EP0247216A1 - Arrangement for drying damp insulating layers, such as layers for noise insulation , heat insulation or the like - Google Patents

Abstract

1. An arrangement for drying insulating layers (12) having become damp by leaked-in water such as layers for noise insulation in floating floor finishes, heat-insulating layers or the like by means of air comprising at least one fan (23) connectable over a pipe (18) to at least one bore (26) extending in the floor finish to the insulating layer, characterized in that an exhaust fan (23) draws air out of the insulating layer (12) over the bore (26) acting as an outlet aperture, the fan blowing the air into the atmosphere while indoor air flows into the insulating layer (12) over the distantly disposed inlet aperture (24) and wherein a water separator (19) is disposed upstream of the exhaust fan (23).

Description

The invention relates to a method for drying out insulating layers that have become moist due to penetrated water, such as impact sound insulation layers in floating screeds, thermal insulation layers or the like with the aid of air, in which at least one hole is made up to the insulating layer and air passes through a distant opening and in which the humidified air coming from the insulating layer is measured for its moisture content and the introduction of air is stopped when the moisture content falls below a predetermined value.

Such a method is known (DE-PS 30 43 646).

In the known method, dehumidified air, which has a temperature of 30 to 35 ° C. when entering the bore, is injected through the bore in the screed by means of a high-pressure fan. If the inlet pressure is maintained for a sufficiently long time when the air is injected, the air looks for a way through the ultimately air-permeable impact sound insulation layer and removes the existing water. In the case of floating screeds, there are usually gaps between the screed and the adjacent walls, through which a vapor barrier layer extends upwards. This gap is often sufficient to allow the moisture-enriched air to escape from the impact sound insulation layer, especially when the baseboards are removed. This known method makes the unpleasant removal of the cover and possibly wet insulating layers in the case of water damage superfluous.

The known method is expediently carried out with an adsorption dryer which works in a known manner to regenerate. The air is introduced into the impact sound insulation layer with the aid of a high-pressure fan via the adsorption dryer. The plant outlay is therefore not negligible. Furthermore, per 40 m² of floor about 6 holes with a diameter of 90 mm are drilled. For this reason, it is necessary to remove the floor covering. After the drying process has been carried out, a new floor covering is usually required.

The invention is based on the object of specifying a method for drying out insulating layers which have become damp from outside water, such as impact sound insulation layers in floating screeds or thermal insulation layers, by means of which the installation outlay can be reduced considerably and which normally makes the replacement of the floor covering unnecessary.

This object is achieved in that air is sucked out of the insulating layer and blown into the atmosphere by means of a suction blower or the like via the bore serving as the outlet opening, while room air flows into the insulating layer via the distant outlet opening.

In the method according to the invention, air is sucked out of the insulating layer through a bore, for example in the screed, with the aid of a suction blower. For areas up to 100 m², only a single hole of about 20 mm in diameter is required. The negative pressure is compensated for by flowing room air, which either enters the insulating layer through the side gaps to the wall or through additional holes to be drilled. A treatment of the air by tempering or drying, as is the case with the known method, is omitted. Accordingly, the outlay on equipment is reduced in the process according to the invention. All that is required is a suction fan, which corresponds approximately to the high-pressure fan of the known method.

It has surprisingly been found that the process according to the invention is superior to the known process in every respect. The method according to the invention can thus save around 30% of the time compared to the known method. Such a time saving benefits both the person damaged by water damage and the operator of a system for drying out insulating layers.

Another important advantage of the invention is that far fewer holes need to be drilled per surface for effective dehumidification. These boreholes can also have a much smaller cross section than the boreholes according to the known method. The small number of holes with smaller diameter enable the top coverings or floor coverings to be retained. The costs for drying are therefore drastically reduced again.

At the beginning of the dehumidification process, the free water is sucked out first. Then relatively moist air is drawn out of the insulating layer. So that the suction fan is protected from water and dirt particles, it is expedient according to one embodiment of the invention if water is separated from the humidified air flowing to the suction fan. This can be done using known liquid separators.

If there is a relatively high level of humidity in the room due to water damage, it can also be useful to dry the room air. This can be done with the help of a known adsorption dryer.

Depending on the insulation material used, there may be smaller particles in the insulating layer which are sucked in during the drying process according to the invention. In order to prevent them from getting into the suction fan or into the room, a filter is connected upstream of the suction fan according to one embodiment of the invention.

In addition or as an alternative to the filter, according to a further embodiment of the invention, a sieve can be arranged in the end region of the suction line between the bore and the suction fan. The sieve prevents loose particles present in the insulating layer from entering the suction line and from there to the water separator or the suction fan.

The moist air emerging from the suction fan is at an elevated temperature. Therefore, according to a further embodiment of the invention, it is expedient if this air is passed through a heat exchanger. The heat energy recovered in the heat exchanger can be used to heat the room air and / or to preheat the adsorption dehumidifier. Heated indoor air supports the dehumidification process of the insulating layer, which is faster. Adding heat to the adsorption dehumidifier reduces its energy consumption.

The invention is explained in more detail below using an exemplary embodiment.

The only figure shows a section through a floating screed and a system for drying one a schematic representation of the impact sound insulation layer in the screed that has got wet from outside.

A floating screed layer 11 is applied to a concrete ceiling 10, an impact sound insulation layer 12 made of a suitable soft resilient material being arranged between the layers 10, 11. A vapor barrier layer 14 is drawn up between the screed layer 11 and the room walls 13. Such a floating screed is known and will not be described further in detail.

In the screed layer eats a bore 16 of 20 mm in diameter up to the impact sound insulation layer 12. A nozzle 17 provided with a sieve 17a is inserted into the bore and is connected to the suction inlet of a suction blower 21 via a suction line 18, a water separator 19 and a filter 20. The outlet of the suction fan 21 goes into the atmosphere via a line 22. The line 22 contains a heat exchanger 35 with a blower 36. The hot air obtained by the heat exchanger 35 is conducted into the room according to arrow 37 and / or via a line 38 to an adsorption dehumidifier 26. The suction blower 21 is driven by an electric motor 23. It sucks the air out of the step sound insulation layer 12, water or moisture being taken along. The water is separated and separated in the water separator 19, which is constructed in a known manner. Particles contained in the intake air, for example dust particles or the like, are collected in the filter 20. Because of the negative pressure in the impact sound insulation layer 12 caused by the suction fan 21, ambient air flows into the impact sound insulation layer, as indicated by arrow 24. An additional hole is usually not necessary.

If the room air is too humid due to the water damage that has occurred, a conventional room air drying can be carried out with the aid of a known adsorption dryer 26.

The operation of the system shown in the figure can run completely automatically with the aid of a controller 27. A drain line 31 is connected to the lower end of the water separator 19. A control valve 30, which is controlled by the control device 27, is arranged in the line 31. Instead of a valve 30, a pump can also be provided in order to empty the contents of the water separator more quickly. A level sensor 29 is provided in the water separator 19, for example in the form of a Float switch. If the level sensor 29 responds, the valve 30 is opened or the pump located in the line 31 is switched on in order to carry out the emptying process within a predetermined time. At the same time, the blower motor 23 is switched off via a control line 39. The timer is in the control device. When the time set in the timer has expired, the valve 30 is closed or the pump motor is switched off while the fan 21 is started again. An additional level sensor 40 in the water separator 19 responds if the level sensor 29 has not responded, for whatever reason.

The control device 27, the valve 30 or the pump, not shown, is assigned a pulse counter. The pulse counter counts the number of switching operations of the valve 30 or the pump motor. Each circuit corresponds to the flow of a predetermined amount of water from the water separator 19. The number of pulses is therefore a measure of the amount of water removed from the impact sound insulation 12. In this way, control over the amount of water removed is possible. If this exceeds a value that can theoretically be absorbed by the dehumidified impact sound insulation layer at the same time, there is a display of a construction error, ie the impact sound insulation layer is not is self-contained, but is connected to other water-bearing layers.

The units provided in the system according to the invention can be arranged in a single housing, as indicated by the box 41 shown in broken lines. The box 41 can be a mobile housing that can be moved to any place on the building. Since the adsorption dehumidifier 26 is only used selectively, it is provided as a separate unit. A cooling fan can be assigned to the housing 41 in order to introduce sufficient cooling air into the housing, in particular for cooling the suction fan or its drive motor 23.

Claims (10)

1. A method for drying out insulating layers that have become damp due to penetrated water, such as impact sound insulation layers in floating screeds, thermal insulation layers or the like, with the aid of air, in which at least one hole is made up to the insulating layer and air passes through a distant opening and in which the Moisturized air coming from the insulating layer is measured for its moisture content and the introduction of air is stopped when the moisture content falls below a predetermined value, characterized in that air is sucked out of the insulating layer and into the atmosphere by means of a suction fan or the like via the bore serving as an outlet opening is blown while room air flows into the insulating layer via the distant inlet opening. 2. The method according to claim 1, characterized in that water is separated from the humidified air flowing to the suction fan. 3. The method according to claim 1 or 2, characterized in that the room air is dried. 4. The method according to any one of claims 1 to 3, characterized in that the air blown into the atmosphere is passed through a heat exchanger for heating the room air. 5. The method according to any one of claims 1 to 3, characterized in that the air blown into the atmosphere is passed through a heat exchanger and the recovered thermal energy is supplied to an adsorption dehumidifier. 6. Plant for performing the method according to one of claims 1 to 5, characterized in that the suction fan (21) is connected upstream of a water separator (19). 7. Plant according to claim 6, characterized in that a filter (20) is arranged between the water separator (19) and the suction fan (23). 8. Plant according to claim 6 or 7, characterized in that a sieve (17a) is arranged in the end region of the suction line (18) between the bore (16) and suction fan (21). 9. Plant according to one of claims 6 to 8, characterized in that the water separator is assigned a pulse counting device which counts the number of operations of the water separator (19). 10. Plant according to one of claims 6 to 9, characterized in that the suction fan, the water separator, the filter, the control device and optionally the heat exchanger are arranged in a preferably mobile housing and the housing (41) is assigned a cooling fan.

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