DE3736576A1 - PLASTIC ELECTRODE - Google Patents

Abstract

Known plastic electrodes, in particular those used in the drying of walls, have the drawback that they are practically ineffective after a very brief transition period. To obtain a conductive plastic electrode which has the same voltage potential over its entire surface, even when large, and which gives trouble-free performance for long periods, the electric line (3) having a lower resistance than that of the conductive plastics material of the plastic electrode (7) is conductively connected to the material of the plastic electrode (7) through a resistance connection (5). The resistance of the resistance connection is greater than that of the electric line (3) and that of the plastics material. The plastic electrode is particularly useful in the drying of walls.

Description

The invention relates to a plastic electrode according to the upper Concept of claim 1.

Plastic electrodes made of conductive plastic are from the bottom sentence known. A known plastic electrode exists thereby from a flexible network, which for example inside as metallic mesh-like threads comprises that of one in the middle of the band-shaped electrode in the longitudinal direction current supply line with voltage ver be worried.  

This metallic basic net can be immersed in a plastic bathroom with a thermoset, which is made of there is electrically conductive plastic. The thread-like Carrier materials can, with the exception of the power supply line, in the central longitudinal direction of the band-shaped elec trode also consist of carbon threads, which like the Metal threads are preferably silver-plated.

But it has now been shown that this or also known plastic electrodes a variety of after share. On the one hand, there is the problem that if a conductive plastic with metallic power supply is contacted, this leads to undesirable reactions at the current transitions between metal and plastic results in what ultimately leads to electrode destruction that can.

Everyone poses a far more serious problem dings the generation of homogeneous electric fields, especially al lem with large-area electrolysis electrodes. Furthermore problematic is the transmission of electricity to the processing electrolyte, for example in conc trier form can be present in aqueous solution.

One could in the case of the Tech nik think that through the reticulated electrode structure a largely uniform current transfer on the whole th area of the mesh electrode with a uniform overall electrical fields and potentials should be possible. In practice, however, it has now been shown that this cannot be maintained, especially during extended operation.  

Through the most diverse reactions between plastic electrodes and electrolytes like inside between the conductive, especially metallic and silver-plated power supply boxes beln and the plastic itself there are so many reactions on what ultimately leads to a constant increase in opposition values and to a completely uneven tension distribution and uneven current density values.

This creates excessive current in the area of the center conductor seal until this leads to complete failure while the external electrode surfaces because of the prevailing there the higher resistances did no work. Ver Similar processes arise with flat films electrodes with selective power supply.

The object of the present invention is therefore that Avoid disadvantages according to the prior art and a To create conductive plastic electrode that even with large surfaces dimensioning over their entire area largely has the same voltage potential, and one largely uniform current over the entire area density or intensity compared to an electrolyte can be maintained.

The task is inventively according to the characterizing part of claim 1 specified note paint solved. Advantageous embodiments of the invention are specified in the subclaims.

In the plastic electrode according to the invention State of the art taken a completely different path.  While in the prior art the electrical lines anyway much more conductive in the plastic electrode are the plastic material of the electrode itself and above in addition, for example, power and voltage supply lines in addition, according to the state of the art, silver can be used in the present invention completely reversed path. According to the invention thereafter provided that the at least one electrical Lei device for the plastic electrode with this not directly and is in direct contact, but via interposed resistance. The resistance value should be larger as that of the electrical line as well as that Resistance value of the electrically conductive plastic material the plastic electrode. The higher resistance value of the zwi Switched resistors thus act as insulation protection for the electrical lines. The resistance of the electri The plastic electrode acts against the electrical one Supply line as a "receiving water" and distributes the electricity optimal on the entire surface.

Especially when using the plastic electrode for the Osmotic drainage of masonry is for the Wi the electrical plastic electrode is a resistor value, which is preferably about 0.5-1 kΩ / m, um the transition resistance to masonry and mortar is low to keep.

Although, of course, in a band-shaped one, for example Plastic electrode parallel the electrical connection line managed and in regular or irregular intervals the connecting cables between the electrical supply line and the plastic electrode can be provided into which the resistors mentioned are built, so in a preferred embodiment, the electrical line  Integrated in the plastic electrode but provided that the electrical line with at least comparatively low resistance with an equivalent surrounded sheathed conductor with which it is in the electrical Contact is there. The surrounding sheath conductor has a significant increase resistance value greater than the resistance value of the conductive plastic and the electrical conductor itself.

It is also possible that the sheath conductor as a resistance ver binding to the electrical line and the electrical Plastic electrode material in discrete sections on the electrical feed line is formed, and that the ver permanent sheathing areas of the electrical conductor are provided with an insulating layer.

Thanks to the sheathed conductor with considerably greater resistance worth as the resistance value of the conductive plastic electro den-Materials ensures that the electrode in the loading empire of the sheath conductor works little and is active, so that the actual electrical arranged in the sheath conductor Line is not overloaded.

Although an electri provided in the central longitudinal region sufficient power and voltage supply different variants can be implemented, in which, for example, in the case of a band-shaped electrode each with the outer sheathed with a sheathed conductor cal supply line is arranged. But also zigzag shaped in the electrode or even double zigzag formed electrical supply lines are possible.

The cross-sectional thickness can be designed differently, without one especially in the field of electrical wiring provide sufficient wire cross-section. Furthermore  can the electrical conductor instead of a thread-like Cross-section can also be designed in the form of a band.

Profiling, in particular, has proven to be advantageous for example in cross section in the manner of a zigzag arrangement, whereby the overall surface can be enlarged.

The plastic electrode according to the invention is particularly suitable easily using extrusion and / or calendering capable thermoplastic. With this band-shaped structure can improve the immediate electrodes surface and for better connection and attachment to the wall large recesses and punchings in the Be introduced plastic electrode.

Although as an electrical conductor for current and voltage supply and the plastic electrode a metallic Lei ter can be used, an electri carbon or coal ladder. Because the ge wrestling resistance, like metal, causes reactions on the electrode, which leads to a quick passivation ren. The contact resistance becomes infinitely large, so that the electrode can then no longer work.

All materials that come into consideration as sheath conductors in which the resistance is greater than that of the elek tric supply manager, but also the manager Plastic electrode material. In a preferred embodiment In principle, the envelope manager consists of the same plastic material as the conductive plastic material the plastic electrode, but with the difference that in  immediate border area to the voltage and power supply line the density of the material, and / or the Mi proportions changed or but additional admixtures added or omitted to clearly show the resistance value heights.

Further advantages, details and features of the invention follow from the drawings illustrated embodiments. Show in detail nen

Figure 1 is a schematic partial plan view of a band-shaped plastic electrode.

Fig. 2 is a schematic partial top view of a band-shaped plastic electrode with integrated electrical supply line;

Fig. 3 is a schematic excerpt Cross-sectional position through the embodiment of FIG. 2;

Figure 4 is an alternative embodiment in plan view.

Fig. 5-7 three further exemplary embodiments in schematic plan view.

In Fig. 1 a first embodiment of a conducting plastic electrode is shown. It is a band-shaped plastic electrode, for example with a width of 15 to 30 cm. To save material, a large number of punched-outs 1 are made in the plastic electrode, which, in deviation from the circular through openings, can also have any other shapes. These punching conditions 1 offer advantages especially when using the plastic electrode for drying masonry, since the electrodes can then be held on the masonry when the plaster is applied. In other applications, such a punching can be dispensed with, so that a full-surface plastic electrode is used.

The plastic electrode consists of a suitable lead the plastic material. One of the current and voltage supply serving electric line 3 is in the example shown Ausfüh example of the plastic electrode separately ausgebil det. At regular intervals, resistors 5 in connecting lines 6 connect the electrical line 3 to the conduct the material of the plastic electrode, which is provided with the reference numeral 7 .

A material with a low resistance is generally used for the electric line 3 in order to have only a slight drop in performance here. Non-metallic conductors are preferably used, for example consisting of carbon or coal or from the use of these materials.

The possible materials for the electrical plastic electrode 7 generally have a higher resistance value than the electrical line 3 . The resistors 5 , via which the plastic electrode are electrically connected to the electric line 3 , are selected so that their resistance is significantly greater than the resistance value of the electric line 3 and also greater than the resistance value of the plastic material of the plastic electrode 7th As a result, the plastic electrode acts against the resistors 5 and thus against the electric line 3 as a receiving water, so that the current and voltage are optimally distributed over the entire surface of the plastic electrode 7 . The resistance value of the plastic material of the plastic electrode 7 can have values of preferably 0.5 kΩ / m to 1 kΩ / m.

In the following, reference is made to FIGS. 2 and 3, which show a preferred exemplary embodiment. From this embodiment, the power and voltage supply electrical line 3 is integrated in the plastic electrode 7 arranged in the central longitudinal region. As can be seen in particular from the cross-sectional view according to FIG. 3 (the cross-sectional view is shown with the omission of the punched-out tongues 1 ), here the electric line 3 is surrounded with a sheathed conductor which corresponds to the functions of the resistors 5 . In other words, despite the integrated arrangement, the electrical line 3 is only connected to the actual material of the plastic electrode 7 via the sheathed conductor representing the resistor 5 . Since the resistance value of the sheathed conductor 5 is also clearly above the resistance value of the plastic electrode 7 or the electric line 3 , the preferred and surprising properties of the plastic electrode are achieved. In order to ensure a sufficient cross-section for the electric line 3 , this can, as shown in the exemplary embodiment, not only have a thread-like but also a band-shaped cross-section.

In order to achieve the largest possible surface, the plastic electrode 7 can also be profiled. In the exemplary embodiment shown, it is formed in a zigzag shape in cross section, which increases the surface area by 41% compared to a flat band-shaped electrode with the same external dimensions. This increase in the current transfer area has a positive effect when the electrode is used. In addition to the punched 1 , the adhesion of such an electrode is also improved by this profiling, in particular when used for drying masonry, since the mortar 9 can attack the electrode better and maintains the adhesion speed even in the event of temperature fluctuations. For this purpose, the reefs 11 is preferably introduced in the longitudinal direction of the electrode.

As can also be seen from the example, the plastic electrode, in particular in the region of the electric line 3, can also be formed with a different thickness from the other thickness. For example, the thickness of the plastic electrode can have 0.05 to 2 mm, preferably 1 mm, for example. In the area of the power supply line 3 , the thickness can easily be 2 to 5 times the otherwise customary thickness, for example 3 to 4 mm.

Due to the different thickness selection, the resistance and thus a desired potential profile can also be generated in certain areas. For example, the thickness at the distance from the electric line 3 could increase slightly.

Plastic material is preferably used as the material for the plastic electrode, which is capable of extrusion and / or calendering. In this case, the electrical line 3 can be processed together with the thermoplastic material to the plastic electrode in an extrusion process. The desired cross-sectional shape in the plastic electrode can also be produced by calendering.

The exemplary embodiments according to FIGS. 4 to 7 are only intended to show schematically that several electrical lines 3 with the corresponding sheathed conductors 5 which represent the increased resistance value can also be provided. In addition, the electrical lines 3 can also be laid deviating from a straight line with the resistance sheathed conductor that gives them.

In the exemplary embodiment according to FIG. 5, the two power supply lines 3 are arranged next to one another in a zigzag shape. In one case or another, this can lead to improved results.

In the exemplary embodiment according to FIG. 6, the two electrical lines 3 are arranged so as to cross each other. Likewise, further cross-shaped or net-like overlapping electrical lines 3 can be provided in the plastic mass.

In the exemplary embodiment according to FIG. 7, the plurality of electrical lines 3 extending across the longitudinal direction of the band-shaped electrode are formed in the interior of the plastic material, which in this exemplary embodiment are each firmly connected to the electrical line 3 running in the longitudinal direction on the outer edge. However, an electrical line 3 running in the longitudinal direction as the main line is sufficient. Of course, all electrical lines 3 are coated with the above-mentioned sheath line 5 having the higher resistance value. The sheathed conductors 5 with higher resistance are not shown in FIGS . 5 to 7.

Although metallic conductors are also fundamentally or at least theoretically possible for the electrical conductor 3, electrical conductors 3 made of non-metallic materials are generally preferred to avoid passivation effects. For example, conductors made from carbon or coal are suitable.

Different conductive materials can be used as the plastic material. They should preferably be capable of extrusion and / or calendering. In practice, a plastic electrode material has proven to be favorable, which consists of two components A and B , where A is a thermoplastic macromolecular material, and B either a mixture of

• a) a non-mediating electrical conductivity metallic fabric and
• b) an additive by oxidation or reduction can build stable electrochemical potential,

or a non-metallic substance that is conductive ability and ability to build an electrochemical bottom tentials is available at the same time. As far as the Disclosure content of patent application P 36 10 380 in referred to in full.

The resistors or, in particular, the sheath conductor 5 surrounding the actual electrical line 3 can also consist of materials which have the desired higher resistance value. However, a material or a group of materials which are formed from a non-metallic or predominantly non-metallic composition is preferred. A plastic material is possible, which is identical in principle and in its basic structure to the material of the actual conductive plastic electrode, but in which the density, the thickness and / or the mixing ratio and / or the mixing are changed so that the resistance values change significantly increase the plastic electrode of the plastic electrode 7 .

Claims (19)

1. Plastic electrode, consisting of conductive plastic with an electrical line for power and voltage supply, characterized in that the electrical line ( 3 ) with compared to the conductive plastic material of the plastic electrode ( 7 ) lower resistance value with the interposition of a resistance connection ( 5 ) with the Material of the plastic electrode ( 7 ) is conductively connected, the resistance of the resistance connection being greater than the resistance of the electrical line ( 3 ) and also greater than the resistance of the plastic material of the plastic electrode ( 7 ). 2. Plastic electrode according to claim 1, characterized in that the electric line ( 3 ) from the actual plastic electrode ( 7 ) is guided separately, the resistance connection between the electric line ( 3 ) and the plastic material of the plastic electrode ( 7 ) from several spaced, resistance-containing connecting lines ( 6 ), which branch off from the electric line ( 3 ) and lead to the material of the plastic electrode ( 7 ). 3. Plastic electrode according to claim 1, characterized in that the at least one electrical line ( 3 ) is arranged integrated in the plastic electrode ( 7 ) and is surrounded by a sheathed conductor forming the resistance connection ( 5 ) with which it is in electrical contact, whereby the sleeve is surrounded by the plastic material of the plastic electrode ( 7 ) at least in a partial circumferential area. 4. Plastic electrode according to claim 1 or 3, characterized in that the resistance connection between the electric line ( 3 ) and the material of the Kunststoffelek electrode ( 7 ) producing sheathed conductor as a resistance connection ( 5 ) on the electric line ( 3 ) at discrete intervals and that the electrical conductor ( 3 ) is insulated in the remaining peripheral area from the plastic material of the plastic electrode ( 7 ). 5. Plastic electrode according to one of claims 1 to 4, characterized in that the electrical line ( 3 ) has a band-shaped structure. 6. Plastic electrode according to one of claims 1 to 5, characterized in that the material thickness of the plastic electrode (7) in cross-section to the electric line (3) and is different from the longitudinal extension of the plastic electrode (7). 7. Plastic electrode according to one of claims 1 to 6, characterized in that the thickness or height of the plastic electrode at least in the region of the electric line ( 3 ) is greater than in other areas of the plastic electrode ( 7 ). 8. Plastic electrode according to one of claims 1 to 7, characterized in that the plastic electrode ( 7 ) is profiled in its thickness. 9. Plastic electrode according to one of claims 1 to 8, characterized in that the plastic electrode for Erzie treatment of a surface and thus current transfer surface enlargement is provided with grooves ( 11 ). 10. Plastic electrode according to claim 9, characterized in that the corrugations ( 11 ) are aligned in the longitudinal direction of the electrode. 11. Plastic electrode according to one of claims 1 to 10, characterized in that the plastic electrode a has band-like or foil-like shape. 12. Plastic electrode according to claim 11, characterized in that a plurality of recesses ( 1 ) are introduced in it. 13. Plastic electrode according to one of claims 1 to 12, characterized in that one or more Elektrolei lines ( 3 ) in the longitudinal, transverse and / or in the diagonal direction or crosswise, meandering or undulating in the material of the plastic electrode are provided, the Electric line ( 3 ) is surrounded with a higher resistance pointing resistance connection ( 5 ) in the manner of a sheathed conductor. 14. Plastic electrode according to one of claims 1 to 13, characterized in that the resistance of the preferably formed in the form of the sheath conductor Wi resistance connection ( 5 ) is greater than or equal to at least 1 kΩ / m, preferably 2 kΩ / m. 15. Plastic electrode according to one of claims 1 to 14, characterized in that the resistance of the electrical conduit ( 3 ) is less than 0.3 to 0.5 Ω m. 16. plastic electrode after a; of claims 1 to 15, characterized in that the resistance of the plastic material of the plastic electrode ( 7 ) is approximately 0.5 to 1 kΩ / m. 17. Plastic electrode according to one of claims 1 to 16, characterized in that carbon or carbon threads are provided as the electrical conductor in the interior of the sheath conductor producing the resistance connection ( 5 ). 18. Plastic electrode according to one of claims 1 to 17, characterized in that the difference in the resistances between the resistance connection (sheath conductor 5 ) to the lei tend plastic material of the electrode 0.5 to 1.5 kΩ / m, preferably 0.8 to 1, 2 kΩ / m, about 1 kΩ / m. 19. Plastic electrode according to one of claims 1 to 18, characterized in that the material of the sheath conductor for the resistance connection ( 5 ) essentially corresponds to the plastic material of the plastic electrode ( 7 ), but different from it by a different density, thickness Mixing ratio and / or different admixtures differs in such a way that the sheath conductor has a higher resistance value than the plastic material of the plastic electrode ( 7 ).