RU2641059C2 - Method for increasing thermotechnical homogeneity of three-layer building envelope and device for its implementation - Google Patents

Abstract

FIELD: construction.

SUBSTANCE: in order to prevent undesirable heat flow through the key, the key is heated at the junction of the key to the inner carrier layer by a power corresponding to the heat flow passing through the key. A device for the method implementation is also described, characterized in that a heating element is arranged at the junction of the key to the inner carrier layer, for example, with an electrical power equal to the design value of the maximum heat flow connected to a controller controlling its power which is connected to temperature sensors, one of which is installed in the area of the key location, and the other one is installed in a thermotechnically homogeneous area, half the distance to the adjacent key.

EFFECT: increased thermotechnical homogeneity.

3 cl, 6 dwg

Description

The invention relates to the field of construction and relates to the thermal efficiency of the building envelope (external wall).

Currently, more and more attention is paid to energy conservation in construction. Multilayer, in particular three-layer, external building envelopes are widespread.

For example, the design of OAO "DSK-1" is known, containing the inner and outer reinforced concrete layers and the thermal insulation layer located between them, while the inner and outer layers are interconnected by reinforced concrete dowels, a fragment of which is shown in the photograph of figure 1.

The disadvantage of this design is the undesirable heat fluxes between the outer and inner layers passing through the keys, which affects the thermal characteristics of the structure, its resistance to heat transfer and heat engineering uniformity.

The figure 2 shows a thermogram of the inner surface of a three-layer reinforced concrete panel, on which there is a temperature drop caused by the key.

According to GOST 31310-2005 “Three-layer reinforced concrete wall panels with effective insulation”, the nominal dimensions of reinforced concrete lintels (keys) should be taken at least 60 mm. In this case, it is recommended to comply with the condition according to which the value of the coefficient of heat engineering uniformity of the panels, determined in accordance with SP 23-101-2004 "Design of thermal protection of buildings" and taken into account in the calculation of heat transfer resistance, should be at least 0.6.

The authors performed mathematical modeling of the thermal state of a typical three-layer structure of the following parameters.

The outer layer of reinforced concrete is 0.07 m thick, the inner one is 0.1 m thick. The insulation layer (expanded polystyrene with a thermal conductivity coefficient of 0.039 W / mK) is 0.15 m thick. The reinforced concrete key is 0.06 m thick, one per 1 m ^{2 of} wall.

The simulation results show that the heat transfer resistance of this design without taking into account the heat flux along the keys is R _O = 4.09 m ² K / W.

The dowel is a heat-conducting inclusion (“cold bridge”) and reduces the heat transfer resistance to R _O = 2.18 m ² K / W, then the coefficient of heat engineering uniformity r = 2.18 / 4.09 = 0.53, which is less than the value of this quantities regulated by GOST 31310-2005.

The results of mathematical modeling of the distribution of temperature fields in a model of a three-layer panel design are presented in figure 3.

There is also a technical solution according to the USSR author's certificate No. 1392225, according to which, in accordance with the description, “a predetermined temperature on the inner surface of the panel” is provided.

However, this technical solution, based on increasing the contact area of the dowel and the inner layer of the three-layer panel, only leads to a certain decrease in the heat flux density and a corresponding increase in temperature on the inner surface of the panel, which contributes to a certain increase in the coefficient of thermal engineering uniformity.

The results of mathematical modeling of this technical solution show that it leads to a decrease in the density of the heat flux passing through the key and to an increase in the coefficient of heat engineering uniformity by no more than 9%.

A method is proposed for increasing thermotechnical homogeneity, namely, in order to prevent heat flow along the key, at the point where the key adjoins the internal bearing layer, the key is heated with a power corresponding to the heat flux passing through the key.

The authors performed two-dimensional mathematical modeling of the proposed technical solution.

The results show that when the heater power is 30 W, the heat transfer resistance on the inner surface of the sample is R _O = 4.01 m ² K / W, the coefficient of heat engineering uniformity r = 4.01 / 4.09 = 0.98, which exceeds the normalized index.

In a graphical form, the results of mathematical modeling of the distribution of temperature fields in a model of a three-layer reinforced concrete panel with a heater are presented in figure 4.

Since the temperature difference between the inner and outer walls of the enclosure changes during operation depending on the ambient temperature, in order to save energy, the heating power of the dowel is regulated to minimize the temperature difference in the area where the dowel is located and outside the area of the thermal effect of the dowel.

A device for implementing the method consists in the fact that at the junction of the dowel to the inner bearing layer there is a heating element, for example, an electric one, with a power equal to the design value of the maximum heat flux, connected to a controller controlling its power, which is connected to temperature sensors, one of which installed in the area of the dowel, and the other in a thermotechnically homogeneous area, half the distance to the adjacent dowel.

The device is illustrated in figure 5.

The three-layer enclosing structure, consisting of the outer 1 and inner 2 bearing layers connected by a key 3, with a thermal insulation layer 4 located between them is equipped with a heater 5, for example, an electric one, connected to a controller 6, to which, in turn, temperature sensors 7 are connected and 8, installed on the inner surface of the inner carrier layer, one of which is located in the area of the dowel 3, and the other halfway to the adjacent dowel.

The device operates as follows.

When the controller 6 is turned on, the latter begins to measure the temperature difference between the readings of the sensor 7 (colder) and the sensor 8. If the difference in the readings is outside the specified range, the heater 5 is turned on at minimum power, and the controller increases its power until the temperature difference the readings of sensors 7 and 8 will not decrease to the specified setting, after which the controller records the achieved power. If, due to a change in the temperature of the outdoor air, the heat flow along the key changes, and the temperature difference, according to the readings of the sensors 7 and 8, is outside the specified range, the controller 6 accordingly changes the power of the heater 5 (increases or decreases depending on the nature of the change in the temperature of the outdoor air) .

The figure 6 shows the calculated confirmation of the efficiency of the heater in the form of graphs of the temperature on the inner surface of the panel in the area of the dowel and the heat flux density at different values of the heater power, controlled by the controller according to the temperature difference between the two sensors.

The proposed technical solution prevents the heat flow from the warm side and allows to achieve a high degree of thermotechnical uniformity of the building envelope.

Claims (3)

1. A method of increasing the heat engineering uniformity of a three-layer building envelope containing internal and external load-bearing layers with a layer of thermal insulation located between them, interconnected by discretely arranged fasteners - dowels, characterized in that the dowels are heated at the junction of the dowel with the internal load-bearing layer power corresponding to the heat flux along the key. 2. The method according to p. 1, characterized in that the regulation of the heating power is carried out according to the temperature difference in the area of the dowel and outside the heat affected zone of the dowel. 3. A device for implementing the method according to PP. 1 and 2, characterized in that at the junction of the dowel to the inner bearing layer there is a heating element, for example, an electric power equal to the calculated value of the maximum heat flux through the dowel, connected to the control power of the heater by a controller that is connected to temperature sensors, one of which installed in the area of the dowel, and the other halfway to the adjacent dowel.

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