RU2628530C2 - Method of determination of wall maximum humification localization for analysis of protection against compound building wall excessive moistening - Google Patents

Abstract

FIELD: measuring equipment.

SUBSTANCE: one measures the wall temperature, where the wall outside surface temperature is measured in the capacity of the wall temperature, the interior wall temperature and the temperature among the material layers that form the wall. One also measures the integral outside air temperature for the period with the negative average monthly temperature and the indoor temperature. After that, one draws the polygonal line of the temperature variation across the wall thickness. Afterwards, one compares the temperature value on the boundaries in each of the wall layers with the temperature in maximum humification localization for every wall material layer by virtue of the construction of a temperature curve diagram across the material layer thickness and the temperature graph in maximum humification localization across the material layer thickness. This graph is a horizontal line of a constant temperature across the wall thickness. And if the line of the temperature in maximum humification localization intercrosses the temperature variation across the wall thickness line, then one verifies that the maximum humification localization of the wall material layer passes against the wall through the crossing point of the above-mentioned lines. If there is no maximum humification localization in two neighbouring layers and, at the same time, the maximum humification line in wall material outer layer lies higher than temperature variation line in this layer, the line of the temperature in maximum humification localization in the inner layer lies below the temperature variation line in the inner layer, then one verifies that the wall maximum humification localization centres around the joint of the two layers of this wall. And if the maximum humification localization is not determined in accordance with the two above-stated versions, then one verifies that it is placed along the outer surface of the wall outer layer.

EFFECT: simplification of the analysis of protection against excessive moistening.

4 dwg

Description

The invention relates to methods for assessing the conditions of thermal insulation of walls of buildings and structures, taking into account the degree of their moisture, which changes during the operation of buildings and structures.

There is a method for determining the moisture potential of materials of building envelopes, in which they conduct a test for thermal conductivity, sorption and vapor permeation of the building material under investigation, and determine the moisture potentials by the results of humidity and temperature control and calculate the moisture characteristics of building materials in the humidity potential scale (see copyright certificate SU No. 1157431, class G01N 25/56, publ. 05.23.1985).

However, this method requires a sufficiently large number of measurements and calculations, which complicates its use.

Closest to the invention in technical essence and the achieved result is a method for predicting protection against waterlogging of a multilayer wall of a building, which consists in measuring the temperature of the wall and humidity of the wall using sensors with the transmission of the measurement results to the display (see patent CN No. 105678971, cl. G08B 21/20, publ. 06/15/2016).

This method allows you to monitor the condition of the wall by measuring the temperature of the wall and temperature and humidity. However, the method does not allow to determine the distribution of humidity over the wall thickness, which does not allow prediction of protection against waterlogging of the multilayer walls of the building and, as a result, the possibility of further use of the building with these walls.

The technical problem to be solved in the invention is the solution to the problems of the above technical solutions.

The technical result that is achieved in the invention is to simplify the method for predicting protection against waterlogging of a multilayer wall of a building.

The specified technical problem is solved, and the technical result is achieved due to the fact that the method of determining the location of the plane of maximum wall moisture to predict protection against waterlogging of the multilayer wall of the building is to measure the temperature of the wall, and the temperature of the outer surface of the wall, the temperature the inner surface of the wall and the temperature between the layers of materials forming the wall, and additionally measure the average temperature of the outside air and for a period with a negative average monthly temperature and indoor temperature, then a broken line of temperature change along the wall thickness is built, then the temperature value at the boundaries in each wall layer is compared with the temperature in the plane of maximum moisture for each layer of wall material by plotting the change temperature over the thickness of the material layer and a temperature graph in the plane of maximum moisture over the thickness of the material layer, representing a horizontal line of constant t temperatures along the wall thickness, and if the temperature line in the plane of maximum moisture intersects the line of temperature change along the wall thickness, then it is established that the plane of maximum wetting of the wall material layer passes along the wall through the intersection of the above lines if there is no maximum plane in two adjacent layers humidification and at the same time in the outer layer of the wall material the maximum humidification line lies above the line of temperature change in this layer, in the inner layer the temperature line in the maximum humidity humidification lies below the line of temperature change in the inner layer, then it is established that the maximum wetting wall of the wall lies in the junction plane of two layers of the wall, and if the maximum wetting plane is not defined in accordance with the two above options, then it is established that it is located along the outer surface of the outer layer of the wall.

Energy efficiency is one of the most relevant areas in modern construction. One of the mistakes made during design is the neglect of forecasting the humidity conditions of the building envelope, in particular the walls of the building. This leads to the accumulation of moisture in the thickness of the wall, condensation and the appearance of mold on the inner surface of the wall, cracks in the bearing parts of the structure. Moisture entering the fence greatly affects its thermal regime. Moistening of the material leads to an increase in its coefficient of thermal conductivity, therefore, the heat-shielding qualities of the entire building envelope are reduced, which leads to an increase in the heat loss of the building and the large cost of heat for heating.

Also, the presence of moisture in the building envelope affects the comfortable and hygienic parameters of the microclimate inside the building. A low temperature forms on the inner surfaces of the wall with wet layers, creating an unfavorable radiation environment in the working area of the room. If the temperature on the inner surface of the outer wall is lower than the dew point temperature, this may cause condensation to form. Wet building material is a favorable environment for the emergence and reproduction of microorganisms in it, when inhaled spores of which a person develops allergies and other diseases. The correct protection against moisture of the building envelopes is achieved with the correct calculation of the protection against waterlogging of the building envelopes and the competent organization of ventilation in the premises. And today, the issue of forecasting protection against waterlogging of multilayer walls of buildings is relevant.

This method allows us to simplify and present a comparison in a simple accessible form of the obtained temperature values of maximum humidification with temperatures at the boundaries of the layers of the building envelope.

In FIG. 1 shows a typical construction of an exterior or facade wall of a building.

In FIG. 2 shows a variant of the graphical determination of the position of the plane of maximum humidification by the thickness of the wall of the building.

In FIG. Figure 3 shows a variant of the graphical determination of the position of the maximum moisture plane by the thickness of the two-layer structure of the building wall when the maximum moisture plane is located at the junction with a layer of materials forming the two-layer wall structure.

In FIG. Figure 4 shows a variant of the temperature distribution in a four-layer wall structure corresponding to the position of the maximum humidification plane outside the four-layer wall structure.

The wall structure is a facade composite thermal insulation system (according to GOST R 53786-2010 Composite facade thermal insulation systems with external plaster layers. Terms and definitions; GOST R 53785-2010 composite thermal insulation facade systems with external plaster layers. Classification), consisting of thin external plaster layer, insulation (mineral wool or polystyrene), aerated concrete base, internal cement-sand plaster (Fig. 1)

A typical construction of a multilayer wall consists of an external thin plaster layer 1, insulation 2 (for example, mineral wool or polystyrene), a base of aerated concrete 3, internal cement-sand plaster 4. Position 5 indicates the plane of maximum moisture.

The negative outside air temperature in the drawing is shown by a minus sign, the positive indoor temperature in the drawing is shown by a plus sign, δ _x shows the actual position of the maximum humidification plane from the interface plane of the insulation and the external wall plaster, and δ _ut indicates the thickness of the insulation.

The method of determining the location of the plane of maximum wall moisture to predict protection against waterlogging of a multilayer wall of a building is implemented as follows.

The temperature of the wall is measured, and the temperature of the external surface of the wall (t ₁ ), the temperature of the internal surface of the wall (t ₂ ) and the temperature (t ₃ ) between the layers of the materials forming the wall are measured as the wall temperature, and the average outdoor temperature is additionally measured (indicated by minus) for a period with a negative average monthly temperature and indoor temperature (indicated by a plus sign).

After that, a broken line of temperature change along the wall thickness is built, and then the temperature value at the borders in each of the wall layers (see Fig. 2) is compared with the temperature (t _mu ) in the plane of maximum moisture 5 for each layer of the wall material by plotting the change temperature over the thickness of the material layer and a temperature graph in the plane of maximum moisture over the thickness of the material layer, representing a horizontal line of constant temperature across the wall thickness.

If the temperature line 6 (t _mu ) in the maximum moisture plane 5 intersects the temperature change line 7 along the wall thickness, then it is established that the maximum moisture plane of the wall material layer passes along the wall through the intersection point of the above lines.

If in two adjacent layers (see Fig. 3) there is no maximum moisture plane 5 and at the same time in the outer layer of the wall material the maximum moisture line 8 lies above the temperature change line 9 in this layer, in the inner layer the temperature line 10 in the maximum moisture plane lies below the line 11 of the temperature change in the inner layer, it is established that the plane 5 of maximum wetting of the wall lies in the plane of the junction of two layers of the wall.

If the plane 5 of maximum moisture in accordance with the two above options is not defined, then establish (see Fig. 4) that it is located along the outer surface of the outer layer of the wall.

This method allows us to simplify and present a comparison in a simple accessible form of the obtained temperature values of maximum humidification with temperatures at the boundaries of the layers of the building envelope.

Claims (1)

The method of determining the location of the plane of maximum wall moisture to predict the protection against waterlogging of a multilayer wall of a building, which consists in measuring the temperature of the wall, characterized in that the temperature of the external surface of the wall, the temperature of the internal surface of the wall and the temperature between the layers of materials forming wall, and additionally measure the average temperature of the outside air for a period with a negative average monthly temperature and the inside temperature and premises, after that they build a broken line of temperature change along the wall thickness, and then compare the temperature value at the boundaries in each wall layer with the temperature in the plane of maximum moisture for each layer of wall material by plotting a temperature change over the thickness of the material layer and a temperature graph in plane of maximum moisture in the thickness of the layer of material representing a horizontal line of constant temperature along the wall thickness, and if the temperature line in the plane of maximum If humidification crosses the line of temperature change along the wall thickness, then it is established that the plane of maximum wetting of the wall material layer passes along the wall through the intersection point of the above lines, if the plane of maximum moisture is absent in two adjacent layers and the maximum humidification lies above the line of temperature in this layer, in the inner layer the temperature line in the plane of maximum humidification lies below the line of temperature in morning layer, establish that the plane of maximum dampening walls lies in the plane of the junction of the two layers of the wall, and if the maximum humidification plane according to the two preceding embodiments is not defined, the state that it is located along the outer surface of the outer wall layer.

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