adsorbing structure, so that continuation of electrolysis is not hindered, and one surface of the hydrogen-absorbing metal has a small diffusion coefficient for hydrogen and Since the metal thin film having a high melting point is joined, the amount of absorbed deuterium permeating into the vacuum container can be significantly reduced, and the amount of deuterium absorbed can be increased. Therefore, the excess heat of the Fleishman-Ponds effect between deuteriums due to the adsorption of deuterium on the hydrogen-sucking metal can be increased, and a high amount of heat, stability, and reproducibility can be obtained.

[0007]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS An embodiment of the present invention will be described below with reference to the drawings. FIG. 1 is a sectional view showing an embodiment of the present invention, in which 1 is an electrolysis vessel, 2 is a vacuum vessel, 3 is a composite structure plate, 4 is an anode provided in the electrolysis vessel 1, 5 Is an iron ring surrounding the anode 4, 6 is a charged particle source provided in the vacuum container 2, and 7 is an exhaust system of the vacuum container 2.

The composite structure plate 3 is a plate of hydrogen absorbing metal such as palladium or titanium, the surface on the side of the electrolysis vessel 3 is left as it is, and the surface on the side of the vacuum vessel 2 is a diffusion coefficient for hydrogen such as molybdenum. Is formed by joining (coating) metal thin films having a small melting point and a high melting point. And
On the lower side with the composite structure plate 3 sandwiched, the periphery thereof is surrounded by an iron ring 5, and an anode 4 of a metal electrode such as platinum or nickel is formed.
An electrolytic vessel 1 having a closed structure is provided, and the vessel is filled with an electrolyte solution in which a metal salt is dissolved in heavy water. Here, when a potential difference is applied between the composite metal plate 3 and the anode 4, the electrolysis of heavy water starts, deuterium and oxygen are generated in the container, and the generated deuterium forms the composite structure plate 3. The oxygen that is absorbed by the existing hydrogen-sucking metal is adsorbed by the iron that forms the iron ring 5 to form iron oxide. Therefore, even if the electrolysis vessel 1 is a closed vessel, electrolysis can be continuously performed, and deuterium can be continuously absorbed by the hydrogen suction metal. Then, due to the absorption of the deuterium, excess heat is generated in the same manner as the above-mentioned Fleischmann-Ponds effect.

The deuterium absorbed by the hydrogen sucking metal is coated with a thin film of molybdenum or tungsten having a small diffusion coefficient for hydrogen on the back surface of the composite structure plate 3 (on the side of the vacuum container 2). It becomes difficult for the hydrogen to permeate to 2, and this makes it possible to store a large amount of deuterium in the hydrogen suction metal.

On the other hand, in the vacuum container 2, high-speed charged particles are extracted by the charged particle source 6 and the charged particles collide with the composite structure plate 3, so that the collision point locally becomes hot in vacuum. In the same manner as the above Yamaguchi method, excessive heat is generated again. It is also possible to attach a scanning device in order to cause charged particles to efficiently collide with the composite structure plate 3.

[0011]

INDUSTRIAL APPLICABILITY As described above, the present invention is directed to a Freishmann-manufactured by adsorbing deuterium on a hydrogen-sucking metal.
It is possible to effectively generate excess heat due to the ponds effect, and obtain high heat quantity, stability and reproducibility. In addition, by utilizing both the adsorption and desorption of deuterium as in this device, it is possible to obtain a device that can prevent wasteful evaporation of deuterium as much as possible and that can continuously generate heat. effective.

[Brief description of drawings]

FIG. 1 is a sectional view showing an embodiment of the present invention.

[Explanation of symbols]

 1 Electrolysis vessel 2 Vacuum vessel 3 Composite structure plate 4 Anode 5 Iron ring 6 Charged particle source 7 Exhaust system

Claims (2)

[Claims] 1. A hermetically sealed structure using a plate of hydrogen-sucking metal such as palladium or titanium, the one side of the hydrogen-sucking metal plate being a cathode, and a metal electrode such as platinum or nickel being an anode. An electrolysis container is constituted, an oxygen adsorption structure is provided in this container, an electrolytic solution in which heavy water is dissolved is filled in this container, and a potential difference is given between the anode and the cathode to electrolyze the electrolytic solution to generate it. Means for absorbing deuterium in the hydrogen-sucking metal to generate excess heat due to the Fleishman-Ponds effect and adsorbing the generated oxygen to the oxygen-adsorbing structure, a vacuum on the other surface of the hydrogen-sucking metal plate. A container is formed, and accelerated charged particles are made to collide with this surface to locally raise the temperature of the hydrogen-sucking metal in which deuterium is absorbed by the electrolysis, and a deuterium-Fleishman of deuterium in the hydrogen-sucking metal. −
A heat generating device comprising means for generating a ponds effect and generating excess heat. 2. A desorption of deuterium is suppressed by bonding a thin film of a metal such as molybdenum having a small diffusion coefficient to hydrogen and a high melting point to only one surface of a plate of a hydrogen-absorbing metal such as palladium or titanium. Means for forming a composite structure plate, the surface of the base material of the composite structure plate as a cathode, a metal electrode of platinum, nickel or the like as an anode to constitute an electrolysis container of a closed structure, oxygen adsorption structure is provided in this container, This container is filled with an electrolytic solution in which heavy water is dissolved, and a potential difference is applied between the anode and the cathode to electrolyze the electrolytic solution, and the deuterium thus generated is absorbed by the hydrogen-sucking metal to produce a Fleishman-
A means for adsorbing the generated oxygen to the oxygen adsorbing structure as well as generating excess heat due to the Pons effect, a vacuum container is formed on the surface of the composite structure plate to which the thin film is bonded, and accelerated particles are made to collide with this surface. A means for locally raising the temperature of the hydrogen-scavenging metal in which deuterium has been absorbed by the electrolysis to a high temperature to cause a Freishmann-Ponds effect of deuterium in the hydrogen-suctioning metal to generate excess heat, A heat generator equipped.