EP0100845A2 - Reinforcing or supporting element for building material, in particular an electrode - Google Patents

Abstract

Reinforcing or carrier elements for plaster are used as electrodes in electro-osmotic dehumidification installations. The elements comprise a carrier body constituted by a flexible net having a surface of synthetic resin in contact with the plaster and the net has filamentary carrier materials incorporated therein. The synthetic resin is a conductive, essentially ion-free thermosetting resin of macromolecular structure, preferably an at least partially cross-linked acrylate polymer having a high surface roughness and containing a small amount of a plasticizer, and forms either the matrix or a coating of the flexible net. The filamentary carrier materials may be carbon or metal filaments. In the use of the dehumidification installation, a voltage alternating between a positive and a negative potential is conducted between the cathode and the anode, the time interval of the positive potential exceeding that of the negative potential.

Description

The invention relates to a reinforcing or supporting element for building materials, in particular electrodes designed as a plaster base for electroosmotic dehumidifying devices with a reticulated supporting body, and a method for the electroosmotic movement of polar liquids in porous solids (masonry or the like) by applying an electrical voltage between Electrodes, using such reinforcement or support elements.

Reinforcing or supporting elements for building materials are known which consist of rod-shaped or net-shaped or lattice-shaped materials. For reinforcement of concrete structures, mainly mats or grids made of structural steel or as a plaster base, mainly fine metal grids are used. If the metal grids are used as a plaster base, they are often coated with fired ceramic materials to ensure better adhesion of the plaster mortar. The disadvantage of these metallic Plaster carriers that, due to different pH values, they are exposed to corrosion in the building and the different moisture conditions. In many cases, the arrangement of the grids in zones with different pH values leads to the formation of a galvanic element and thus to a field structure which causes the structures to be destroyed or the moisture to be drawn up from the ground into the structures. These adverse effects are particularly noticeable when the plaster base is used to renovate old historic buildings that have to be drained. It is therefore often necessary to install electrodes of dehumidification systems working on an electro-osmotic basis in addition to the plaster supports in order to achieve dehumidification of the building structure.

Numerous different methods of draining walls are in use today. As from a research work published by the Austrian artist under the title "Mauerfekeit". Institute for Building Research (Verlag Straßenbau, Chemie und Technik Verlagsgesellschaft mbH, Heidelberg 1967), the following options are distinguished: Plastering measures, ventilation processes, dehumidifiers, installation of sealing layers, pore filling, electro-osmotic and other processes. The present invention belongs to the electroosmotic method, which is why briefly the theoretical basis according to the above. Publication is received.

The electro-osmotic processes use the phenomenon of electro-osmosis to slow down the moisture rising in the capillaries of the masonry and to push it down. Polarization occurs at the interface between water and a solid, with a negative charge on the surface of the solid and a positive charge on the liquid particles. This charge (polarization) normally occurs Not appearing, migration occurs only in an electrical field, whereby the solids (insofar as they are mobile) migrate to the positive anode (also known as electrophoresis), the liquid particles, especially if the solid particles are prevented from moving, strive to migrate to the negative cathode.

Since the water e.g. Always contains salts in the masonry, there is a conductivity, so that by appropriate choice of the electrode materials, galvanic elements can be produced which cause the electroosmotic phenomena. Disadvantages are signs of corrosion and the limited life of the electrodes, and the fact that the device is maintenance-free is an advantage.

With the active methods, the electric field between the installed or attached electrodes is generated by external current. Corrosion can also occur here, but the problem that is solved today by using graphite, the electrically conductive plastics.

The extensive patent literature deals with the arrangement and composition of the electrodes (DE-PS 27 22 985, DE-PS 26 03 135, DE-OS 27 03 813, DE-OS 27 06 193). DE-OS 27 06 172 proposes electrodes with additional foils to prevent corrosion.

As can be seen from DE-OS 27 05 814 and DE-PS 25 03 670, the voltage that can be used in the active process is limited by the decomposition voltage, depending on the composition of the masonry and the salinity of the water, since electrolysis is caused by decomposition of the water Gases were generated that must destroy the components in which the electrodes are installed, such as plaster. According to DE-OS 27 05 814 could be caused by oxyhydrogen formation even pose an explosion risk, so that a limit of 2.8 V is required. On the other hand, it would be desirable to increase the electric field by increasing the voltage in order to improve the desired effect. This is particularly necessary with old or very thick masonry or with very strong moisture pressure. The drying effect can also be achieved much more quickly by increasing the voltage.

The invention is based on the object of creating a reinforcing or supporting element for building materials of the type mentioned at the outset which can also be used in areas with different or changing pH values and which enables an intimate connection with the building materials which give them. In addition, it should be possible to use this reinforcement or support element at the same time as an electrode for a dehumidification system working on an electroosmotic basis.

This object of the invention is achieved in that the support body is designed as a flexible network, which consists of a plastic - in particular a conductive, essentially ion-free plastic in the manner of a thermoset with a macromolecular structure - and / or is surrounded by it, and in that the network thread-like carrier materials, for example Carbon thread, metal thread or the like, which are preferably silver-plated, are assigned.

The surprising advantages of this solution lie in the fact that a chemically neutral reinforcement or support element for building materials is created, the installation of which is possible in building structures regardless of different pH values. Furthermore, this type of reinforcement or support elements prevents the formation of electrical fields by electrochemical degradation, so that the use of such reinforcement elements is also possible in the renovation of old historical structures with moistened structures.

Another surprising advantage of the solution according to the invention is that the reinforcement or support elements can simultaneously be used as electrodes for a dehumidification system operating on the electroosmotic principle. The mesh-like electrode is particularly suitable for field build-up over large areas, whereby the intimate connection of the mesh with the unspecific building materials also ensures intensive field build-up over a longer period of operation. In addition, subsequent settlements between the individual building materials or the entire building structure do not impair intensive field construction. If individual threads of the network are interrupted, a thawing or a power supply is ensured through the connection via the threads running in parallel, especially in systems operated with external current. At the same time, however, the prerequisite is created that when using the reinforcing or supporting elements as electrodes, even in the case of large-scale systems and at higher operating voltages, no disturbances due to electrolytic decomposition or hydrogen deposits on an anode can occur. The decisive factor here is the continuous coating of the mesh with conductive plastic. Thanks to the flexibility of the network, it can be easily adapted to different environmental conditions, such as different floor levels or building levels. This advantage comes to the fore especially when used for the renovation of dampened building structures. Since the coating of the mesh with the conductive plastic causes the voltage to be distributed uniformly over the entire surface of the electrode, a large-area electrokinetic effect, for example large-area electroosmosis, is achieved.

According to another very essential feature of the invention, it is provided that the plastic forming or surrounding the mesh, for example an acrylate, has at least partially cross-linked polymers a high surface roughness and a low plasticizer content, and preferably with an oxygen-reducing metal, eg titanium, boron, is doped. The high waiter Surface roughness has the advantage that there is an intimate connection of the surrounding building materials, in particular the plastering mortar with the network. In connection with the low plasticizer content it is achieved that this intimate connection is also maintained and there is no shrinkage on the circumference of the network, so that even for a long time a perfect contact with the surrounding construction materials, especially when using the reinforcing elements as electrodes for dehumidification systems, is guaranteed is. The permanent contacting is additionally increased by the use of oxygen-doped metals-doped plastics, since the passivation of the anode network is switched off.

It is also advantageous if the plastic surrounding the thread-like carrier material has semiconductor properties and a relatively low carbon content, the carbon components being freely suspended in the plastic. The use of a plastic having semiconductor properties is distinguished by the fact that the charge transport takes place through electrons and holes, in contrast to the so-called ion semiconductors, in which mass transport is associated with the charge transport. Above all, the conductivity in the temperature conditions occurring in building structures is advantageous for the use of such reinforcing or supporting elements for building materials. Since the carbon components in these semiconductors do not have to form a skeleton in order to increase the conductivity, it is possible to find sufficiency with a low carbon component, as a result of which the fragility of such plastic coatings is reduced.

According to a further embodiment of the invention it is provided that the network is assigned power supply lines which are formed by lanyards composed of a plurality of flexible individual strands. This enables an evenly continuous con Tacting the network when using the reinforcing element as an electrode or it is advantageously possible, when using the reinforcing or supporting elements according to the invention, to contact them retrospectively at any time to build up electrical fields in building structures, for example to install horizontal barriers for moisture insulation or the like .

Furthermore, it is also possible within the scope of the invention that the power supply line is made of carbon threads or metal threads, e.g. made of titanium or the like, since this improves the power supply lines, the strength of the networks against mechanical stresses and at the same time the conductivity. In addition, the use of titanium is distinguished by the small electrochemical potential difference compared to hydrogen, so that the risk that a galvanic element can build up is additionally reduced.

According to the invention, however, it is also possible for the power supply line to be arranged in the longitudinal direction of a band-shaped network and approximately centrally between the longitudinal edges of the network. This ensures an even power supply to the various power supplies and, above all, easily damages bridged power supplies.

According to a further advantageous embodiment of the invention, it is provided that the mesh size is adapted to the building material surrounding the network and preferably has a mesh size of 5 mm in the form of a plaster base. This makes it possible to adapt the reinforcement or support elements to their area of application, so that the network cannot be damaged when the building materials are introduced.

It is also advantageous if the network is elastic and back is designed to be spring-free, in particular made of flexible plastic, since this greatly simplifies the plastering or incorporation of the reinforcing elements into the building materials and allows them to be well adapted to the surfaces of the building bodies.

In the context of the invention it is also possible that the network forms a cathode and / or an anode of a voltage supply device for an electro-kinetic system and that the two networks are arranged one above the other in the vertical direction, the network closer to the ground with the negative pole a DC voltage source and the other network is connected to a positive pole and that a counter-pole switching element is arranged between the network connected to the positive pole and the DC voltage source. By using electrodes of the same type, the disadvantages of electrolytic degradation due to potential differences existing in the structure can be avoided. In addition, it is possible to work with relatively low voltages when using the reinforcing elements as electrodes in so-called active electro-kinetic systems, since by using a counter-pole switching element, electrolytic deposits on the anode are avoided and therefore there is no passivation or insulation of the network connected to the positive pole.

According to the invention, it is also possible for the counter-pole switching element to have a pulse switch arranged in parallel with smoothing diodes of a rectifier circuit, from which an input at the negative pole of a DC voltage source and the output of which is connected to a supply line to the anode, a closing contact of the pulse switch being applied via a timing element . Such a circuit can be produced very easily in the different technologies, such as relay control, transistor control or with integrated switching components set so that a simple adaptation to the different applications and environmental conditions is easily possible.

Finally, the invention also encompasses a method for the electroosmotic movement of polar liquids in porous solids (masonry or the like) by applying an electrical voltage between electrodes, using net-shaped supporting bodies of a reinforcing or supporting element for building materials.

This method is characterized in that the voltage applied is a voltage alternating between positive and negative potential, in which the time integral of the positive voltage is greater than that of the negative voltage, the positive voltage preferably being greater than the negative voltage. The feature of the larger positive time integral enables the desired electroosmotic effect, while the negative voltage eliminates any substances formed by electrolytic decomposition, in particular the unfavorable gases, in a reverse reaction. The high concentration of the substances produced at the eel electrodes leads to a rapid and preferred reversal of the chemical processes, while the build-up of the reversed electric field and thus the reversal of the electroosmotic effect is reduced or completely prevented.

The method according to the invention for different time integrals can be demanded by different time components and / or different voltages of the positive and negative voltage components. There are particular advantages if the AC voltages represent a sinusoidal voltage with a mains frequency with a reduced negative voltage. The voltage peak of the negative period can be cut off or only the part of the sine voltage exceeding a certain voltage can be used. It is particularly advantageous here that this is very easily realized by semiconductors.

The advantage of the invention lies not only in the increased desired effect, which leads to the desired success in a fraction of the time, even with very high water pressure in old and thick masonry, but also in the reliable avoidance of chemical decomposition of the water while preventing gas formation or deposition of heavy metals, which in turn can lead to the destruction of building materials. The measured effective voltages of the positive portion of the AC voltage can be greater than 16 V. Electrodes made of conductive or semiconducting plastics are not attacked.

Finally, the invention also encompasses a method in which the network is connected to a structure via chemically or electrochemically resistant materials and then a construction material, in particular a plastering mortar, is applied to the network and embedded between the outside of the construction material and the structure, after which the Network is connected to the DC voltage source via the opposite pole switching element and the voltage alternating between positive and negative potential is applied. This advantageously enables the combination of a reinforcement or support element with the use as an electrode for a dehumidification system operating on the electroosmotic principle. Due to the sensible sequence of the individual process steps, an optimal result is achieved when using the reinforcement or support element.

For a better understanding of the invention, it is explained in more detail below with reference to the exemplary embodiments shown in the drawings.

• Fig. 1 eine Draufsicht auf einen netzförmigen Tragkörper, gemäß der Erfindung;
• Fig. 2 einen netzförmigen Tragkörper nach Figur 1 in schaubildlicher Darstellung, teilweise geschnitten;
• Fig. 3 einen Faden des Tragkörpers im Schnitt, gemäß den Linien III - III in Figur 2;
• Fig. 4 die Anordnung der erfindungsgemäßen, netzförmigen Tragkörper bei gleichzeitiger Verwendung als Elektroden für ein Entfeuchtungssystem;
• Fig. 5 eine Ausfuhrungsvariante einer auf elektroosmotischem Prinzip arbeitenden Elektro-Kinetik-Anlage, bei der der erfindungsgemäße netzförmige Tragkörper als Verstärkungs- bzw. Tragelement und gleichzeitig als Elektrode eingesetzt wird;
• Fig. 6 eine Spannungsversorgungsvorrichtung für die erfindungsgemäßen Verstärkungs- bzw. Tragelemente, wenn diese als Elektroden für eine Elektro-Kinetik-Anlage verwendet werden;
• Fig. 7 eine Spannungszeitkurve für die zwischen positivem und negativem Potential wechselnde Spannung, wie sie an die Verstärkungs- bzw. Tragelemente angelegt werden kam, wenn diese als Elektroden einer Entfeuchtungsanlage verwendet werden.

Show it

• Figure 1 is a plan view of a net-shaped support body, according to the invention.
• 2 shows a reticulated support body according to FIG. 1 in a diagrammatic representation, partly in section;
• Figure 3 shows a thread of the support body in section, according to lines III - III in Figure 2.
• Figure 4 shows the arrangement of the net-shaped support body according to the invention with simultaneous use as electrodes for a dehumidification system.
• 5 shows an embodiment variant of an electro-kinetic system operating on the electroosmotic principle, in which the net-shaped support body according to the invention is used as a reinforcement or support element and at the same time as an electrode;
• 6 shows a voltage supply device for the reinforcement or support elements according to the invention when these are used as electrodes for an electro-kinetic system;
• 7 shows a voltage-time curve for the voltage alternating between positive and negative potential as it came to be applied to the reinforcement or support elements when these are used as electrodes of a dehumidification system.

In Figure 1, a support body 1 is shown, which serves as a reinforcing or supporting element for building materials. This support body 1 is designed as a network 2.

In the network 2, a power supply line 3 is integrated, which is formed by a conveyor belt 4. The power supply line 3 is arranged in the longitudinal direction - arrow 5 - of the band-shaped network 2 approximately centrally between the two longitudinal edges 6. The Lahnband 4 consists, as indicated over part of its length, from a plurality of individual strands 7, which are formed by metal thread 8. The surface of the metal threads 8 can be silver-coated, or e.g. Titanium wire is used to obtain a good conductivity and a small potential difference between the surface of these metal threads 8 and the plastic 9 surrounding them. If the potential difference is small, then an electromotive force can hardly be formed between the different materials, such as silver or titanium and the plastic 9 according to the invention, and therefore no current flows. However, this does not lead to metal degradation, especially of those metals that have a more negative intrinsic potential, so that no ions go into solution.

In Figure 2, a support body 10 is shown, which is formed by a network 11. The individual threads 12 to 14 of the network 11 consist of a plastic 15. This plastic 15 is essentially ion-free and is designed in the manner of a thermoset with a macromolecular structure. This plastic 15 is preferably, for example, an acrylate with at least partially crosslinked polymers, which has a high surface roughness and a low proportion of plasticizer. The plastic 15 can preferably be designed in accordance with the Austrian patent specification 313 588 from the same inventor. It is advantageous if the plastic is doped with oxygen-reducing metals. When using a network 11 with a plastic doped in this way 15 as an anode, the oxidation of the anode and its passivation is switched off. In order to make the network correspondingly resistant to mechanical stresses or to increase the conductivity of the network threads, metal threads 16 or carbon threads 17 can be incorporated into these network threads. The metal or carbon threads 16 and 17 are incorporated in the plastic 15 of the threads 13 of the network.

In the embodiment in FIG. 2, it is further recommended that a power supply line 18 is formed by a thread 14 of the network. In this case, metal threads 14E or carbon threads 17 are arranged in these mesh threads 14 to increase the conductivity, but also in addition to increase the mechanical strength, which can optionally be provided with a silver coating 19. This silver coating achieves the advantages already described in connection with FIG. 1. Of course, it is also possible to provide the metal or carbon threads 16, 17 in the threads 13 with a silver coating in order to achieve the conductivity of the entire network, and thus an increased field structure over the entire network area.

In the context of the invention, it is also possible to use any plastic 15 which is highly elastic, flexible or limp and conductive, in the manufacture of the network 11. In this case, the entire network is covered with the plastic 15 to produce the desired surface quality of the network 11, as is indicated in the region of the crossing threads 12 and 14 of the network 11.

The carbon or metal threads 17 or 16, regardless of their function with regard to improved electrical properties, such as higher conductivity and the like, form a strength-enhancing, thread-like carrier material 20. The carrier material 20 can of course be formed from threads of any material, but the carbon and metal threads are preferred because they have a good combination of high strength and good conductivity within the desired properties of the invention.

FIG. 3 shows a section through a thread 13 of the net 11 on an enlarged scale. As can be seen, 13 metal threads 16 or carbon threads 17 are embedded in the plastic 15 of the thread, some of which are provided with a silver coating 19. Furthermore, it can be seen from this section that 15 plastic constituents 21 are freely suspended in the plastic. This free-floating arrangement of carbon constituents 21 is possible because the plastic 15 has semiconductor properties and the carbon is therefore not required to build up a line system, but only to increase the conductivity.

FIGS. 4 and 5 show two different design variants as to how the support bodies 1 or nets 2 or 11 according to the invention can be arranged on structures 22 and 23, respectively. The building structure 22 or 23 consists, for example, of brick masonry or reinforced concrete in the exemplary embodiments shown.

In the embodiment according to FIG. 4, two nets 24 and 25 are fastened to the building structure 22 by means of fastening means 27 consisting of resistant materials 26, for example plastic clamping anchors. After the network 24 is connected to the positive pole 28 and the network 25 to the negative pole 29 of a DC voltage source 30 of a voltage supply device 31, the networks 24 and 25 are embedded in a building material 32, in the present case a plastering mortar 33. The plastering mortar 33 is applied in such a thickness that the nets 24 and 25 can lie below its outside 34. The networks 24 and 25 thus form an anode 35 and a cathode 36 of an electro-kinetic Appendix 37. In order to prevent an effective horizontal barrier against the rising of moisture 38, which is contained in the foundation area of the building structure 22, the two networks 24 and 25 are arranged one above the other in the vertical direction on the outside of the building body. The grid 25 forming the cathode 36 is arranged in the bottom 39, a change of soil advantageously taking place in the area of the net 25, so that porous, highly water-draining layers are arranged in the area of the net. In the application form shown in FIG. 5 of the support body according to _the invention - in the description of which the same reference numbers are used as in FIG. 4 for the same parts - the net 24 forming the anode 35 on the base 24 is due to a thickness 40 of the structure 23 the inside of the building facing side of the structure 23 and the grid 25 forming the cathode 36 attached to the outside thereof. As in the exemplary embodiment according to FIG. 4, the network 25 is again arranged in the region of the bottom 39 and when the two networks 24, 25 are applied to the DC voltage source 30, an intense electrical field 41 is created, which is indicated schematically by field lines 42.

Due to the arrangement of the anode above the cathode, the moisture travels within the structure 23 in the direction of the cathode or is prevented from rising in the structure 23 by the moisture 38 rising in the foundation. This dehumidification or drying effect is symbolically indicated by arrows 43 in FIGS. 4 and 5 in both exemplary embodiments. The field structure between the networks 24 and 25 in FIG. 4 is also symbolically indicated by field lines 42.

In order to avoid depolarization of the anode and thus a weakening of the conductivity and a reduction in the field strength irrespective of or in addition to the doping of the plastic, the DC voltage source 30 is assigned a counter-pole switching element 44. This opposite pole switching element 44 causes the Polarity in the electro-kinetic system 37 is periodically and briefly reversed. The ions in the electric field cannot be deposited as a result, the depolarization is avoided. The high conductivity achieved in this way in the building structure 22 or 23 prevents the salt ions migrating between the networks 24 and 25 from depositing and blooming. Due to the high conductivity, a high current passage in the structure 22 or 23 is achieved, so that a very intensive field is built up, which causes an intensive water transport in the direction of the cathode.

Of course, it is also possible to arrange the networks 2, 11, 24, 25 according to the invention in two different high positions relative to the floor 39 and to short-circuit them with one another, ie to connect them, as a result of which the natural potential difference is equalized and a so-called horizontal barrier is created which prevents the Prevents water through the built-in networks.

The advantage of using the grids of the invention as reinforcing or _- a supporting element for building materials lies mainly in the fact that by the specific used plastic material, due to the high surface roughness and low shrinkage, over a long period an intimate bond between the structural material and the reinforcing element exists, whereby moisture accumulations in the area of the reinforcing elements and thus subsequent corrosion are switched off and a high electrical conductivity of the system is achieved when using the network as electrodes.

FIG. 6 shows a voltage supply device 45 for the networks 48, 49 according to the invention, which form an anode 46 or a cathode 47. The voltage supply device comprises a transformer 50, smoothing diodes 51, an opposing pole switching element 52 and a timing element 53 Pol switching element 52 has a pulse switch 55 which is arranged in parallel with the smoothing diodes 51 of a rectifier circuit 54 and is formed by a transistor 56. The signal passage through the transistor 56 is made possible for a certain period of time via the timing element 53. The diode 57 assigned to the opposite pole switching element 52 ensures that a voltage passage is only possible if a negative potential is present at an output 58 of the transformer 50. An input 59 of the pulse switch 55 is present at the output 58 of a DC voltage source 60 formed by the transformer 50. An output 61 is connected to a lead 62 to the anode 46. The transistor 56 serving as a make contact is driven by the timing element 53. Between the supply line 62 and a supply line 64 and the anode 46 or the cathode 47, a changeover switch 65 is also provided, with which the voltage supply of the two networks 48 and 49 can be reversed if necessary, so that the anode acts as a cathode or vice versa. Furthermore, a current display device 66 is assigned to the voltage supply device 45. Of course, the formation of this power supply apparatus in the present invention, without departing from this, any modifiable and it is shown instead of the transistor circuit also possible to use corresponding relay controllers or integrated circuits or microprocessors or _d gl..

A preferred form of the voltage-time curve is shown in FIG. The positive sine curve 67 of a correspondingly stepped down mains voltage is preserved, while the negative part 68 of the sine curve is cut off in the lower voltage range, so that as long as the negative part of the original sine curve does not exceed a certain voltage, no voltage is present and only when the sine voltage has reached the predetermined value Voltage limit is exceeded, the voltage exceeding this voltage limit is applied to the electrodes.

If the use of the mains frequency also offers particular advantages, the method according to the invention is not restricted to sinusoidal voltages of 50 or 60 s ^-1 .

This preferred form of the voltage-time curve can be achieved, for example, with the voltage supply device 45 described in FIG. 6. The passage through the transistor 56 is only opened by the km sensor arranged in the timing element 53 after a positive period of time, so that the anode 46 is subjected to a negative voltage. With a corresponding design of the timing element 53, the supply of the negative voltage via the lead 62 through the transistor 56 is then blocked again when the preselected voltage level is undershot. This creates the special voltage curve shown in FIG. 7.

It is advantageous for the present invention when using the reinforcement or support elements according to the invention as electrodes if their minimum distance in the vertical direction of the structure is at least 10 cm. The network forming the cathode is preferably to be arranged approximately 30 to 50 cm below the surface of the ground. For the method according to the invention in connection with the voltage supply device 45, it is of crucial importance that the load integral at any point of the electrodes with regard to the voltage or the current strength is set in such a way that the production of aggressive oxygen is negligibly small or only in one Order of magnitude moved by which the reinforcement or support elements cannot be destroyed.

List of reference symbols

• 1 supporting body
• 2 network
• 3 power supply line
• 4 tapes
• 5 arrow
• 6 longitudinal edge
• 7 single strands
• 8 metal thread
• 9 plastic
• 10 supporting bodies
• 11 network
• 12 threads
• 13 threads
• 14 threads
• 15 plastic
• 16 metal thread
• 17 carbon thread
• 18 power supply line
• 19 silver coating
• 20 carrier material
• 21 coolant component
• 22 structures
• 23 structure
• 24 network
• 25 network
• 26 material
• 27 fasteners
• 28 positive pole
• 29 negative pole
• 30 DC voltage source
• 31 power supply device
• 32 construction material
• 33 plastering mortar
• 34 outside
• 35 anode
• 36 cathode
• 37 Electrical kinetic system
• 38 moisture
• 39 floor
• 40 thickness
• 41 field
• 42 field line
• 43 arrow
• 44 opposite pole switching element
• 45 power supply device
• 46 anode
• 47 cathode
• 48 network
• 49 network
• 50 transformer
• 51 smoothing diode
• 52 opposite pole switching element
• 53 timer
• 54 Rectifier circuit
• 55 pulse switches
• 56 transistor
• 57 diode
• 58 exit
• 59 entrance
• 60 DC voltage source
• 61 exit
• 62 supply line
• 63 make contact
• 64 supply line
• 65 switches
• 66 Current display device
• 67 sine curve
• 68 share

Claims (15)

1. Reinforcing or supporting element for building materials, in particular electrodes designed as plaster bases for electroosmotic dehumidifying devices with a net-shaped supporting body, characterized in that the supporting body (1, 10) is designed as a flexible network (2, 11, 24, 25, 48, 49) which consists of a plastic (9, 15) - in particular a conductive, essentially ion-free plastic in the manner of a thermoset with a macromolecular structure - and / or is uneven with it, and that the network (2, 11, 24, 25, 48,49) thread-like carrier materials (20), for example Carbon threads (17), metal threads (8, 16) or the like, which are preferably silver-plated, are assigned. 2. Reinforcement or support element according to claim 1, characterized in that the plastic (9, 15) forming or surrounding the network (2, 11, 24, 25, 48, 49), e.g. an acrylate, with at least partially crosslinked polymers, has a high surface roughness and a low proportion of plasticizer, and preferably with an oxygen-reducing metal, e.g. Titanium, boron, is doped. 3. Reinforcing or supporting element according to claim 1 or 2, characterized in that the thread-like carrier material (20) surrounding plastic (9,15) has semiconductor properties and a relatively low carbon content, the carbon components (21) floating in the plastic ( 9.15) are arranged. 4. Reinforcement or support element according to one of claims 1 to 3, characterized in that the network (2, 11, 24, 25, 48, 49) power supply lines (3) are assigned, which by several flexible individual strands (7) composite lanyards (4) are formed. 5. reinforcement or support element according to one of claims 1 to 4, characterized in that the power supply line (3) by incorporated into the network threads, preferably silver-coated, carbon threads (17) or metal threads (8, 16) e.g. is formed from titanium or the like. 6. Reinforcing or supporting element according to one of claims 1 to 5, characterized in that the power supply line (3) in the longitudinal direction of a band-shaped network (2, 11, 24, 25, 48, 49) and approximately centrally between the longitudinal edges ( 6) the network is arranged. 7. reinforcement or support element according to one of claims 1 to 6, characterized in that the mesh size is adapted to the network (2,11,24,25,48,49) surrounding building material (32) and preferably during training has a mesh size of 5 mn as a plaster base. 8. reinforcement or support element according to one of claims 1 to 7, characterized in that the network (2, 11, 24, 25, 48, 49) is elastic and springback-free, in particular made of flexible plastic (9, 15). 9. reinforcing or supporting element according to one of claims 1 to 8, characterized in that the network (2, 11, 24, 25, 48, 49) a cathode (36, 47) and or or an anode (35, 46) of a voltage supply device (31, 45) for an electro-kinetic system (37) and that the two networks (2, 11, 24, 25, 48, 49) are arranged one above the other in the vertical direction, the bottom (39 ) closer network (2,11,25,49) with the negative pole (29) of a DC voltage source (30,60) and the other network (2,11,24,48) with a positive pole (28) and that between the on the positive pole (28) connected to the network (2, 11, 24, 48) and the DC voltage source (30, 60) a counter-pole switching element (44, 52) is arranged. 10. Reinforcement or support element according to one of claims 1 to 9, characterized in that the opposite pole switching element (44, 52) has a pulse switch (55) arranged parallel to smoothing diodes (51) of a rectifier circuit (54), one of which Input (59) at the negative pole (29) of a DC voltage source (30, 60) and its output (61) is connected to a feed line (62) to the anode (35, 46), with a make contact (63) of the pulse switch (55) being connected a timer (53) is applied. 11. A method for the electro-osmotic movement of polar liquids in porous solids (masonry or the like) by applying an electrical voltage between electrodes, using reticulated supporting bodies of a reinforcing or supporting element for building materials according to one of claims 1 to 10, characterized in that that the applied voltage is a voltage alternating between positive and negative potential, in which the time integral of the positive voltage is greater than that of the negative voltage, the positive voltage preferably being greater than the negative voltage. 12. The method according to claim 11, characterized in that the time of the positive applied voltage is greater than that of the negative. 13. The method according to any one of claims 11 or 12, characterized in that the AC voltage is a sinusoidal voltage with mains frequency, wherein the voltage of the negative period is reduced, in particular the voltage peak of the negative period is cut off. 14. The method according to claim 13, characterized in that in the negative period only the portion (68) of the sine voltage exceeding a certain voltage is applied and preferably the sine voltage (67) of the positive half-wave is greater than 6 volts. 15. The method according to any one of claims 11 to 14, characterized in that the network (2,11,24,25,48,49) via chemical or electrochemical resistant materials (26) connected to a structure (22) and then a Building material (32), in particular a plastering mortar (33) applied to the network (2, 11, 24, 25, 48, 49) and embedded between the outside (34) of the building material (32) and the building body (22), after which the network (2, 11, 24, 25, 48, 49) is connected to the DC voltage source (30, 60) via the opposite pole switching element (44, 52) and the voltage alternating between positive and negative potential is applied.

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