EP0395085A1 - Method for drying out walls through electrosmosis by means of electromagnetic irradiation and electronic apparatus used therefor - Google Patents

Abstract

A method and an electronic apparatus for drying out walls are described. The apparatus comprises an LC oscillating circuit, in which natural oscillations are excited by square-wave pulses of a pulse train signal. The pulse repetition frequency of the excitation signal is lower than the natural frequency of the resonator. After each oscillation excitation by the pulse train signal, the resonator performs a damped oscillation, the amplitude of which drops during the course of half a period of the pulse train signal to a value less than 10% of the maximum amplitude of the oscillation, the resonator emitting in time with the pulse train signal successive electromagnetic wave trains of an amplitude decreasing in a manner corresponding to the oscillation variation of the resonator.

Description

The invention relates to a method for dehumidifying masonry, in which the masonry is exposed to electromagnetic radiation generated by an electromagnetic resonator and emitted by a radiation device, the resonator for generating the electromagnetic radiation with periodic electrical pulses having a pulse repetition frequency lower than the natural oscillation frequency of the resonator to electromagnetic natural vibrations.

The invention further relates to an electronic device for dehumidifying masonry, with an electromagnetic resonator, in particular an LC resonant circuit, with a pulse generator circuit connected to the resonator, which, to excite natural vibrations of the resonator, have periodic pulses with steep pulse edges and with a pulse repetition frequency lower than the natural vibration frequency emits the resonator, and with a device for radiation of electromagnetic waves generated by the vibrations of the resonator.

Field of application of the invention is the dehumidification of masonry, the moisture of which stems in particular from rising damp, such as, for example, due to capillary, osmotic or other electrokinetic effects penetrating into the masonry and rising therein groundwater, backwater or leachate.

It is known that electrical or electromagnetic fields have an influence on rising damp in masonry and can be used to dehumidify the masonry.

The so-called electro-osmosis processes work on the basis of moisture control with electric fields. With these methods, the electric field is created by means of electrodes embedded in the masonry and in the ground. For the correct placement and attachment of the electrodes, however, considerable structural interventions in the masonry are generally required. Another disadvantage of the known electro-osmosis processes is that the electrodes oxidize or corrode over time and thus have only a limited service life.

It has surprisingly been found that dehumidification of masonry can also be achieved without electrodes embedded in the masonry if electromagnetic radiation is allowed to act on the moist masonry. An electronic device of the type mentioned at the outset which works according to this principle is known from the Austrian patent application 2398/86. The known device comprises an L-C resonant circuit which is excited to resonate by a pulse generator circuit. The natural oscillation frequency or resonance frequency of the resonant circuit is a multiple of the pulse repetition frequency of the pulse generator. The pulse repetition frequency of the pulse generator is adapted to the fluctuation frequency of the electromagnetic earth field and is 7 to 15 pulses per second. Through special switching measures, the resonance oscillation of the oscillating circuit is maintained for a certain duration with constant power during each oscillation-stimulating pulse. An antenna connected to the resonant circuit via a coupling capacitor emits electromagnetic wave trains generated in the resonant circuit with an essentially constant amplitude per wave train in time with the vibration-stimulating pulses.

The known electronic device requires a comparatively large amount of circuitry for the generation of the frequency-coordinated pulse sequence signal for the electromagnetic earth field, for which Maintaining a substantially constant amplitude of the resonance oscillation of the resonant circuit and for the temporal limitation of the oscillation trains within a period of the excitation pulse signal.

The invention has for its object to provide an efficient, non-destructive method for dehumidifying masonry that can be carried out with simple means.

To achieve this object, it is proposed according to the invention that a resonator is used to generate the electromagnetic radiation which, after each excitation by the pulse train signal, carries out a damped oscillation, the amplitude of which during a period of half a period of the pulse train signal to a value less than 10% of the maximum amplitude the vibration drops.

It has surprisingly been found that particularly good dehumidification of the masonry to be treated is achieved if the resonator is damped in such a way that its oscillation amplitude drops to a value less than 10% of the maximum amplitude within a quarter period of the pulse sequence signal.

A particularly good dehumidification effect is achieved if a resonator is used whose natural vibration frequency is in the range of 141 kHz +/- 4 kHz.

The aim of the invention is also to provide an electronic device of the type mentioned at the outset for carrying out the method, which is inexpensive to manufacture and requires only a small amount of circuitry.

To achieve this goal, it is proposed that the resonator be designed in such a way that it generates a signal after each vibration excitation by the pulse train signal damped vibration executes, the amplitude of which drops to a value less than 10% of the maximum amplitude of the vibration during the duration of half a period of the pulse train signal.

The resonator interacts with the pulse generator circuit such that it experiences an electromagnetic oscillation deflection when a steep pulse edge occurs, which is followed by further oscillation periods. Due to the damping of the resonator, the resonator oscillation decays almost completely during the duration of a half period of the pulse train signal. The oscillation process is repeated when the next steep edge of the pulse sequence signal occurs. The resonator performs damped oscillation trains in time with the pulse sequence signal and generates electromagnetic waves in accordance with the oscillation profile. Only a few inexpensive electrical or electronic components are required to implement the device according to the invention. A simple pulse shaper circuit, e.g. a Schmitt trigger, or another simple trigger circuit known per se, which converts a sinusoidal voltage into a square wave voltage, for example. The signal supplied to the pulse shaper can be derived, for example, directly from the 50 Hz mains signal, the pulse sequence signal then having a frequency of approximately 50 Hz to excite the resonator. The resonator is preferably designed as a simple L-C parallel resonant circuit, the quality factor of which is selected so that the required damping behavior of the resonator vibration results. The resonator can also be designed as an L-C series resonant circuit.

It has surprisingly been found that a particularly good dehumidification effect for the dehumidification of masonry comes from the device according to the invention if the resonator is so damped that its Vibration amplitude almost completely within a quarter period of the pulse generator signal, but at least drops to a value less than 10% of the maximum amplitude.

In a particularly preferred development of the invention, the pulse generator circuit is designed as a pulse shaper circuit. The pulse shaper circuit is connected to the secondary winding of a network transformer and transforms the AC voltage signal supplied by the network into a 50 Hz square-wave signal, which is used as a pulse train signal for vibrating the resonator.

The coupling of the resonator to the pulse shaper circuit is preferably chosen such that both rising and falling pulse edges of the pulse train signal lead to excitation of an oscillation of the resonator. In this way, every half period of a square wave signal is used to generate an oscillation train and thus to emit an electromagnetic wave train.

The device according to the invention works particularly efficiently with a circuit for suppressing positive voltages. This circuit comprises a diode which ensures that the oscillation-stimulating pulse sequence signal does not assume a voltage which is positive with respect to the earth potential.

Experiments have shown that dehumidification of masonry occurs particularly effectively with the device according to the invention if the natural oscillation frequency of the resonator is in the range from 130 to 150 kHz, preferably 137 to 145 kHz, best at 141 kHz. According to a development of the invention, an optical control display for function control is provided. In one embodiment, the optical control display comprises two between the pulse generator circuit and the resonator in parallel switched, oppositely polarized LEDs. The LEDs provide control of the pulse train signal.

A plastic housing is preferably provided to protect the device from dirt and damage.

Setting means can be provided for setting the desired resonator frequency. In the case of an L-C resonant circuit, a trimmer capacitor or a device that changes the inductance of the coil can be provided for frequency adjustment.

An antenna can be provided for the radiation of the electromagnetic waves.

In a preferred variant, however, the resonator itself is used as a radiation emitter. In the case of an L-C resonant circuit, the coil in particular serves as a transmitter. This further simplifies the circuit.

• Fig. 1 teilweise schematisch eine Schaltung eines erfindungsgemäßen Gerätes zur Entfeuchtung von Mauerwerk und
• Fig. 2 ein Signalverlaufsdiagramm zur Erklärung des Schwingungsverhaltens des Resonators in Bezug auf die Anregungsimpulse der Impulsgeberschal­tung.

In the following an electronic device according to the invention will be described with reference to the figures. It shows:

• Fig. 1 partially schematically a circuit of a device according to the invention for dehumidifying masonry and
• Fig. 2 is a waveform diagram for explaining the vibration behavior of the resonator in relation to the excitation pulses of the pulse generator circuit.

The device according to the invention comprises an LC parallel resonant circuit 10, the resonance frequency of which is 141 kHz lies. The capacitance of the capacitor C of the resonant circuit 10 can be changed in order to adjust the resonance frequency. The resonant circuit 10 is connected downstream of a pulse shaper circuit 12, which converts the sinusoidal 50 Hz signal supplied by a mains transformer 14 into a 50 Hz square wave signal with a duty cycle of 50% and feeds this square wave signal to the resonant circuit 10. Between the pulse shaper circuit 12 and the resonant circuit 10, an optical control display 16 is inserted with two light-emitting diodes connected in parallel and arranged opposite to one another with regard to their flow direction. The control display 16 is used to monitor the function of the device.

The mains transformer 14 serves both as a signal generator for the pulse shaper circuit 12 and as a 12 volt AC voltage source for supplying the entire device according to the invention. A resistor R ensures current limitation of the device. The working current is a few mA. The device therefore requires only low electrical power, which is associated with the advantage of low operating costs.

A diode D is connected in such a way that it suppresses voltage in the device which is positive with respect to earth potential, so that the square-wave signal supplied by the pulse shaper 12 does not assume a voltage which is positive with respect to earth potential.

The operation of the device according to the invention is explained below with reference to FIG. 2. 2 shows a qualitative representation of the amplitude profile of the resonator oscillation (diagram A) in comparison with the pulse train signal delivered by the pulse shaper 12 (diagram B). The frequency of the resonator 10 (141 kHz) or the period of the resonator is not drawn to scale for the sake of simplifying the drawing. When a positive edge F₊ of the square-wave vaccination sequence signal occurs, the oscillating circuit 10 is excited to a natural oscillation, which, however, is damped to such an extent that its amplitude A, which means the amount of the maximum deflection per oscillation period, during the period of a quarter period T / 4 of the rectangular pulse train signal decays almost completely. The next vibration deflection or excitation of the resonator 10 takes place when the next negative edge F₋ of the pulse sequence signal occurs. The voltage changes of the oscillation train following the negative edge F₊ are opposite to those of the previous oscillation train. The vibration trains have essentially the same damping behavior. After a period T of the rectangular pulse train signal, the oscillation processes described above are repeated when the next positive edge F nächsten occurs.

The resonant circuit 10 emits wave trains with an amplitude profile according to diagram A and in time with the pulse train signal, i.e. in each half period of the pulse train signal a wave train to the environment.

The device according to the invention preferably has a plastic housing which does not or only negligibly absorbs the electromagnetic radiation emitted by the resonator. In the case of a device with a metal housing, care must be taken to ensure that the radiation-emitting elements, in particular the coil L, are not enclosed by the housing.
It is not imperative that the pulse train signal be a square wave signal. It is important, however, that the pulse sequence signal contains the resonance frequency of the resonator as a spectral component, which is generally the case when the pulses have steep pulse edges.

The device according to the invention is expediently placed in the vicinity of the masonry to be dehumidified. The range achieved in tests with the exemplary embodiment described above, within which a good dehumidification effect could still be determined, is approximately 20 m, a transmission power of approximately 15 μW averaged over time being measured.

Claims (20)

1. A method for dehumidifying masonry, in which the masonry is exposed to electromagnetic radiation generated by an electromagnetic resonator (10) and emitted by a radiation device, the resonator (10) for generating the electromagnetic radiation with periodic electrical pulses having a pulse repetition frequency excites less than the natural oscillation frequency of the resonator (10) into electromagnetic natural vibrations, characterized in that a resonator (10) is used to generate the electromagnetic radiation, which after each excitation by the pulse sequence signal executes a damped oscillation, the amplitude of which lasts for half a period Period of the pulse train signal drops to a value less than 10% of the maximum amplitude (M) of the oscillation. 2. The method according to claim 1, characterized in that a resonator (10) is used to generate the electromagnetic radiation, which performs a damped oscillation after each excitation by the pulse train signal, the amplitude of which during a quarter period of the pulse train signal to a value less than 10% of the maximum amplitude (M) of the vibration drops. 3. The method according to claim 1 or 2, characterized in that a square wave signal with a pulse duty factor of iw 50% is used as the pulse sequence signal for vibrating the resonator. 4. The method according to claim 1, 2 or 3, characterized in that the pulse train signal for Vibration excitation of the resonator is derived from the mains AC voltage. 5. The method according to claim 3 or 4, characterized in that a resonator (10) is used to generate the electromagnetic radiation, which both on a rising edge (F₊) and on a falling edge (F₋) of the pulse train signal in Natural vibrations is offset. 6. The method according to any one of the preceding claims, characterized in that it is ensured that the vibration-stimulating pulse sequence signal does not assume any voltage which is positive with respect to the earth potential. 7. The method according to any one of the preceding claims, characterized in that a resonator is used to generate the electromagnetic radiation, the natural vibration frequency is in the range of 141 kHz +/- 4 kHz. 8. Electronic device for dehumidifying masonry,
- With an electromagnetic resonator (10), in particular LC resonant circuit,
- With a connected to the resonator (10) pulse generator circuit (12) for the excitation of natural vibrations of the resonator (10) periodic pulses with steep pulse edges (F₊, F₋) and with a pulse repetition frequency lower than the natural oscillation frequency of the resonator (10) emits, and with a device for emitting electromagnetic waves which are generated as a result of the vibrations of the resonator (10),
characterized,
that the resonator (10) is designed such that it is excited by the pulse train after each vibration excitation signal executes a damped oscillation, the amplitude of which drops to a value less than 10% of the maximum amplitude (M) of the oscillation over the duration of half a period (T) of the pulse train signal. 9. Electronic device according to claim 8, characterized in that the resonator (10) is designed such that it carries out a damped oscillation after each oscillation excitation by the pulse train signal, the amplitude of which during a quarter period of the pulse train signal to a value less than 10% the maximum amplitude (M) of the vibration drops. 10. Electronic device according to claim 8 or 9, characterized in that the pulse generator circuit (12) is designed as a pulse shaping circuit, which converts a signal with a sinusoidal shape into a square wave signal corresponding frequency and with a pulse duty factor of 50%. 11. Electronic device according to claim 10, characterized in that the signal input of the pulse shaper circuit (12) is connected to the secondary winding of a network transformer (14) serving as a voltage supply for the entire device and the signal supplied by the network transformer (14) into the pulse train signal for excitation the resonant circuit (10) is formed. 12. Electronic device according to claim 10 or 11, characterized in that both the rising and the falling edges (F₊, F₋) of the pulse sequence signal trigger an oscillation of the resonator (10). 13. Electronic device according to at least one of claims 8 - 12, characterized in that a circuit, in particular a diode (D), is provided for suppressing positive voltages, which ensures that the vibration-stimulating pulse sequence signal does not assume a positive voltage relative to the earth potential. 14. Electronic device according to at least one of claims 8 - 13, characterized in that the natural vibration frequency of the electromagnetic resonator (10) is in the range of 141 kHz +/- 4 kHz. 15. Electronic device according to at least one of claims 8 - 14, characterized in that an optical control display (16) is provided for checking the function of the device. 16. Electronic device according to claim 15, characterized in that the control display (16) comprises two parallel, oppositely polarized light emitting diodes, which are inserted between the resonator (10) and the pulse generator circuit (12). 17. Electronic device according to at least one of claims 8 - 16, characterized by a plastic housing. 18. Electronic device according to at least one of claims 8 - 17, characterized in that the resonator frequency is adjustable. 19. Electronic device according to at least one of claims 8 - 18, characterized in that the device for emitting electromagnetic waves is an antenna coupled to the resonator (10). 20. Electronic device according to at least one of claims 8 to 18, characterized in that the resonator (10) forms the device for emitting electromagnetic waves.

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