DE2530326A1 - Galvanic cell with coated foil magazine - has bobbins with coating and carrier layers and electrolyte layer - Google Patents

Abstract

A galvanic cell has a storage compartment housing several supply rolls of coated foils. At least one of the foils (11-13) is coated with a material in the electrochemical series, e.g. zinc. These foils are guided through a working compartment (2) in close contact with each other by a belt and/or roller system (24). Two electrode layers (11, 13) separated by an electrolyte layer (12), consists of, e.g. zinc and carbon. A motor drives the foils (11-13) and a eception compartment receives the foils from the working compartment. Current collectors (32) are in contact with the two electrode layers.

Description

Device for generating electricity, such as Glavanisches Element The invention relates to a device for generating electrical power, such as galvanic element.

Galvanic elements are a @ wet elements and dry elements in use. As the primary element widespread at mers @ en is the zinc-carbon element, which is used e.g. for Flashlight batteries is used. Put coal and zinc in a suitable one Electrolytes, a voltage is created after the electrochemical series of voltages of 1.50 V. The zinc is decomposed in the process. About the drop in tension in a loaded galvanic To prevent an element, a substance, a so-called depolarizer, must be interposed that binds the resulting hydrogen.

The performance of a galvanic element depends on the size of the effective area between the electrodes.

The performance of conventional galvanic elements is limited.

The object of the invention is to provide a novel device of the initially to create described type, with which despite low weight and low A higher performance can be achieved.

This object is achieved according to the invention in that in a storage cell several supply rolls are rotatably mounted on which coated films are wound are, of which at least one with a material of the electrochemical series, e.g. zinc coated, the coated foils in a work cell in close contact with each other via a belt and / or roller system, wherein two electrode layers separated by an electrolyte layer, e.g. zinc and carbon are formed that a motorized drive device is provided for moving the films is that the work cell has a receiving cell for receiving the foils from the work cell is downstream and that current collector with both electrode layers are in electrical contact.

The invention is based on the knowledge that to increase the Power of a battery or an accumulator is the exchange area of the electrodes must be enlarged.

This can be achieved by two-dimensional arrangement of the electrodes forming layers. These layers then have to be thin to cover a large area to accommodate on a limited volume. As it is in the case of a primary element the less noble material of the electrochemical series is consumed, Continuous replacement must be provided when the battery is sufficient Should have capacity. This is now achieved according to the invention in that the electrodes are movably guided and driven. With this inventive concept it is possible to remove used material from the work cell and fresh, unused material To track material.

In the simplest case, according to an embodiment of the invention in the storage cell has three storage rolls on each of which is coated with film strips are wound up. On the first roll is a foil with a fine zinc coating for example 0.025 mm thick. The second roll consists of a perforated one Foil double-sided acidic with a suction cup / waterlal is coated. The third roller preferably also carries a perforated one Slide that on one side with a depolarizer and on the other is coated with carbon. As long as the three foils are wound on the supply roll no discharge occurs. The shelf life is therefore almost unlimited. Will the three film foils are now brought together in the work cell Junction formed a galvanic element, with between the two Electrode layers zinc and carbon a voltage difference of 1.5 V is generated. The current strength depends on the currently available effective electrode area Thanks to a band system in the work cell, this electrode area can be reduced to the smallest Space can be kept very large if that is composed of the above-mentioned layer foils and for the sake of simplicity hereinafter referred to as galvanic tape element is guided back and forth closely parallel to each other. In this way you can Contact areas even in a work cell the size of a cigar box of several 1,000 cm2. In the case of a simple zinc-carbon strip, this results with a surface load of 0.16 A / cm2 a current strength of several 100 A, which at 1.5 V leads to a power of at least 500 W.

If, for example, eight identical elements are used to achieve a 12th V-voltage connected mechanically in parallel and electrically in series, so results A battery pack of a small volume that is capable of generating a lot of power of 4 kW. Since the foils can be kept extremely thin, you can the supply rolls are kept for great lengths. As the speed of movement of the galvanic 3arldes is only small, the device according to the invention has a high capacity, completely new areas of application, not least the power supply developed by electrically powered motor vehicles.

The device according to the invention can be used both as a primary cell are replaced in such a way that the used part of the layer films is replaced at intervals but it can also be used as a rechargeable element, in particular as an accumulator can be used, having the same advantages, namely high performance with minimal Weight and small size can be achieved.

The speed of the galvanic belt depends on the current load away. In the case of a single-use Gaivan tape (primary cell), the Speed controlled so that the consumable material is exiting from the work cell is practically used up. In the adjoining reception cell can then the galvanic Tape back into the individual layer foils be split up, for example to reuse them later after processing to be able to.

Based on the drawing, which represents an embodiment, be the Invention described in more detail.

It shows: FIG. 1 a schematic longitudinal sectional view through the novel Device, Fig. 2 is a greatly enlarged sectional view through the multiple Galvanic tape consisting of laminated foils and FIG. 3 shows a perspective view of a battery pack according to the invention.

1 schematically shows a storage cell 1, a work cell 2 and a receiving cell 3. All three cells 1, 2 and 3 consist of thin-walled Housings that can be separated from one another in the exemplary embodiment and by means of push-button-like Fasteners can be connected to each other.

Cells 1 and 3 are identical and can be interchanged will.

The supply roll 1 has three supply rolls in an overarching arrangement 5, 6, 7. The receiving cell 3 has three Qu-, Nahlnerollen 8, 9, 10. On the supply roll 5, a layer film 11 is wound up, which consists of a thin carrier film 14 with a fine zinc coating 15 (Fig. 2). The roller 6 carries an electrolyte layer film 12, which consists of a perforated carrier film 16, which is covered on both sides with absorbent, acidic material layers 17 and 18 is provided. Finally, the role 7 carries an electrode layer film 13 which has a perforated carrier film 19, which on its upper side, which faces the foils 11, 12, has a depolarization layer 20 and has a carbon layer 21 on the exposed underside.

The three layer foils 11, 12, 13 are lifted in the storage cell 1 a common exit roller 22 out. This is where the three layer foils come into play 11, 12, 13 together and form a galvanic element band 23.

The galvanic tape 23 is through a slot in the work cell 2 introduced. The work cell has a multitude of endless pulleys, each around two pulleys guided around guide and pressure belts 24, which are arranged so that two Tape sections of adjacent tapes 24 run parallel at a distance that is approximately the thickness of the galvanic tape 23 is equivalent to. The lower. Pulleys The guide and pressure belts 24 are each provided with a gear 25.

All gears 25 mesh with one another. The gear 25a sits on a drive shaft 26, which comes out of the housing at both ends the work cell 2 is exposed and carries couplings, not shown, by means of which they are connected to the drive shafts 26 of working cells arranged in parallel (FIG. 3) it. On an outer cell of the cell packet 27 shown in FIG. 3 is a drive motor 28 attached, which all coaxially arranged drive shafts 26 of the individual work cells 2 of the package 27 drives. Each drive shaft 26 in turn, drives each of the plurality of guide belts 24 so that all of the belts are driven at the same speed.

Is the front end of a galvanic tape 23 in the insertion slot The work cell 2 is introduced, so the galvanic tape 23 is threaded after starting of the motor 28 automatically thanks to the help of stationary deflection guides 29 in the tape guide system and exits the work cell at 30 after having gone through the entire tape guiding system 2 off.

There is a pantograph at the entrance to work @ cell 2 31, which is in electrical connection with the zinc electron and the negative pole represent. At the outlet of the cell 2 is the other current collector 32, the is in conductive connection with the carbon electrode. This pantograph represents the positive contact.

If the carrier film for the layer film 11 is a non-conductive plastic film is used, the current collector must be on the underside of this layer foil, so lie directly on the zinc coating, which is achieved in the exemplary embodiment can be that the current collector before the merging of the individual film sheets 11, 12, 13 is still arranged within the storage cell 1.

The galvanic band 23 emerging from the work cell 2 then occurs into the laterally releasably attached housing of the receiving cell 3, is then in the three layer foils 11, 12, 13 aufgespa th, each of these layer foils is wound onto one of the three take-up rollers 8, 9, 10.

In order to save a separate drive for the take-up rollers, the Rear wall 33 of the work cell 2 arranged three friction rollers 34 which are rotatable on the housing are stored and are in frictional engagement with the rearmost deflecting belt 24.

Counter-pressure rollers 35 ensure the Relbantrieb. With the distribution rollers 34 each has an end plate 36 connected to the transmission, which when pressed Housing 3 through slots 37 in the front wall of the housing with the coils of the Rolls 8, 9 and 10 is in frictional engagement. The gear ratio between the Rollers 34, 36 is then chosen so that the take-up rollers 8, 9, 10 are fast enough are rotated so that the laminated tapes 11, 12, 13 are wound up tightly.

As the winding diameter increases, the friction gears occur a corresponding slip.

The illustrated embodiment according to FIG. 1 results for an element of 25 cm length consisting of the three cells 1, 2 and 3, 15 cm in height and approx. 10 cm in width, as shown in the drawing itself. The active contact surface of the galvanic tape 23 in the work cell 2 is approx. 1,800 cm². If one calculates with a low surface load of 0.16 A / cm², this results in a current yield of 290 A. If a fine zinc coating is used of about 0.025 mm, this is consumed after the specified current load approx. 18 minutes.

This results in a necessary belt speed of 10 cm / minute. Although because of the very small required thickness of the individual layer tapes 11, 12, 13 a substantial Larger supply housed in cells 1, 3 can only be expected with a storage length of 24 m.

This results in a continuous running time of the device of 4 hours.

The capacity of the element is wide with the data described over 1,000 Ah.

If, as shown in Fig. 3, for example, eight cells are mechanically attached to one another and connected the cells electrically one behind the other, as indicated by the diagonal current conductors 38 in FIG Fig. 3 is illustrated, then results from the cell packet 27 shown at the two terminals 39, 40 a voltage of 12 V and a continuous output of 3.5 kW.

The above data are based on the illustrated embodiment and on the basis of the most unfavorable dates. In practice, the role system more closely trained. The galvanic tape 23 is only a fraction of that in the drawing shown thickness. The housing dimensions are therefore much smaller. Of the The supply that can be wound up on the rolls is a multiple of the specified size. The power output and the capacity are therefore significantly higher than the above Sizes given for illustration purposes only.

In the foregoing, the invention is based on a simple zinc-carbon element has been explained. Various modifications are possible within the scope of the invention. In this way, the laminated film 13 does not need to be unwound from a supply roll and then taken up a supply roll to be wound up because the carbon layer has not been spent. This layer film 13 can circulate as an endless belt in the work cell 2. Also lies It is within the scope of the invention, the guide and pressure belts 24 as electrode belts to equip with the layer film 13, which is possible, since yes between the bands 24 and the galvanic tape 23 there is no relative speed.

It goes without saying that any other pairing of materials is still possible possible for the galvanic element.

The entire arrangement can also be designed as a rechargeable device be. In the simplest case, this could be achieved by using the drive motor 28 is reversed after the supply rolls 5, 6, 7 have been used up.

Finally, the principle described can also be used for accumulators used; will.

In all cases this is compared to conventional, unloadable Stroni storage elements thanks to the moving electrodes the advantage achieved that on a considerably smaller Space and with incomparably lower weight, a greater power output is possible is.

Claims (11)

Patenten @ rüche 1. Device for generating electricity, such as galvanic element, d u r c h e k e n n -z e i c h n e t that in a storage cell (1) several storage rollers (5, 6, 7) are rotatably mounted on which coated foils (11, 12, 13) are wound, of which at least one coated with a material from the electrochemical series, e.g. zinc is that the coated foils are in close contact with one another in a work cell (2) are guided over a belt and / or roller system (24), two, of one Electrolyte layer (12) separate electrode layers (11, 13), e.g. Zinc and coal, are formed that a motorized drive device (28) for moving the foils (11, 12, 13) is provided that the work cell (2) a receiving cell (3) for receiving the foils from the working cell is connected downstream is and that current collector (31, 32) with both electrode layers in electrical Be in contact. 2. A @ ichtung according to claim 1, characterized in that in the Work cell (2) a motor-driven belt system (24) is provided which consists of a number of parallel, endlessly revolving belts, between each of which the closely spaced layer films (1 2, 13) as galvanic Band (23) are performed. 3. Device according to Anspnzll 1 or 2, characterized in that the receiving cell (3) receiving rollers (8, 9, 10) for the film foils (11, 12, 13) having. 4. Device according to one of claims 1 - 3, characterized in that that the storage cell (1) and the Aufnahanezelle (3) are identical. 5. Device according to one of claims 1 - 4, characterized in that that the storage cell (1) and / or receiving cell (3) can be removed from the work cell (2) and are arranged interchangeably. 6. Device according to one of claims 1 - 5, characterized in that that the guiding and pressing system (24) in the work cell (2) has a drive shaft (26), with which the pulleys of the guide belts (24) are geared are coupled. 7. Device according to claim 6, characterized in that the drive shaft (26) Frontal couplings for connecting additional coaxial drive shafts (26) having adjacently arranged work cells (2) of a cell packet (27). 8. Device according to one of claims 1 - 7, characterized in that that the rollers (5, 6, 7) of the storage cell (1) and / or the receiving cell (3) are geared are coupled to the drive shaft (26) of the work cell (2). 9. Device according to one of claims 1 - 8, characterized in that that the guiding and pressing system (24) in the work cell (2) in opposite directions Directions is drivable. 10. Device according to one of claims 1 - 9, characterized in that that at least one layer film, in particular the nobler material of the electrochemical The film (13) supporting the tensioning line of the galvanic element as a continuous film in the work cell (2) is arranged circumferentially. 11. Device according to one of claims 1 - 10, characterized in that that it is designed as a rechargeable primary element or as an accumulator.