RU2558874C1 - Three-layered resource-saving reinforced-concrete panel - Google Patents

Abstract

FIELD: construction.

SUBSTANCE: three-layered reinforced-concrete panel includes a heat-insulating layer, external and internal reinforced-concrete layers connected to each other with stiff braces and made in the form of reinforced concrete keys passing through the heat-insulating layer, and reinforced concrete ribs arranged along the perimeter of the panel; in addition, it is provided with at least two reinforced concrete keys that are arranged on opposite end faces of the panel, and the reinforced concrete ribs in the cross-section parallel to panel layers have the surface area determined from the ration of panel thickness, thickness of its middle layer, heat conductivity coefficients of rib materials, panel layers, reinforcement bars and warmth-keeping material, as well as the required resistance of heat transfer; with that, heat conductivity coefficient of material of the reinforced concrete keys passing through the heat-insulating layer exceeds by 2.5-3 times the heat conductivity coefficient of material of the reinforced concrete keys arranged on opposite end faces of the panel. The heat-insulating layer is made from thin-fibre material and located in the form of twisted bundles longitudinally elongated throughout the panel length.

EFFECT: providing energy-saving operating conditions of industrial buildings and structures, especially under conditions of negative ambient air temperatures.

2 dwg

Description

The invention relates to the construction, in particular to the enclosing structures of industrial buildings.

The well-known three-layer reinforced concrete panel (see RF patent No. 2274714, IPC Е04С 2/00, published on 04/20/2006), including a heat-insulating layer, outer and inner reinforced concrete layers interconnected by rigid bonds made in the form of reinforced concrete dowels passing through the heat-insulating layer and reinforced concrete ribs placed around the perimeter of the panel are additionally equipped with at least two reinforced concrete dowels, which are placed on opposite ends of the panel, and reinforced concrete ribs in section, pa parallel to the panel layers, have an area determined from the ratio of the panel area, the thickness of its middle layer, the coefficients of thermal conductivity of the rib materials, panel layers, reinforcement and insulation, as well as the required heat transfer resistance.

The disadvantage is the reduction of the thermal properties of a three-layer reinforced concrete panel, especially in the autumn-winter and winter-spring periods of operation, due to various periodic ambient temperature fluctuations during the day, which leads to additional heat loss through reinforced concrete dowels passing both through the heat-insulating layer and placed on the ends of the panel.

Known three-layer reinforced concrete panel (see patent No. 2398078, IPC Е04С 2/06, publ. 08/27/2010), comprising a heat-insulating layer, outer and inner reinforced concrete layers interconnected by rigid bonds made in the form of reinforced concrete dowels passing through the heat-insulating layer, and reinforced concrete ribs placed around the perimeter of the panel, is additionally equipped with at least two reinforced concrete dowels, which are placed on opposite ends of the panel, and reinforced concrete ribs in section, steam -parallel layers of the panel have an area defined by the area ratio of the panel, the thickness of its middle layer, thermal conductivity of materials ribs, layers of panel reinforcement and insulation, as well as the required heat resistance. In this case, the coefficient of thermal conductivity of the material of reinforced concrete dowels passing through the heat-insulating layer is 2.5-3 times higher than the coefficient of thermal conductivity of the material of reinforced concrete dowels located on opposite ends of the panel.

The disadvantage is the loss of heat through the insulating layer with a daily change in ambient air temperature, especially with its negative values and the presence of solar radiation.

The technical task of the invention is the creation of resource-saving properties of a three-layer reinforced concrete panel in the changing temperature conditions of operation of the building envelope.

The technical result of providing energy-saving operating conditions for industrial buildings and structures, especially in conditions of negative ambient temperatures, is achieved by the fact that the three-layer reinforced concrete panel includes a heat-insulating layer, the outer and inner reinforced concrete layers interconnected by rigid bonds made in the form of reinforced concrete dowels, passing through the heat-insulating layer, and reinforced concrete ribs placed around the perimeter of the panel, is additionally equipped with at least m Here, two reinforced concrete dowels, which are placed on opposite ends of the panel, and reinforced concrete ribs in a section parallel to the panel layers, have an area determined from the ratio of the panel area, the thickness of its middle layer, the thermal conductivity of the rib materials, panel layers, reinforcement and insulation as well as the required heat transfer resistance. In this case, the thermal conductivity of the material of the reinforced concrete keys passing through the heat-insulating layer is 2.5-3 times higher than the coefficient of thermal conductivity of the material of the reinforced concrete keys placed on opposite ends of the panel, while the thermal insulation layer is made of fine fiber material and is arranged in the form of twisted longitudinally elongated along the length of the panel of beams.

In FIG. 1 shows a general view of a three-layer reinforced concrete panel with partial cuts, in FIG. 2 - distribution of temperature and thermal fields in the contact areas of the dowels both at the end of the panel and in the insulating layer of the panel.

The three-layer reinforced concrete panel includes the outer 1 and inner 2 reinforced concrete layers and the middle heat-insulating layer 3. The outer 1 and inner 2 reinforced concrete layers are connected by rigid bonds made in the form of reinforced concrete keys 4 passing through the heat-insulating layer 3 and reinforced concrete keys 5 that are placed at opposite ends of the panel. The total number of reinforced concrete keys 4 and 5 is determined by calculation, while the number of keys 5 must be at least two. The outer 1 and inner 2 reinforced concrete layers are also connected by reinforced concrete ribs 6, which have an area determined from the ratio of the area of the panel, the thickness of its middle layer, the thermal conductivity of the materials of the ribs, the layers of the panel, reinforcement and insulation, as well as the required heat transfer resistance. The ribs 6 are placed around the entire perimeter of the panel and seal the space between the layers 1 and 2, thereby protecting the heat-insulating layer 3 from mechanical damage and weathering during storage, transportation and installation of the panel. In this case, the material of the reinforced concrete keys 4 passing through the heat-insulating layer 3 has a thermal conductivity coefficient 2.5-3 times higher than the thermal conductivity coefficient of the reinforced concrete keys 5 placed on opposite ends of the panel. The heat-insulating layer 3 is made of fine-fiber basalt material 7 and is located in the form of twisted beams longitudinally elongated along the length of the panel 8.

Resource-saving properties of the proposed reinforced concrete panel according to the invention under operating conditions under varying environmental temperature effects are manifested as follows.

The impact of daily changes in the air temperature of the surrounding building environment leads to the cyclical effect of heat fluxes from the outer 1 and inner 2 layers to the insulating layer 3, while the insulating layer 3, performing the main function of eliminating the passage of heat flux, prevents the transfer of heat from both the inner 2 layers to the outer 1 layer, and vice versa, including the presence of a higher temperature, for example, under the influence of solar radiation, the surface of the outer layer 1 in comparison with the inner surface layer inner layer 2 heated room at low temperatures of the ambient air. Consequently, the energy intensity of the heated building is due to the maximum required resource consumption for the high-temperature energy carrier of the heating system that supports the calculated microclimate parameters in the room under the condition of heat losses through the external fencing - three-layer reinforced concrete panels (see, for example, SNiP 2.04.05-91 Heating, ventilation, air conditioning M.: Stroyizdat, 1997).

To reduce resource costs for the production, transportation and consumption of high-temperature (90-150 ° С) coolant used in the heating system of a building (see, for example, SNiP 2.04.07-86 Heating networks. M.: Stroyizdat, 1987 (amended from 04.21.94 g.)), The heat-insulating layer 3 is made of fine-fiber basalt material 7 located in the form of twisted beams longitudinally elongated along the panel 8. Then, in the daytime in the presence of solar radiation with negative ambient temperatures, the surface of the outer 1 layer is warm conductivity transfers heat to the thin fibrous basalt material 7 of the heat-insulating layer 3, and due to the fact that the thin fibrous basalt material 7 is arranged in the form of twisted bundles 8 longitudinally elongated along the panel length, thermal energy is accumulated over the thickness of the heat-insulating layer 3 (see, for example, fibrous materials from basalts. Ukraine, publ. "Technique" Kiev, 1971-76 with ill.).

In the absence of solar radiation and / or at night, the heat accumulated in the heat-insulating layer 3 passes through the inner 2 layer into the heated room, maintaining the microclimate parameters in it, which reduces the consumption of high-temperature coolant in the heating system.

In the daytime during the heating period of operation of the building, thermal energy from a heat exchanger, mainly located near the external fence, for example from three-layer reinforced concrete panels, along with the heating of the indoor air, is transferred to the inner layer 2 and then to the insulating layer 3, where it is accumulated on twisted longitudinally elongated beams 8 of thin-fiber basalt material 7, virtually eliminating the flow of heat into the outer layer 1.

The thermal energy accumulated by accumulating in the heat-insulating layer 3 at the coming night time, when the normalized temperature of the internal air is allowed to decrease due to the reduction in the consumption of the high-temperature coolant of the heating system, especially in offices and industrial buildings due to the reduction in the presence of people or their complete absence, is transferred to the thermal conductivity through the inner layer 2 into the room. The result is a resource-efficient operation of the building. Therefore, the implementation of the heat-insulating layer 2 of fine-fibrous basalt material 7 in the form of twisted longitudinally elongated bundles 8 provides not only protection from heat loss, but also the maintenance of a normalized temperature regime in the building due to heat transfer, which was accumulated and subsequently transferred to the internal air of the heated room .

At negative ambient temperatures, reinforced concrete ribs of a certain thickness represent additional “cold bridges”, and eliminating this phenomenon by reducing the thickness of reinforced concrete ribs around the panel perimeter (according to the prototype), of course, reduces heat loss. But not always justified in terms of strength design parameters.

The implementation of reinforced concrete dowels placed on opposite ends of the panel from a material with a thermal conductivity coefficient 2.5-3 times less than the thermal conductivity coefficient of the material of reinforced concrete dowels passing through the heat-insulating layer leads to local redistribution of temperature and thermal fields at the contact points of the concrete dowels with the main material of the three-layer panel. The temperature field of the external environment with a minus temperature affects the reinforced concrete key at the end of the panel and the temperature field of the internal with a minus ambient temperature (for example, the location of the panel as a building floor) with a temperature gradient of various (up to three times) intensities due to the thermal conductivity of the corresponding materials. As a result, in the contact point (Fig. 1) for the end of the panel, where the appearance of “cold bridges” is possible, a temperature-thermal boundary layer is formed (see, for example, pp. 68-77. Isachenko VP and other Heat Transfer. M .: Energoizdat, 1981, 416 pp., Ill.), Caused by the opposite direction of the temperature gradients (grad t) of the external environment and the heat dissipation flux (g _races ), which determine the heat loss of the panel from the internal environment, for example, room heat when using panels as a building floor. In this case, the thickness of the temperature-thermal boundary layer increases with a periodically varying change in ambient air temperature from minus to zero and even plus during the day. At the same time, at the contact point of the reinforced concrete dowels passing through the heat-insulating layer, a thermal-thermal boundary layer is also formed, which ensures the dissipation of the heat flux, which determines heat losses both in the outer and inner reinforced concrete layer, and in the heat-insulating layer, but with the value of temperature gradients three times less than for external conditions.

As a result of the presence of local zones (reinforcement of concrete dowels at the ends of the panel and in the insulating layer), the redistribution of temperature and thermal fields provides an increase in the thermal properties of the three-layer reinforced concrete panel as a whole.

The originality of the invention lies in the fact that in a three-layer reinforced concrete panel, the heat-insulating layer is made of fine fiber material and is located in the form of twisted beams longitudinally elongated along the panel length, which ensures resource-saving operation of the building by energy-saving use of a high-temperature coolant of the heating system due to not only eliminating heat losses from the outside fences, but also the maintenance of normalized temperature conditions indoors due to e accumulation of thermal energy and its subsequent return to a heated room.

Claims (1)

A three-layer reinforced concrete panel including a heat-insulating layer, outer and inner reinforced concrete layers interconnected by rigid bonds, made in the form of reinforced concrete dowels passing through the heat-insulating layer, and reinforced concrete ribs placed around the perimeter of the panel, is additionally equipped with at least two reinforced concrete dowels, which are placed on opposite ends of the panel, and reinforced concrete ribs in a section parallel to the panel layers, have an area determined from the ratio of the area of the panel, the thickness of its middle layer, the coefficients of thermal conductivity of the materials of the ribs, the layers of the panel, reinforcement and insulation, as well as the required resistance to heat transfer, while the coefficient of thermal conductivity of the material of the reinforced concrete dowels passing through the thermal insulation layer is 2.5-3 times higher than the coefficient thermal conductivity of the material of reinforced concrete dowels placed on opposite ends of the panel, characterized in that the heat-insulating layer is made of fine-fiber material and is distributed false twisted in the form of elongated longitudinally along the length of the beams panel.

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