DE19944757A1 - A method for driving out moisture fro a wall using electrodes and a low voltage electrical supply controlled by a microprocessor to maintain a constant current. - Google Patents

Abstract

The wall (1) has electrodes (4) embedded connected by wires (7) to a low voltage supply source. A constant voltage is first applied for a period in which the current rises to a maximum value after which the power is held constant as the current reduces until the voltage is again held constant.

Description

State of the art

The invention is based on one device and one Process for drying and dehumidifying masonry according to the preambles of claim 1 and claim 8.

To masonry, especially walls, floors or ceilings, from Buildings, from moisture penetrating from the ground exempt, are state of the art processes and Devices known based on the principle of electroplating based (DE 44 00 503 C2, EP 0 100 845 A2). In the of the Moisture affected areas of the masonry will be on electrodes inside the building and with a Power supply electrically connected. All Electrodes are at the same potential. Antipole to the The electrodes form the masonry on the Soil surrounding building exterior. To the electrodes a square wave voltage is applied. In the emerging  electric field between the inside wall of the building and that Earth surrounding buildings migrate into the masonry water molecules penetrated to the outside of the building and are pushed back into the ground. Is that Masonry in a constantly moist soil, that's what it has to do Procedures are carried out continuously to make a new one To prevent dampening of the masonry. In order to avoid that the salts dissolved in the water adhere to the If the electrodes are deposited, the square-wave voltage becomes the opposite pole created.

A disadvantage of the known methods and Devices that the voltage source regardless of the Moisture of the masonry always the same voltage impulses delivers. To ensure adequate drying, is a certain voltage value is specified, but this is frequent is not sufficient or is not necessary. The voltage is applied as a square wave voltage of constant period length. This means that the drying does not match the particular Circumstances can be adjusted and therefore in their Implementation is time consuming. You can also use the known devices and methods only limited Drying depths can be reached.

The invention and its advantages

In contrast, the device according to the invention the characterizing features of claim 1 and that inventive method with the characterizing Features of claim 8 the advantage that the Power supply through a with a microprocessor equipped control device is controlled. To the Monitoring the drying process is the amperage measured at a given voltage from  Resistance depends (voltage = current strength, resistance). In addition, the electrical power (power = voltage, current starch) is taken into account during drying. With decreasing moisture of the masonry the increases Resistance. This leads to a at constant voltage Decrease in amperage. The current strength gives it Information about the drying condition of the masonry. The Microprocessor control of the control unit varies current and voltage within specified limits and thus fits the Drying process to the particular circumstances. this leads to to optimize the drying process. In this way become faster drying and higher drying depths reached.

The electrical forces acting on the water molecules are larger than the capillary forces of the masonry. Device and Procedures can thus ensure that none Moisturization of the masonry takes place more.

The electric field is for those in the building people who are staying safely and not stressful because the Power supply provides pulses in the low voltage range. The electric field only forms in the masonry.

Graphite electrodes can be used as electrodes, which in boreholes of the masonry filled with graphite mortar be used. One can on the masonry Graphite mortar slurry can be applied. Subsequently can the affected rooms with usual materials get extended.

Thanks to the microprocessor-controlled power supply the drying process to the respective circumstances customized. This allows a particularly high depth of drying can be achieved with short drying times. thanks to the reduced electrical power in monitoring mode  can the inventive device and The method according to the invention saves energy in continuous operation and applied inexpensively.

According to an advantageous embodiment of the invention, the Control device in an operating mode with the voltage increasing drying while holding either electrical power P or the current I constant. The Information regarding the voltage values refer to the following and also in the claims always to the maximum of the voltage impulses. The increasing drying of the wall leads to an increase in the resistance of the masonry and thus with constant voltage to a decrease in Amperage and electrical power. By accordingly increasing the voltage can either Power or current at a constant value being held. So a high can be achieved in a short time Drying depth can be achieved in the masonry.

According to a further advantageous embodiment of the invention, a constant voltage U _{0 is} specified in an initial mode. The current intensity is set within a time interval from 0 to t ₀ to a maximum value I _max , which depends on the resistance of the masonry. This resistance depends, among other things, on the moisture content in the masonry and on the building materials used. When the current I _max is reached, the control _device goes into a second operating mode in which the power is kept constant at the value P _max reached. Since the current strength decreases due to the progressive drying and the associated increase in resistance, the voltage must be increased accordingly. The constant performance leads to a quick drying of the masonry and a high drying depth right from the start of the drying process. As soon as a predetermined maximum voltage U _{max is} reached, the control device switches to a third operating mode. The voltage is kept constant at the maximum value U _max reached. Because of the progressive drying of the masonry, the resistance continues to increase, which at constant voltage U _max leads to a decrease in the current intensity and the power. An increase in the voltage to achieve a constant electrical power is no longer necessary due to the already advanced drying. The moisture content of the wall adjusts to a natural value, which enables a healthy living climate in the affected rooms. When this natural moisture content and the associated resistance is reached, a current intensity I _{min is set} , the value of which does not change in a certain time interval. When the current I _min is reached, the control device goes into a monitoring mode in which the current is monitored.

According to a further advantageous embodiment of the device according to the invention, the control device in monitoring mode only applies the voltage U _max at certain time intervals and measures the current strength. At all other times the voltage is 0 V. The measured value is compared with the minimum current I _min . If the current is less than or equal to I _min , the monitoring mode is maintained and the voltage is set to 0 V until the next time interval. However, if the current strength is increased compared to Imin, the moisture content of the masonry has increased and the resistance has decreased accordingly. In this case, the control device therefore returns to the operating mode and continuously applies the voltage pulses U _max again. Current and electrical power are adjusted according to the relationships mentioned above, and the drying process continues. If the current drops again to the minimum value Imin after drying again, the control device goes into the monitoring mode again. The processes mentioned can also take place several times in succession. If, when drying starts again, a value is reached for the output that is greater than the originally maximum output P _max , then P _{max is} replaced by the higher value P _max 'and I _max by the higher value I _max '. The device and the method thus automatically adjust to changed conditions.

According to a further advantageous embodiment of the device according to the invention, the value of the maximum electrical power P _max reached in the initial _mode and the minimum current intensity I _{min are} stored in the microprocessor. The maximum voltage U _max and the maximum current I _max can also be stored in the microprocessor. In this way, the respective values can be accessed in the different sections of the drying process. If the values stored in the microprocessor are no longer available when the device is started up again after a failure, the drying process starts again with the constant voltage U ₀ .

According to an advantageous embodiment of the invention Device is connected to the power supply depending on the degree Moisturization and after the areal expansion of the affected masonry a large number of electrodes connectable. For use in smaller buildings such as for example garages, cellars or single-family houses for example up to 100 electrodes at a maximum Voltage of 40 V and a maximum power of 40 W. sufficient. On the other hand, larger buildings need to be dried, such as for example apartment buildings, underground garages or Factory halls, so a device with up to 200 electrodes, one Maximum voltage of 40 V and a maximum output of 80 W can be used. The specified voltage values depend among other things on the parameters of the  Power supply and the control device. The values are therefore only to be understood as examples. Are 200 electrodes not sufficient, so multiple devices can be connected to each other. For example, by Connect up to 15 devices with up to 3000 electrodes Will be provided. To ensure that the Low voltage pulses at the different electrodes are not occur out of phase, the microprocessor control selects from all devices automatically a device that as Master the clock for all others connected as slaves Device specifies. Should the master fail due to a defect fail, so this task is automatically performed by another Device taken over. The damage to the original Master device can operate the entire system be resolved. This also applies if the devices at Power failure or temporary overload fail.

According to a further advantageous embodiment of the inventive method, the voltage in Initial mode initially kept constant and the amperage measured. If there is no change in current and so that no drying is found, the tension in small increments of, for example, 1 V successively increased until a change in current occurs. At this value the voltage was kept constant during the initial mode. Usually the tension is during the initial mode to a fixed value of, for example, 21 V. set. This tension is sufficient for certain masonry but not enough to trigger drying. As a result, remains a change in the measured current. The gradual increase in tension causes that for the Drying necessary and sufficient tension set can be. The voltage in the initial mode is therefore always adapted to the masonry to be dried and not by chosen so high in advance that in any case drying  is guaranteed. The method according to the invention can thus operate more economically in terms of energy consumption as a known method.

According to a further advantageous embodiment of the invention is the clock ratio of the low-voltage pulses by the Microprocessor generated. This leads to the positive and negative voltage pulses in a certain time interval stand in a predetermined relationship. This ratio is however not fulfilled for every period. This kind of tension Compared to a square wave voltage with constant Period length the advantage of a higher flexibility.

Further advantages and advantageous configurations of the Invention are the following description, the drawing and removable from the claims.

drawing

In the drawing is an embodiment of the invention shown and described in more detail below. Show it:

Fig. 1 graphs of power, voltage and current over time

Fig. 2 installation of the electrodes in a wall,

Fig. 3 arrangement of the electrodes on a wall and a floor.

Description of the embodiment

In Fig. 1, the power, the voltage and the current strength are plotted over time. In the initial mode from 0 to t ₀ , a predefined voltage U _{0 is} specified. During this time, the current strength and power increase. At t ₀ , a maximum current I _max and a maximum power P _{max are} reached. The power P _max is kept constant until time t ₁ . Since the current strength decreases between t ₀ and t ₁ due to the progressive drying, the voltage must be increased for this. A maximum predetermined voltage U _{max is} reached at t ₁ . This is maintained until t ₂ . Due to the progressive drying and the associated decreasing resistance, the current intensity and the output decrease until a minimum current intensity I _min corresponding to the natural moisture content of the masonry is reached at t ₂ , which does not change in the time interval between t ₂ and t ₃ . At t ₃ the device goes into monitoring mode. The voltage source is switched off and only switched on for a short time at predetermined intervals in order to measure the current strength and to compare it with the minimum current strength I _min . If the current is less than or equal to I _min , the system remains in monitoring mode and the voltage source is switched off until the next check. If, on the other hand, the current strength is greater than I _min , the voltage U _{max is} continuously applied again. The drying process starts again as at time t ₁ .

Fig. 2 shows a section of a wall 1 in cross section. Plastering mortar 3 mixed with graphite powder is introduced into an approximately 15 cm deep bore 2 running obliquely downwards and the electrode 4 is washed in. The cable which cannot be seen in FIG. 1 and is led out of the electrode 4 is connected to further electrodes ( FIG. 2). The wall is then completely or at least partially provided with a thin slurry 5 mixed with graphite powder.

Fig. 3 shows the arrangement of a plurality of electrodes on a wall 1 and a bottom 6. The electrodes 4 are connected to one another via electrical lines 7 and are connected in the direction of the arrow to a voltage supply, not shown in the drawing. The distance between the electrodes can be between 0.4 and 1.5 m depending on the moisture level of the masonry.

All in the description, the following claims and The features shown in the drawing can be both individually as well as in any combination with each other be essential to the invention.  

List of reference numbers

1

wall

2nd

drilling

3rd

Plastering mortar

4th

electrode

5

Sludges

6

ground

7

electric lines

Claims (12)

1. Device for drying and dehumidifying masonry
with a power supply for generating low-voltage pulses of positive and negative voltage values,
with electrodes ( 4 ) that can be inserted into the masonry ( 1 ) and connected to the power supply,
characterized by
that to control the voltage supply and to maintain a constant electrical power a current measuring and equipped with a microprocessor control device is provided. 2. Device according to claim 1, characterized in that the control device in an operating mode the voltage increased with increasing drying and either the electrical power P or the current intensity I keeps constant. 3. Apparatus according to claim 1 or 2, characterized in that the control device in an initial mode holds the voltage at a predetermined constant value U ₀ , that the control device increases the voltage with increasing drying in a second operating mode after reaching a maximum current I _max the electrical power P _{max remains} constant,
that the control device keeps the voltage at the maximum value constant after reaching a certain maximum voltage U _max in a third operating mode, and
that the control device changes to a monitoring mode after reaching a minimum current I _min . 4. The device according to claim 3, characterized in that the control device in the monitoring mode only applies a voltage at certain time intervals, measures the current and compares it with the current I _min , and that the control device applies the voltage U _max at an increased current I _min . 5. Device according to one of claims 3 or 4, characterized in that the value of the maximum electrical power P _max reached in the initial mode is stored in the microprocessor. 6. Device according to one of the preceding claims, characterized in that the value of the minimum current I _{min is} stored in the microprocessor. 7. Device according to one of the preceding claims, characterized in that it is equipped with further devices for drying and dehumidifying masonry can be connected, and that the control devices of the individual devices with each other automatically Select control device that is the master clock for the low-voltage impulses of all others together connected devices as slaves. 8. Process for drying and dehumidifying masonry, in which several electrodes ( 4 ) connected to a voltage supply are introduced into the masonry ( 1 ) and supplied with voltage in the form of low-voltage pulses, characterized by the following process steps,
that the voltage is kept at a predetermined constant value in an initial mode,
that after reaching a maximum current I _max in a second operating mode, the voltage increases with increasing drying and the electrical power P _{max is} kept constant,
that after reaching a certain maximum voltage U _max in a third operating mode, the voltage is kept constant at the maximum value, and
that after reaching a minimum current I _min in a monitoring mode, the current is monitored. 9. The method according to claim 8, characterized in that in the initial mode the voltage is kept at a predetermined constant value and the current is measured,
that if there is no change in the current strength, the voltage is gradually increased by a predetermined value until a change in the current strength occurs,
that the voltage is then kept constant at this value during the initial mode. 10. The method according to claim 8 or 9, characterized in that in the monitoring mode, a voltage is applied only at certain time intervals, the current is measured and compared with the current I _min , and that the voltage U _{max is} applied at an increased current I _min . 11. The method according to any one of claims 8 or 9, characterized characterized in that the process steps run microprocessor controlled. 12. The method according to claim 10 or 11, characterized characterized in that the clock ratio of the low-voltage Pulses generated by the microprocessor.