WO2015167301A1 - Functional roof structure for preventing collapse of building by snow load - Google Patents

Abstract

The purpose of the present invention is to obtain a roof structure for roof structure heating using a conductive heating film, the roof structure being capable of preventing the loss of many lives resulting from roof collapse due to snow load, and promoting energy reduction and improvement in comfort of indoor living conditions. The present invention is a very useful invention relating to a roof structure which is installed on the roof of a building and consists of a sandwich panel structure having a rectangular shape or an arch shape, the roof structure comprising: a lower bottom metal plate which is installed on the steel beam of the building; a heat insulation material which is installed on the lower bottom metal plate; a conductive heating element which is installed on the heat insulation material; an upper metal plate which is installed on the conductive heating element; and a temperature controller which is connected to the conductive heating element using wire.

Description

Functional Roof Structure to Prevent Building Collapse by Snow Load

The present invention relates to a conductive functional roof structure for preventing the collapse of buildings due to snow load, specifically, to prevent many accidents and property damage due to the collapse caused by snow load, energy saving and indoor housing It relates to a roof structure heating roof structure using a conductive heating element capable of improving the comfort of the environment.

The purpose of the insulation of the building is to keep the indoor temperature of the building comfortable by preventing the warmth of summer and the chill of winter. However, even if the outside air is blocked through the insulation and the room temperature is kept in a comfortable condition, the actual temperature that a person feels may change. The feeling that a person feels hot or cold is not simply caused by room temperature, but by the combined effect of radiant heat and airflow.

In addition to insulation, the most important factor that determines the indoor environment of a building is the heat capacity of the building that determines radiant heat or airflow. A large heat capacity of a building means that it can absorb and store a lot of heat, which can slow down the rapid rise or fall of the room temperature even if the temperature difference between the outside air and the heating / cooling heat source are applied.

There is a big difference in the heat capacity of temporary structures made of corrugated iron and buildings made of concrete. Steel buildings quickly rise when the sun goes down and cool down as the sun goes down, but concrete or stone buildings can prevent the rapid change in room temperature by storing the heat around them. However, high heat capacity does not necessarily create pleasant conditions. If a material with a high heat capacity, such as concrete, absorbs a cold chill in winter, cold radiation can cause a loss of body temperature. Cold radiation refers to the phenomenon that when the temperature drops in the cold winter, the surface temperature of the wall is dropped and the body temperature is deprived of the cold wall. It is the same as the cold and spooky feeling when entering a concrete building in the cold winter. This phenomenon is because the material such as concrete has a high heat capacity, but the heat storage or heat dissipation is linear.

Conventional sandwich panels have a light roof structure and roofs should be supported according to the weight of snow during heavy snowfall in winter. The calculation of the roof structure under the snow load is based on the basic ground snow load, which is a 100-year reproducing cycle.

Heavy snow due to abnormal weather due to environmental pollution and ozone decay can cause the collapse of the roof.

The present invention is to improve the conventional problems by inserting a heating element in the configuration of the sandwich panel in the case of heavy snow melts accumulated on the roof melts snow on the roof to ensure the safety of the roof and building conductive heating element for preventing collapse of the building The purpose is to provide a structure.

Another object of the present invention to provide a conductive heating element roof structure for preventing the collapse of the building due to the snow load to minimize the efficiency and maintenance cost of work during construction.

The present invention is installed on the roof of the building and in the roof structure consisting of a sandwich panel structure of the rectangular form or arch form, the bottom floor iron plate installed on the cheolgolbo of the building; Insulation material is installed on the bottom bottom iron plate; Conductive heating films and other heating elements installed on the insulation; An upper iron plate installed on the conductive heating film and other heating elements; And it relates to a conductive heating film and other heating element roof structure, characterized in that consisting of a temperature controller connected to the conductive heating film and the other heating element by a wire.

The present invention is a very useful invention that has the effect of preventing the safety accident in advance by inserting a heating element in the configuration of the sandwich panel melts snow accumulated on the roof to ensure the safety of the roof and buildings.

1 is a perspective view showing a conductive heating element roof structure for preventing the collapse of the building by the snow load of the preferred embodiment of the present invention.

Figure 2 is an exploded perspective view showing a conductive heating element roof structure of the present invention.

Figure 3 is an exploded cross-sectional view showing a conductive heating element roof structure of the present invention.

Figure 4 is a perspective view showing a conductive heating element roof structure of the present invention.

Figure 5 is an exploded perspective view showing a conductive heating element roof structure of the present invention.

Figure 6 is an exploded cross-sectional view showing a conductive heating element roof structure of the present invention.

Figure 7 is an embodiment showing a conductive heating element roof structure for preventing collapse of the building by the snow load of another embodiment of the present invention.

Hereinafter, a conductive heating element functional roof structure for preventing collapse of a building by snow load in a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

The terms or words used in the specification and claims are not to be construed as limiting in their usual or dictionary meanings, and the inventors are able to properly define the concept of terms in order to best explain their invention in the best way possible. It should be interpreted as meanings and concepts corresponding to the technical spirit of the present invention.

The present invention is installed on the roof of the building and in the roof structure consisting of a sandwich panel structure of the rectangular form or arch form, the bottom floor is installed on the cheolgolbo of the building; Insulation material is installed on the bottom bottom iron plate; A conductive heating element installed on the insulation; An upper plate installed on the conductive guitar heating element; And it is formed as a control unit to control the temperature is connected to the conductive heating element by a wire.

The present invention is installed on the roof of the building and relates to a roof structure consisting of a sandwich panel structure of the rectangular shape as shown in Figs. 1 to 3 or the arch shape as shown in Figs.

1 to 6, the upper steel plate 40 and the lower iron plate 10 in the present invention is preferably 0.1 to 12mm coated molten galvanized steel sheet coated molten zinc plated steel sheet, zinc, aluminum, titanium zinc and other steel sheet surface It is preferable that the treatment is coated with any one of a silicone polyester coating, a polyester resin coating, a silicone resin coating and a fluororesin coating and other coatings. In the present invention, the upper iron plate 40 and the lower iron plate 10 is preferably fixed to the long iron 110, 110-1.

In the present invention, the upper iron plate 40 and the lower iron plate 10 is installed on a steel frame or wooden beam and forms a flat surface without irregularities. In the present invention, the heat insulating material 20 or waterproof sheet is installed on the lower iron plate 10. The part where the waterproof sheet overlaps is joined by heat fusion method.

1 to 6, the heat insulating material 20 in the present invention is preferably used 5mm to 1,200mm polyurethane resin. Insulating material 20 in the present invention is a variety of structures or materials, such as 5mm to 1200mm styrofoam, urethane foam, urea foam and other insulation, and is not limited to a specific structure or material of the material. In the present invention, the conductive heating film (and other heating elements) 30 is preferably used 0.1mm to 1.5mm far infrared film. In the present invention, the conductive heating element 30 preferably uses a moisture penetration prevention film.

In the present invention, it is preferable to use the conductive heating element 30 manufactured by embedding a phase change material (PCM) in the internal and external film materials. The conductive heating element 30 manufactured by incorporating a phase change material (PCM) inside the film material is a liquid phase inside the film material by mixing and embedding the phase change material (PCM). It hardens with an internal and external film material, and becomes a soft sheet form. At this time, the impregnation amount of the phase change material can be adjusted by selecting the formulation according to the purpose of use in the range of 1kg to 3kg per unit area of the nonwoven fabric.

The phase change material used in the conductive heating element 30 of the present invention means a material that stores heat or emits heat as the state of the material changes from solid to liquid or from liquid to solid as the temperature changes. The phase change material exists in the solid state at a temperature lower than the melting point, and when heat energy is applied, the solid state does not change but only the temperature increases. The phase change material exists in the liquid state at a temperature higher than the melting point, and when thermal energy is applied, only the temperature is increased without changing the liquid state. As such, the heat required when the temperature increases is called sensible heat. In addition, the phase change material is a state in which a solid and a liquid coexist at a temperature corresponding to the melting point, and even if thermal energy is applied, this heat is used only for a change of state and no temperature change occurs. This heat is called latent heat. As such, latent heat refers to heat absorbed or released when a state of a substance is transferred. In general, the latent heat is greater than the heat absorbed or released by the temperature change in the absence of phase transition.

Conductive heating element to prevent building collapse due to snow load of the present invention The conductive heating element of the roof structure is a selective power supply switch to supply power to the entire surface or selectively supply power to the entire surface according to the degree of snow accumulation in the control unit And, by installing the eye sensor to detect the height of the accumulated snow on the top of the roof is characterized in that it is formed to automatically supply power to the conductive heating element when the set range or more.

In another embodiment of the present invention, when a lot of snow is accumulated, only a lot of energy is required to melt the snow with heat alone. Also, since the snow can be melted only at the bottom of the stack, a small space can be formed to generate a small vibration or to break the snow. It is necessary to cut the attached eyes. The present invention is a lower surface of the conductive heating element is installed on the insulation

An eccentric shaft 63 in which the diaphragm 61 and the weight 64 are formed, and the vibration member 60 in which the motor 62 and the case 65 were formed are formed.

The vibration member is installed at regular intervals to remove snow by heat and vibration of the heating element.

Claims (3)

1. Installed on the roof of the building, the roof structure consisting of a sandwich panel structure of rectangular or arch shape,

   A bottom floor plate installed on the cheolgolbo of the building;

   Insulation material is installed on the bottom bottom iron plate;

   A conductive heating element installed on the insulation;

   An upper iron plate installed on the conductive heating element; And

   Functional roof structure for preventing the collapse of the building by the snow load, characterized in that the control unit is made to control the temperature is connected to the conductive heating element by a wire.
2. The method of claim 1, wherein the conductive heating element

   Selective power supply switch is formed to supply power to the entire surface or to selectively supply power to each side, and an eye detection sensor that detects the accumulated snow height is installed on the top of the roof to automatically supply power to the conductive heating film when it exceeds the set range. Functional roof structure for preventing collapse of buildings by snow load, characterized in that formed to supply.
3. According to claim 1, Functional roof structure for preventing the collapse of the building by snow load, characterized in that formed on the lower surface of the heating element to be installed on the heat insulator, the vibration member and the vibration member formed in the eccentric shaft and the motor and the case.

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