EP0644300B1 - Floor drying method - Google Patents

Abstract

Water damage in a multi-layered building floor is eliminated by a method which makes it possible to monitor the drying. The method uses a neutron probe, with the aid of which the moisture content is determined. As a reference value, a measured value is taken on a floor of the same structure, but without any water damage. In the damaged room, at least all the room corners are then measured. The corner with the highest measured value is selected as monitoring point. During the drying process then beginning, regular measurements are taken again at said monitoring point. When the reference value has almost been reached, then the drying is interrupted. This method permits specific use of the drying implements at the damaged locations. In addition, the period of time for the repair work is shortened. <IMAGE>

Description

The present invention relates to a method for Optimization and control of a drying process Water damage in a multi-layer building floor.

Water damage in building floors is caused by a wide variety of causes: water pipes in the room floor have leaks, water has penetrated from outside in the water damage area or the water damage has been caused by construction damage, for example if the concrete floor has dried out insufficiently before the remaining layers of the multilayer floor are installed .
With multi-layer building floors, the damage is difficult to locate. If at all, localization is only possible by destroying a section of the ground. These floors usually consist of a concrete layer, over which an insulation layer is arranged, which in turn is covered by a film. The screed to which the floor covering is applied is then applied over the film. In order to be able to determine how large the water damage is and where the wettest point is, the floor structure would have to be removed to a greater extent, at least except for the supporting structure. However, this requires too much time and money. For this reason, it has so far only been determined on the side wall structures whether there is water damage. After the drying process, it is checked again whether the damage has been remedied. However, this procedure leads to material destruction in the floor structures that are not affected by water damage. This also means that numerous drying measures are carried out, which cannot be measured and therefore cannot be controlled.

There are several for measuring the moisture content Known methods. In one procedure, one becomes arbitrary a hole drilled through the hole in the ground Compressed air with a known moisture content is blown in. In another place, possibly also in a hole, the humidity of the air flowing out is measured. The difference in moisture levels should provide information about the degree of evaporation or if no evaporation can be determined about the moisture content in the air flow Give area of the floor structure. This type of measurement hides however several sources of error. The measuring air can, for example a dry path through the different layers of the floor and not with the damaged area Come into contact. This is made possible in particular by that the location of the probe hole in the ground is arbitrary is fixed and thereby in an unfavorable place can be placed. WO 84/01794, for example, discloses a measurement method of this type, the blown compressed air is also used to dry the soil.

Another method is a sample of the soil removed, weighed, dried and then using the Weight loss determined the moisture content. Of the However, the location of the sampling is also chosen arbitrarily like the location of the exploratory borehole. The determination of the moisture content is therefore subject to errors. Both how all other methods can presumably only be one provide incorrect rough estimates of water damage. They do not provide a simple overview of what has been found Progress of drying or the water content in the Floor structure. Also all are known and recognized Methods not reproducible because they destroy the material are. A precise damage plan or, for example, a location a leak cannot be created with it. This is however, it is also not possible to be targeted and controllable Carry out drying. The drying devices will not optimally used and the time required for the renovation security considerations will actually go well beyond that required duration extends. The methods are therefore only to determine the existence of water damage and after the drying process for control or proof repairing the damage. In summary, can are said to be the most meaningful methods of material destruction and are not reproducible and the non-destructive Measurement methods no information about the water volume in the Give floor structure.

However, a measuring method is known by means of which the Moisture content of a material determined non-destructively can be. A neutron probe serves as a measuring device, as is known for example from DE-A-1'598'962. This probe emits neutrons with high kinetic energy into the material. The fast neutrons are through light atomic nuclei, especially hydrogen nuclei, slowed down and partially reflected back to the measuring device. The measuring device detects the reflected, slow neutrons and orders them to a count. This counter value provides information about the Moisture content of neutron bombarded Material. The number of reflected neutrons depends strongly of the construction and composition of the Material. Therefore only meaningful measurements can be made be performed when the count value with a calibration curve the same material structure can be compared. For building floors such a comparison is difficult, however such calibration curves because of the diversity of the multilayer Floors are often not available. Hence this method previously only used for leak detection on flat roofs.

The location of the measurement or sampling is the same as for the known measurement methods arbitrarily. However, one rule becomes followed by everyone: the place should be at least 25 cm from be spaced from each side wall. The usually hydrophilic Construction of the side walls sucks the one lying in the floor Water. Therefore, the opinion is represented in the professional world, that measurements in edge and corner areas become one big falsification of reality.

It is an object of the present invention to provide a method to optimize and control a drying process Water damage in a multi-layer building floor to show that a targeted drying and the Drying times shortened.

This task is solved by a method with the characteristics of Claim 1.

Further advantageous variants of the method can be found in dependent claims.

The method according to the invention uses one described above Neutron probe to get a before the drying process Create damage analysis or at least to the on to determine the most impaired corner of the room. Thereby can spatially the devices necessary for drying be used optimally. Likewise, those for the special Optimal measures taken and the Pressure or vacuum holes are ideally placed. While The drying process is carried out at regular intervals Moisture level of the floor structure on at least one of the Measuring points measured. This determines whether there is still a relevant one Drying progress since the last measurement has been. The time for stopping the measurement can be so can be specifically determined for each case of damage. The Drying times are reduced to what is actually required Dimension shortened. Likewise, the inventive Procedures are immediately determined whether the cause of the Damage has already been remedied or whether, for example, one Line continues to leak. A special feature of the process is that the measurements are contrary to popular opinion all in the corners, near the side walls the most meaningful at these points Measurements are obtained. At these points is usually to expect the highest moisture content.

Figur 1

einen Gebäudeboden im Grundriss mit eingezeichneten Messstellen und

Figur 2

eine graphische Darstellung des Feuchtigkeitsgehaltes des Bodens in Abhängigkeit der Zeit.

The method according to the invention is explained in more detail in the following description and with reference to the drawings. Show it:

Figure 1

a building floor in the floor plan with marked measuring points and

Figure 2

a graphical representation of the moisture content of the soil as a function of time.

The building floors to be renovated are mostly floating floors. The method according to the invention is used a neutron probe to measure the moisture content of the building floor ascertain. Instead of a calibration curve, use this measuring device determines a reference value, which is the normal state of the present soil to be examined. This reference value is determined by in a room without Water damage but with the same multilayer structure of the Soil a measurement is carried out. This room can for example a neighboring room or one above the damaged one Space to be lying space. Instead of this reference measurement can also be done at an earlier time if the structure is known measured, originating from another damage event Reference value can be used.

The extent of the damage is then determined in the room with water damage. At all corners of the room a, b, c, d a moisture measurement is carried out using the neutron probe. The measured values are obtained in an arbitrary unit. A numerical example can be seen in FIG. 1. The corner a with the highest measuring point is now defined as the monitoring point. If necessary, further points in the room can be measured. In this case, a network of measuring points m, p is preferably defined, on the basis of which a damage plan is drawn up. Such a plan is shown in Figure 1. The procedure for drying the floor is decided based on the damage plan or the moisture distribution in the corners of the room.
In another, more refined variant of the method, the measured values are provided with a material-dependent index. This makes sense because the individual side walls can be constructed differently and the side walls influence the moisture content of the corner measuring points. The position of the corners, that is to say whether they are formed by partition walls or by external walls, and, if known, the structure of the side walls is also taken into account. For this purpose, the measured value is multiplied by an independent factor. The measuring point which has the highest measured value after this index correction is taken as the monitoring point.

Known methods are used for the effective drying of the floor and equipment used. One method is to blow in dry compressed air. This method is used when a Damage plan has been drawn up, the moisture distribution is approximately known in the soil. Around the wettest Corners are at the nearest, still dry Place p drying holes. On the wettest A hole is also drilled in corner a. Through the Drilling holes in the dry places is now dry compressed air blown, this air penetrates the floor, takes moisture occurs and emerges as moist air through the bore the wettest corner. The location of the drying well is defined by the damage plan.

Another method that is still little known is this Extraction of the moist air in the floor. Dry Air then flows through the cracks between the floor and the side walls into the different layers of the soil. At This method also dries a hole. This is positioned at the wettest corner a. Through this drying hole, the moisture is now Sucked air. This extraction method has the enormous advantage that targeted removal of the wet air and the existing air moist air not in undefined directions, for example under a facing with an insulating layer or in cavities, is distributed. This is the risk with the pressure drying process.

Regardless of the one used for the drying process Method will be further measurements during the drying process performed with the neutron probe. These measurements are carried out at the monitoring point, i.e. the wettest Room corner a or at the after the index correction wettest measuring point. Further control measurements additional measuring points are possible. All measurements are done at approximately the same time intervals. The measured values be with the reference value of a dry room corresponds, compared. The measured value corresponds approximately to that Reference value or no further drying progress determined, the drying process is stopped. Of the Tolerance value for the comparison of the measured value with the Reference value is about 10%.

Based on the measured values in the area of the wettest corner of the room, a measurement curve is created as a function of time. This serves as a control for the progress of drying and for statistical purposes. The shape of the measurement curve depends on the drying method used. Two typical examples are shown in FIG. 2. The dashed line corresponds to the reference value R. The x-axis corresponds to the time axis in weeks, the y-axis to the measured moisture content in an arbitrary unit. If the drying is carried out by suction, the moisture content in the area of the wettest corner drops very quickly in the first few days and then approaches the reference value R asymptotically. The curve S corresponds to a hyperbola. As soon as the measured value is within the 10% bandwidth T, which is shown in broken lines in FIG. 2, the drying process is ended. In the example shown, this is the case after approximately 3 weeks since the beginning of the drying process.
However, if the drying is carried out by means of bubbles, there is hardly any change in the first few days. After that, however, the moisture content drops more until it approaches the reference value R asymptotically. The curve is designated B in FIG. 2. The criterion for ending the drying process is the same as for the suction process.

Often at every measuring point or at least at the monitoring point carried out several measurements and the statistical Average calculated, taking measurements that are outside of a certain spreading range are neglected will. Experience has shown that the scattering range is the square root of the expected measured value. This averaging is mainly used for small measurements, because there the Measurement accuracy of the device is more important.

The creation of the measurement curve as well as the observation of the Spreading area are important tools for control drying. If there is a deviation from the expected Measured value determined, the cause is to be searched for and closed remedy. For example, the moisture content hardly decreases , it can safely be assumed that either the measures have not been carried out properly, The cause of the damage has not yet been remedied or not known material change in the floor structure is present. A Pipe laid in the floor is still running or water still seeps in from the outside.

Because the drying process through regular measurements is checked, the drying can be stopped immediately if the measured value is up to approximately plus 10% of the measured value of the Corresponds to the reference value. This will lengthen the renovation shortened. The known methods are purely empirical worked and therefore there is always a safety period factored in so that the drying is really sufficient was carried out. In these procedures, a maximum of Finally, a material-destroying control measurement was carried out. This would then also be the point in time when it first started could be determined professionally that the removed Material is dry enough. Based on this sample assumed that the entire area and structure of the Soil has dried.

Claims (8)

1. A method for optimising and controlling a drying process of water damage in a multi-layered building floor, characterised in that

   a) by way of a neutron probe in a room without damage and with the same multi-layered building floor a reference signal is evaluated,

   b) that thereafter in a room with water damage at least all room corners are measured and the corner with the highest reading is defined as a monitoring point,

   c) whereupon the drying process is carried out whilst continuing the measurement in dampest corner in temporally roughly equal intervals,

   d) until the value here has fallen to approximately 10% within the reference value of the dry room or there is effected no more significant drying,

   e) whereupon the drying is stopped.
2. A method according to claim 1, characterised in that the readings evaluated under point b) are provided with a material-dependent index and the measuring location with the highest, index-corrected reading is defined as a monitoring point, whereupon the measurement according to point c) is continued at least at the reading location selected as the monitoring point.
3. A method according to one of the claims 1 or 2, characterised in that at at least one of the measuring points several measurements are carried out and their statistical mean is calculated, wherein values which lie outside a defined scatter reading are disregarded.
4. A method according to one of the claims 1 or 2, characterised in that in the room with water damage a network with measuring points is fixed and on account of the readings at the various measuring points a damage schema is drawn up.
5. A method according to claim 4, characterised in that in the periphery about the dampest corner at the locations which are still dry next to this there are incorporated drying bores.
6. A method according to one of the claims 1 or 2, characterised in that in the dampest room corner there is incorporated a drying bore.
7. A method according to one of claims 1 or 2, characterised in that on account of the measurements in the region of the dampest room corner a measuring curve depending on time is drawn up.
8. The application of the method according to one of the claims 1 or 2, characterised in that it is applied to floating building floors.

Images