FR2565035A1 - High-efficiency electrochemical generator - Google Patents

Abstract

The subject of the invention is a high-efficiency electrochemical generator. The generator is made by combining assemblies of anode and cathode plates together with interposition of magnetic metals immersed in electrolytic fluids together with the positioning of the elements with a spacing 10, 11 sufficient for the passage of the regenerating surfaces. The leaktight trays 9 form stackable or juxtaposable connectable units with circulation of fluid 14, 15 and conductors 12, 13. It is intended to provide a steady state by disintegration of ionic electron ores together with elimination of chemical polarisations.

Description

 The object of the invention relates to a high efficiency electrochemical generator.

 It is intended to provide a continuous regime by disintegration of ionic electron ores with suppression of chemical polarizations.

 It is known to bring different metals into contact in an electrolytic reaction, in order to produce a potential difference allowing the extraction of the electrons of the two metals. Various electrodes made of different metals such as copper and zinc were used for this purpose, which were immersed in an acid solution serving as an electrolyte.

 These devices, which have not varied since the beginning, were of low efficiency, of short operating time, used expensive agents, polluted the environment by acid fumes. In addition, these battery cells could not be used to produce energy as the current power stations distribute them.

 The object of the invention eliminates these drawbacks and makes it possible to create an electrical energy produced by disintegration of the ores in electrolytic reaction in the raw, solid, liquid or compound states starting from product at low cost.

 The generator is constituted by the combination of the assemblies of the anode and cathode plates with the interposition of magnetic metals immersed in electrolytic fluids with the positioning of the elements in sufficient spacing for the passage of the regenerative surfaces. The watertight tanks forming connectable units that can be juxtaposed or stacked.

In the accompanying drawings, given by way of nonlimiting example, of one of the embodiments of the subject of the invention
Figure 1 shows a perspective view of the assembly of anode and cathode elements with the interposition of conductive supports and a magnetic plate between the elements.

 Figures 2 and 3 show on different scales seen in elevation and in cross section 1 battery cell assembly in the electrolytic tanks.

 Figures 4, 5 show the mobile regenerator the anode and cathode faces.

 Figures 6, 7 show alternative embodiments concerning the horizontal positioning of the trays and stacks.

 The elements consist of a stack of conductive supports 2, magnetic metals 3, conductive supports 4, and negative agglomerates 5.

 These agents form elements 6, 7 which are immersed with appropriate spacings 8 in an electolytic bath (Fig 1).

The assembly of the positive electrolytic anode plates 1 and the negative cathodes 5 of magnetic metal and mineral agglomerates 2, 3, 4 allows the connection between the elements of self-inductive plates causing the acceleration of the kinetics of the ions-electrons- volts produced by the reaction phenomena, which ensures maximum, continuous and regular efficiency. f
The elements (Fig 2) are placed in a sealed housing 9 and positioned by spaced supports 10, 11 and connected in series at their ends by conductors 12, 13.

 Electrolytic liquids cover all sides of elements 6, 7 and others.

 The elements rest on low slides guiding the mobile regenerative surfaces 16, 17 and others, at the same time as they position the elements by stabilizing them at the desired spaces.

Adducting and evacuating pipes 15 ensure thermal circulation of the electrolyte and waste evacuation
The positioning bases form slides at the same time for the movement of the regenerating plates 16, 17 and the intervals ensure the flow of the fluids and waste evacuated through the pipe 15.

 A regenerator is formed by a series of plunging tubular elements 16, 17 formed by permeable sheaths comprising an axial partition separating the positive and negative solutions which they spread over the copper 1 and zinc 5 plates.

 The spreading is done by moving along the container 9, the carrier plate 18 and this, from one end to the other.

 Layers of tenths of a millimeter of compound minerals are spread for the anodes and other compositions for the cathodes.

 You can juxtapose the tanks 9, 19 and others in a sequence varying with the powers that one wishes to obtain.

 This sequence can be vertical (Fig 2) or horizontal (Fig 6, 7) representing on different scales the vertical positioning of the tanks 20, 21 and the horizontal stacking of the batteries 22. Thus, with reduced dimensions, all the surfaces d available.

 Generators are thus obtained without combustion, without emanation, without dispersion and without noise, which eliminates pollution, harmful fallout with no contamination or vibration.

 Electric production is continuous by autonomous source with operation in all atmospheric conditions.

 The recharging of electrodes is carried out by an integrated system ensuring the regeneration supply of the component materials.

 Finally, it is possible to recover at the base 13 the deposits of materials created by the disintegration by the drains 15.

 With this device, the sulfurizations and oxidation of the electrodes and the connections which until today caused the generator to stop are eliminated.

 It is possible to control and timer by computers ~ or electronic sets of self-management or remote management, all continuous operating phases.

 The lightness and the low thickness of the elements 6, 7 allow multiple uses by application of light autonomous batteries for all industrial or even domestic applications.

 The electrodes in liquid or pasty electrolytic reaction presented, are only a medium version. They can be constructed from the bulk of a film with auto-thermal dimensions.

 New conceptions in the regeneration of various components and of magnetic or electromagnetic accelerations of ion-electrons-volts with self-inductive energy amperometric inserted from a self recovering exploitable energy.

 This is why the shapes, dimensions and arrangements of the various elements as well as the materials used for their manufacture, may vary within the limit of equivalents, without changing the general conception of the invention which has just been described.

Claims (3)

 10 Device of electrochemical generator with high output and in operation in continuous mode by disintegration of ores with ionic electrons in electrolytic reaction with suppression of chemical polarizations, electrodes and evacuation of waste by thermal circulation, characterized by the fact that the elements are constituted by a stack of conductive supports (2) of magnetic metals (3) of conductive supports (4) and negative agglomerates (5) forming the elements (6, 7) immersed in electrolytic baths.  20 Device according to claim 1 characterized in that the assembly of positive electrolytic anodes (1) and negative cathodes (5) placed in a sealed housing (9) and positioned by spaced supports (10, 11) and connected in series at their ends by conductors (12, 13) being specified that these elements rest on low slides guiding the mobile regenerative surfaces (16, 17) with interval of flow of fluids and waste (15).  30 Device according to Claim 1, characterized in that the adducting (14) and evacuating (15) pipes ensure the thermal circulation of the electrolyte and the evacuation of waste.