DE2432802A1 - Electricity produced electrochemically from environmental heat - by decomposition and recombination cells with natural circulation - Google Patents

Abstract

The parent patent describes a method for converting heat into electrical energy, in which an aqueous electrolytic compound is electrochemically broken down in a decomposition cell at a decomposition voltage which at the reaction temperature is less than the recombination voltage and less than 1.23 volts, this decomposition giving rise to two substances, one of which is a gas; these two substances are conducted to a recombination cell and recombined to give an aqueous compound while generating direct current; this compound is recycled to the decomposition cell; the cooling process which occurs in the decomposition cell results in an inflow of surrounding heat from the environment. In the patent of addition, the recycling of the electrolyte from the recombination cell into the decomposition cell takes place automatically, as a consequence of a higher electrolyte surface level maintained in the decomposition cell than the level in the recombination cell; this difference is produced by the gas released in the decomposition.

Description

Process for converting heat into electrical energy additive to Patent (patent application P 1 # 96143.o-44) The invention relates to a method for converting thermal energy into electrical energy, in which in a cycle an aqueous electrolytic compound in a decomposer cell electrochemically is decomposed, its decomposition voltage at the reaction temperature below the Recombination voltage and below 1.23 volts, and the combination of two substances consists, one of which is a gas, the individual substances produced in a recombination cell be brought, in which they again under direct current delivery to an aqueous compound recombine, and the compound is returned to the decomposer cell, and the decomposition energy is supplied by the recombination cell during the cooling process occurring in the decomposition cell the inflow caused by environmental heat in the decomposer cell, according to patent (patent application P 1596143.0-41).

According to the main patent, a circulating device is used to circulate the electrolyte provided, their electrical power consumption when deriving the characteristic the arrangement with the amount J2 Ru is taken into account.

The method described in the main patent for circulating the electrolyte has the disadvantage that for a decomposer and a recombination cell existing cell pair a circulation device is to be provided.

The invention is based on the object of circulating the electrolyte to reduce the required expenditure of resources and energy to a minimum.

This object is achieved according to the invention in that the return of the electrolyte from the recombination cell into the decomposer cell automatically takes place that the gas released during the decomposition raises the electrolyte level of the decomposer cell above the electrolyte level of the recombination cell.

Appropriate further developments of the subject matter of the invention are the subclaims refer to.

The invention is illustrated below with reference to a nlmg in the drawing Illustrated embodiment explained in more detail.

The cell pair consists of a recombination cell 1 of a decomposer cell 2, a pipe 3 connecting the two cells, a perforated one, for example circular plate-shaped hydrogen electrode 4 of the decomposition cell 2, one for example circular plate-shaped hydrogen electrode 5 of the recombination cell 1, its attachment in the recombination cell 1 is not shown further, a halogen electrode 6 of the recombination cell 1, a halogen electrode 7 of the decomposition cell 2, a Pipeline 8, which hydraulically connects the recombination cell 1 with the decomposition cell 2 connects, with a shut-off device at the connection point to the decomposer cell 2 9 is provided. A lid 10 of the recombination cell 1 is on its inside 11 designed such that the incoming through the pipe 3 in the direction of the arrow Electrolyte is broken up into droplets, the diameter of which is against the electrode 5 directed edge of the inside 11 larger than the diameter of the circular plate-shaped Electrode 5 is. Furthermore, in the cover 10 is a plug 18 which can be closed in a gas-tight manner Port 12 and an inlet port 20 are provided through which the via the pipeline 3 incoming electrolyte to the inside 11 of the lid acting as a drip device 10 enters the recombination cell 1. At 13 is the level of des in the recombination cell 1 located electrolyte designated. A cover 14 of the decomposition cell 2 carries one with a plug 19 gas-tight closable filling opening 15 and an outlet opening 16 opening into the pipeline 3 in the decomposer cell 2 is designated by 17. The covers 10.14 are gas-tight the cells7,2 put on. The cell 2 has ribs arranged on its circumference 32 provided, which introduce environmental heat into cell 2.

A useful resistor 21 is connected on the one hand to the electrode via the line 22 5, on the other hand connected to a starter battery 24 via line 23. Of the Line 23 branches off another line 25 to electrode 4. There is also a switch 26 is provided, which connects the electrode 6 to the electrode 7 via the lines 27, 28 connects, the switch 26 being in position b. In position c des Switch 26, the electrode 7 is connected to the battery 24 via the lines 28,29, whereby a starting circuit for cell 2 is closed during the starting phase. If the switch 26 is in position a, the pair of cells is out of order set.

The mode of operation of the pair of cells is explained in more detail below. The operating status is shown in the drawing.

Before commissioning (switch 26 in position a) is used as an electrolyte highly concentrated, aqueous hydrogen halide through opening 15 into the decomposer cell 2 filled, but # at most until the mirror 17 denotes lower margin the outlet port 16 has reached. The pressure of the liquid on the backflow flap 9 causes them to close the pipeline 8. Then there is a dashed line shown, located below the underside of the gas electrode 5 on the pot 33 Filling opening 31 acting as an electrolyte, low concentration, aqueous hydrogen halide filled with halogen dissolved therein in the recombination cell 1 until the mirror 13, the horizontally arranged diffusion gas electrode 5 from below barely wetted. Finally, hydrogen is generated through the openings 12, 15 for so long blown from an external source until all air is displaced from the pair of cells. The gas-tight stoppers 18 and 19 are then inserted.

By moving the switch 26 to position c, the starting circuit closed. Hydrogen develops on the underside of the electrode 4 of the cell 2 in the form of bubbles, while 2 halogen is deposited on the electrode 7 of the cell. The hydrogen vesicles go away with both the electrolyte and the also of the deposited halogen through the perforation holes of the electrode 4 their top side and form with the electrode 4 and outlet opening between the top side 16 located electrolyte volume a physical mixture, the mean density only a fraction of the electrolyte in the recombination cell 1 (approx 3 # for bromine and about 5% for iodine). As a result of this density difference the level 17 of the cell 2 rises and causes the mixture to flow into it the outlet opening 16, and from there into the pipeline 3. As a result of the effect of the force of gravity segregation occurs again, with free access to the gaseous mixture to the top of the electrode 5 of the cell 1, while the liquid portion over the drip device 11 reaches the mirror 13. The drip device breaks up 11 the incoming electrolyte from the pipeline 3 into individual droplets, with which it is achieved that neither the gas-side surface of the electrode 5 is wetted, as well as an undesirable electrical shunt between the electrodes 4 and 5 is prevented.

The recombination cell 1 has its readable on a voltmeter 30 Nenns, -, o, annung reached, then the starting process is finished, and the switch 26 is brought into position b, which closes the operating circuit.

The hydrogen located above the electrode 5 combines below Direct current output with the halogen dissolved in the electrolyte. The one between the electrodes The electrical voltage present in 5 and 6 drives a direct current through the useful resistor 21 and through the cell 2, whereby the hydrogen evolution initiated during the starting process is continued. Since the pipeline 3 continuous electrolyte arrives in cell 1, the level 13 of the electrolyte in this cell rises the operating altitude shown in the drawing. This increases the hydrostatic Pressure above the electrode 6, which is sufficient to keep the backflow flap 9 permanently open to keep. The highly concentrated hydrogen halide that forms during recombination flows back through the pipeline 8 into the cell 2. Because of the electrical Series connection of cell 1 and cell 2 only as much hydrogen and halogen in the Cell 2 are generated as required in cell 1, there is no need for a dosage for hydrogen or halogen, when changing from nominal operation to standstill by By moving the switch 26 to position a, the operating circuit is interrupted, and the evolution of hydrogen comes to a standstill. By segregating the over the electrolyte located in the electrode 4, its level 17 sinks below the lower level Edge of the outlet opening 16. The pipe 3 empties and the flow in the Pipeline 8 also disappears. The different heights of the mirrors 13 and 17 cause the hydrostatic pressures over the two electrodes 6 and 7 are different. The pressure difference causes the backflow flap 99 the To close pipeline 8. This prevents the mirror heights from being balanced and total wetting of the gas electrode 5 from below avoided. When exiting the electrode 4, the hydrogen must have the hydrostatic pressure that the mixture exerts on the underside of the electrode 4. The for Overcoming this pressure required work is the electrical operating circuit taken and is expressed in an increase in the decomposition voltage Uz by one if the amount is below 10 mV / cell pair.

To start again, switch 26, as described above #, brought back to position c.

Claims

Claims (4)

Claims 1. A method for converting heat into electrical Energy at which an aqueous electrolytic compound in a circuit is electrochemically decomposed in a decomposition cell, with its decomposition voltage is below the recombination voltage and below 1.23 volts at the reaction temperature, and the compound consists of two substances, one of which is a gas, where the individual substances produced are brought into a recombination cell in which they recombine again with direct current delivery to an aqueous compound, and the Compound is returned to the decomposer cell, with the decomposition energy is supplied by the recombination cell and the one entering the decomposition cell The cooling process causes ambient heat to flow into the decomposer cell, after (Patent claims patent (patent application P 1 # 96143.o-4i), characterized in that the return of the electrolyte from the recombination cell (1) in the decomposition cell (2) takes place automatically in that this occurs during decomposition released gas the electrolyte level (17) of the decomposition cell (2) over the electrolyte level (13) of the recombination cell (1) raises. 2. Arrangement according to claim 1, characterized in that each cell cm, 2) is designed as a pot (33,34) with a lid (10,14) that connects the two cells are via a pipeline that can be closed by a shut-off device (9) on the decomposition side (8) for the highly iron-free, undecomposed electrolyte and another, dated Lid (14) of the decomposition cell (2) beginning above the electrolyte level (17), to the cover (10) of the recombination cell (1) leading pipeline (3) for gas and the low concentrated electrolytes including halogen that in both pots (33,34) Plate-shaped hydrogen electrodes (gas electrode 4, diffusion gas electrode 5) are arranged horizontally that the hydrogen electrode (4) of the decomposer cell (2) is perforated while the hydrogen electrode (5) of the recombination cell (1) is designed as a diffusion gas electrode that the diffusion gas electrode (5) over a halogen electrode (6) and the gas electrode (4) over a halogen electrode (7) while maintaining a minimum distance are arranged, and that in every operating state the electrolyte level (17) of the decomposer cell (2) over the only the underside of the electrode (5) reaching the electrolyte level (13) of the Recombination cell (1) lies. 3. Arrangement according to claim 2, characterized in that the inside of the lid (10) of the recombination cell (1) as a drip device (11) is designed for the incoming electrolyte from the pipe (3) that the gas-side surface. (1st electrode (5) of the recombination cell (1) from the outgoing Electrolyte droplets are not wetted 0 4. Arrangement according to claim 2 and 3, characterized characterized in that an electrical series connection of diffusion gas electrode (5), useful resistor (21) and gas electrode (4) is provided that the halogen electrodes (6,7) in nominal operation via a switch (26 b) electrically connected in series are, and that the halogen electrode (7) over the switch during the starting phase (26 c) is connected to one pole of a battery (24), while the other pole of this Battery is at the connection point of the useful resistor (21) and gas electrode (4). (Patent claims) L e r s e i t e