EP1746214B1 - Method and arrangement for drying masonry and buildings by electro osmosis - Google Patents

Description

The present invention belongs to the technical field of masonry drying by means of the mechanism of action of the electro-osmosis on the object to be dried, and relates to those method and arrangement group in which electrodes on both sides are applied and then a current flow from the anode to the cathode is effected.

In addition to purely mechanical, injection, air circulation and radiation drying processes by means of infrared or microwave radiation, the state of the art in masonry drying also includes those mechanical / electrical processes with the corresponding arrangements which utilize the mechanism of action of electroosmosis with respect to the use of electricity.

For each group of drying methods well-known to those skilled in the art and skilled in the art, there are a variety of drying apparatuses and arrangements, therefore, it would be unnecessary to describe them separately and in detail as prior art.

Those skilled in the field of building drying are generally well-known in the field of drying methods and arrangements that exploit the mechanism of action of electro-osmosis, in particular the actively operating wired electrode methods / arrangements. These are used in contrast to the following passive methods / arrangements predominantly and very numerous in the drying.

In these actively working methods, for example, rods are mechanically introduced into the wall, wired, a suitable means as a counter electrode, for example, again a rod or rods, is / are usually mounted in the ground and this circuit is energized. Thus, a water movement can be set in the object to be dried in motion, this DE 44 00 503 A1 , This has given very good results for dry house draining, but the salt migration that goes hand in hand with uncontrolled water migration has removed the benefits of increased corrosion on the electrodes. There were many building damage. Also known are actively working arrangements with wired grids or networks, this also DE 44 00 503 A1 . DE 37 14 943 C2 , In these arrangements, grids or nets are mounted in / on the wall or under the plaster, wired, a counter electrode is usually positioned in the ground and this circuit is energized. In principle, the distribution of the stress in the masonry is greater in area than in the before and after arrangements. This also raises the question of the electrochemical resistance or the uncontrolled salt transport, since on the one hand the salt transport is associated with the water / moisture movement on the other hand salts crystallize in moisture reduction due to migration and / or evaporation and thus their concentration increase. Unimpairable corrosion damage is the result. Wiring rod assemblies employing the passive approach are well known to those skilled in the art of building drying. In this procedure, the electrochemical relationships are used directly without external voltage source. The electrochemical series of voltages here ensures the build-up of a (low) voltage, so that in the wake here too an uncontrolled water and salt movement begins. Depending on the structure, material and salt composition, there are also high failure rates.

In all previously known methods, incl. Arrangements that use the electroosmosis, either DC or AC voltage is used. They all have the disadvantage that the humidity is not controllable. There are even osmosis applications with extreme drying characteristics, whereby the buildings or parts of buildings after drying were almost dust-dry.

In addition to the above-mentioned methods / arrangements, other methods have been disclosed which are also intended to make use of the mode of action of electroosmosis. Their effect and meaningfulness appears controversial. For example, the revelation uses AT 392 108 B in an arrangement proposed there, a resonant circuit constructed by means of a coil with a capacitance connected in parallel, which builds up an electric field and with which it should be dried. This disclosure, as well as others with these technical effects of irradiation by electromagnetic waves from antennas, including the DE G 89 05 412.1 or EP 0 395 085 B1 , have no relevance to the technical solution proposed below according to the invention.

The font EP-A-0 401 519 describes a procedure and the font WO-A-90 10767 describes a method and an arrangement for drying masonry and structure by means of electro-osmosis, in which a pulsed voltage is applied to at least two electrodes. These are on the one hand In the wall and building, on the other hand in the corresponding environment, the voltages are applied in a certain time sequence to the electrodes or in the case of writing WO-A-90 10767 the arrangement is characterized by certain connections of the inputs and outputs with other arrangement components. A possible structure of the electrodes or references to this is revealed to the reader of this v.g. Not fonts.

Based on the deficiencies of the aforementioned prior art, the invention is based on the object, the arrangement according to the arrangement of the initially described method and further develop arrangements for wall and building dehumidification or dry-keeping by means of current flow from anode to cathode in such a way that an increase in the technical-technological effectiveness of the electroosmosis-based drying process, by a specific influence on the electroosmotic processes and the controllability of the moisture, and at the same time to provide a more effective and easier to handle electrode design and arrangement.

According to the invention this task and objective is solved by the following.

• in den Pulsfolgen A und B für den Puls T₁ von 1 bis 42 V bei Plus-Spannung und für den Puls T₃ von gleichfalls 1 bis 42 V bei Minus-Spannung sowie für die Pulse T₂ und T₄ bei jeweils 0 V,
  sowie zeitabhängig
• für T₁ in der Pulsfolge A zwischen 10 ms und 2 s und in der Pulsfolge B zwischen 1 µs und 100 µs
• für T₂ in der Pulsfolge A zwischen 10 ns und 10 ms und in der Pulsfolge B zwischen 10 ns und 1 µs
• für T₃ in der Pulsfolge A zwischen 1 ms und 1 s und in der Pulsfolge B zwischen 1 µs und 20 µs
• für T₄ in der Pulsfolge A zwischen 10 ms und 10 s und in der Pulsfolge B zwischen 20 µs und 10 ms

zwischen den Elektroden und damit im zu trocknenden Mauer- und Bauwerk und seiner Umgebung realisiert werden. Die erste Pulsfolge A dient mit ihrer Pulsfolge und Pulslänge hauptsächlich dem Zwecke der Hauptentfeuchtung und die zweite Pulsfolge B mit differenzierterer schwächerer elektrischen Wirkung dient in aller Regel dem Zwecke der Verfeinerung des Entfeuchtungsvorgangs, zur Trockenlegung schwach feuchter Bereiche oder zur Trockenhaltung, die dann materialspezifisch eingestellt wird. Mit Hilfe beider Pulsfolgen-Komponenten kann die kapilare Feuchte im Mauerwerk gezielt gesteuert werden.In the object to be dried, according to the method as already known, voltages are generated dual with two differently formed pulse trains, this with a first pulse train A and a second pulse train B. These pulse sequences can be parallel in time, consecutive times and / or in time depending on the resulting requirements overlapping or alternately introduced. Thus, according to the usual experience and knowledge of Trocknungsfachmannes specially adapted to the respective local conditions adapted variable, alternating and / or intermittent current / voltage state size and direction dependent

• in the pulse sequences A and B for the pulse T ₁ of 1 to 42 V at plus voltage and for the pulse T ₃ of likewise 1 to 42 V at minus voltage and for the pulses T ₂ and T ₄ at 0 V,
  as well as time-dependent
• for T ₁ in the pulse sequence A between 10 ms and 2 s and in the pulse sequence B between 1 μs and 100 μs
• for T ₂ in the pulse sequence A between 10 ns and 10 ms and in the pulse sequence B between 10 ns and 1 μs
• for T ₃ in the pulse sequence A between 1 ms and 1 s and in the pulse sequence B between 1 μs and 20 μs
• for T ₄ in the pulse sequence A between 10 ms and 10 s and in the pulse sequence B between 20 μs and 10 ms

be realized between the electrodes and thus in the wall and structure to be dried and its surroundings. The first pulse train A is used with its pulse train and pulse length mainly for the purpose of main dehumidification and the second pulse train B with differentiated weaker electrical effect is usually for the purpose of refinement of the dehumidifying process, for draining weakly moist areas or for keeping dry, which is then adjusted material-specific , With the help of both pulse sequence components, the capillary moisture in the masonry can be specifically controlled.

The claimed dual-operating pulse sequences A and B are shown in concentrated form in the following table: method T ₁ + T ₂ PAUSE T ₃ - T ₄ PAUSE 1.first pulse sequence A Draining from 10 ms 10 ns 1 ms 10 ms to 2s 10 ms 1 s 10 s tension 1 to 42V 0V - 1 to - 42 V 0V 2. second pulse sequence B dry storage from 1 μs 10 ns 1 μs 20 μs to 100 μs 1 μs 20 μs 10 ms tension 1 to 42V 0V - 1 to - 42 V 0V

It can be seen that the first pulse sequence A contains in its structure of pulse sequence and pulse length long active plus pulses and short active minus pulses with intervening shorter inactive pause times, and that the second pulse sequence B has a short duration in its structure of pulse sequence and pulse length active plus pulses and short active minus pulses with intermediate oneself alternating even shorter and multiple longer inactive break times includes.
If appropriate, a multiple pulse sequence A, B, C,... X can also be generated parallel in time, consecutively in succession and / or temporally overlapping over and above the dual pulse sequence.
As an arrangement for carrying out the previously known method are provided in dual mode and periodically operating pulse generator, in which the long-pulse (LP) and short pulse (KP) settings are made material specific, a circuit technically subsequent output stage (2) and in turn the power amplifier circuit-wise following multi-layer electrode, wherein this multi-layer electrode initiates the pulsed current / voltage state in the wall / building. A ground spike closes the circuit by connecting to the power amplifier.

• kaum Bauarbeiten notwendig sind,
• die Wände nicht unkontrolliert getrocknet werden (Gebäudeabriß!),
• Energie summarisch effizient eingesetzt wird,
• Energie direkt mit physikalisch interessierenden Impulsdauern in die Wand eingebracht wird,
• eine Tiefenwirkung während und nach der Trocknung erreicht wird,
• eine ständige Kontrolle der Feuchte - mit Korrekturfunktionen versehen - stattfinden kann,
• bei Bedarf weiterhin Sensoren sowie Datenlogger eingesetzt werden können, die den Regelkreis verfeinern können,
• der Trocknungszeitraum, nach Bauwerks- und/oder Bauherrenmaßgabe festgelegt wird - Schnelltrocknung oder allmähliche Trocknung,
• eine elegante Anpassbarkeit (Sprühverfahren für Elektroden) an sehr unebenen Wänden für die örtlichen Aufgaben einer Trockenlegung möglich ist,
• keine Elektroden in das Mauerwerk eingesetzt werden müssen, da Oberflächenelektroden aufgesprüht werden, somit kein Eingriff mit der event. Gefahr der Bauwerksschädigung erfolgt,
• es möglich ist, mit Hilfe einer minimalen Oberflächenelektrode auch nicht belegte Bauteile physikalisch zu erreichen,
• es möglich ist, den Feuchtegehalt gezielt zu steuern, womit entsprechenden Anforderungen genügt werden kann, wie z.B. die Aufrechterhaltung eines erhöhten Feuchtegrades zum Schutze alter Kunstwerke oder die Einstellung eines geforderten Wohnraumklimas,
• durch den wahlweisen Einsatz der dualen Pulskomponenten die Elektroden zusätzlich geschont werden.

The multi-layer electrode according to the invention consists of a predominantly sprayed multi-layer tape, which is applied directly to the surface to be treated surface and from a first sprayed layer consisting of a binder and a conductor, a second layer thereon, which consists of a sprayed or laid electrical conductor and optionally of a stabilizing, electrically conductive or non-conductive reinforcement, and on top of a third sprayed cover layer, which may consist of an insulating protective coating, or is represented by insulating sheet, is formed. In the multi-layer tape, additional conductive plastic, electrolytes, conductive or non-conductive reinforcing mesh or conductive plaster can be provided as required. A ring closure by means of the multi-layer tape, but with an electrical gap, so as not to cause a short circuit, even with other electrically bridged gaps to the building, usually on the outer walls, with connection of the multi-layer tape to the power amplifier can be provided. In a ring closure around the building electrical bridging of the multi-layer tape, for example, on door and Window openings may be provided by means of normal insulated wire in Kabelkanälchen to overcome the aforementioned gaps. The multilayer tape can also be sprayed on only a single wall in then angular or continuously curved arrangement, for example, meandering, round or oval, optionally as a spiral. Furthermore, the multi-layer tape can also be arranged under channels, eg cable channels. Depending on the existing requirements, it is also possible to perform the multi-layer tape in sections in a wall-locking manner and in sections contactlessly with the masonry.
This new inventive teaching improves drying, especially in the field of building drying, in that

• hardly any construction work is necessary,
• the walls are not dried uncontrollably (building demolition!),
• Energy is used summarily efficiently,
• Energy is introduced directly into the wall with physically interesting pulse durations,
• a depth effect is achieved during and after drying,
• a constant control of the humidity - provided with correction functions - can take place,
• If required, sensors and data loggers can be used that can refine the control loop.
• the drying period is determined according to the building and / or building owner's requirement - quick drying or gradual drying,
• an elegant adaptability (spraying method for electrodes) on very uneven walls is possible for the local tasks of a drainage,
• no electrodes must be used in the masonry, as surface electrodes are sprayed on, thus no interference with the event. Danger of structural damage occurs,
• it is possible to physically reach unassigned components with the aid of a minimal surface electrode,
• it is possible to control the moisture content in a targeted manner, with which corresponding requirements can be satisfied, such as the maintenance of an increased degree of moisture for the protection of old works of art or the setting of a required living space climate,
• By the optional use of the dual pulse components, the electrodes are additionally protected.

In the following embodiment, the invention will be explained in more detail.

The invention will be described in a typical variant of a variety of possible alternatives.

• Fig. 1 zeigt den vorbekannten Verfahrensablauf
• Fig. 2 zeigt die Anordnung der Gesamtanlage

The explanation of the invention is given by way of an example selected method and an exemplary arrangement for the realization of the technical solution according to the invention from a variety of procedural and apparatus alternatives. Since further process and arrangement alternatives are conceivable for this, they thus comprise the teaching according to the invention.

• Fig. 1 shows the previously known procedure
• Fig. 2 shows the arrangement of the entire system

Embodiment 1

On the structure to be treated directly a first layer, which consists of a binder material and a conductive material, here graphite, sprayed. Then a second layer, which is formed from a sprayed-on electrical conductor and from a stabilizing, electrically nonconductive reinforcement of tulle, is applied. On top of that, the third layer of a nonconductive protective lacquer is sprayed on as cover layer.

The multilayer electrode according to the invention thus consists of a predominantly sprayed three-layer electrode, which serves as a closed ring around the building and on a certain particularly wet wall of this building on this meandering is placed.

The building substance to be dried is subjected to the previously known process sequence shown in the following table, thus to the voltage values and directions indicated therein and the associated times via the electrodes according to the invention . In this case, a parallel pulse is carried out in time with the pulse sequence A and the pulse sequence B. method T ₁ + T ₂ PAUSE T ₃ - T ₄ PAUSE T _TOTAL 1.first pulse sequence A Draining 1 s 1 ns 0.1 s 5 s 6,100,000,000 s tension 20 v 0V - 20 V 0V 2. second pulse sequence B dry storage 3 μs 30 ns 1 μs 30 ms 30,00403 ms tension 20 v 0V - 20 V 0V

In this drying, moisture and other important process data are collected inside and outside the substance to be dried for the purpose of process control and processed accordingly by the control of the drying process.

Claims (8)

1. An arrangement for drying masonry and building structures through electro osmosis, wherein a pulsed current flow is caused in the masonry or the building structure by arranging at least two electrodes, on one side in the masonry and building structure, on the other side in the environment associated therewith,
   wherein an impulse generator (1) operating in dual mode in a periodic manner in which the long pulse-LP and short pulse-KP settings are performed in a material specific manner, is switched onto a terminal stage (2), and the terminal stage in turn is switched onto an electrode (3), wherein the electrode (3) introduces the pulsed current/voltage condition into the masonry- building structure (4), and a grounding rod (5) completes the circuit as an opposite electrode through a connection with the end stage (2),
   wherein the electrode is configured as a multilayer electrode (3) and made from a substantially sprayed multilayer band, which is directly applied to the surface of the building structure to be treated and which includes a first sprayed layer which is made from a binder and a conductor and a second layer thereon, which includes a sprayed or placed electrical conductor and possibly a stabilizing electrically conductive or non-conductive reinforcement, and on top of it a third final sprayed cover layer, which can include an insulating protective lacquer, or which is formed from insulating flat material.
2. The arrangement according to claim 1, wherein the multilayer band (3) forms an annular enclosure around the building with an electrotechnically caused gap, wherein the annular enclosure is typically configured on exterior walls with a connection with the terminal stage (2).
3. The arrangement according to claim 2, wherein bridges for the multilayer band (3) are provided for the annular enclosure around the building includes, e.g. at door and window openings through normal insulated wire in wire channels or armored special wiring.
4. The arrangement according to claims 1 through 3, wherein the multilayer band (3) is sprayed also on only one single wall in an angled or continuously curved arrangement, e.g. meandering, circular or oval, possibly as a spiral.
5. The arrangement according to claims 1, 2 and 4, wherein the multilayer band (3) is deployed on the surface, but also under channels, e.g. cable channels or below masonry.
6. The arrangement according to claim 1, wherein the multilayer band (3) is also configured as required flush with a wall in sections and without conductive contact to the masonry in particular sections.
7. The use of an arrangement according to one of the claims 1 through 6 for restricting or restraining growth of fungi or mildew, wherein the sprayed electrodes (3) are disposed on the locations of the fungi or mildew growth around the locations or proximal thereto.
8. The use of an assembly according to claim 1 for configuring a faraday cage for electrically shielding, wherein a distance of bands and a band width is determined as a function of a measured interference field, and the bands can be applied on the surface, below stucco, under a wall paper or under paint.

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