TWM504115U - Breathable heat conduction roof - Google Patents

Description

Breathable and thermally conductive roof

The present invention relates to a roof, and more particularly to a roof that is permeable and thermally conductive.

Referring to FIG. 1, the roof of a conventional iron house includes a metal sheet 11, a heat insulation panel 12, and a plurality of beads 13 disposed between the iron sheet 11 and the heat insulation panel 12.

Since the outer layer of the conventional roof is made of metal directly, when the sun shines during the day, it will cause a large amount of "radiation heat" to penetrate the iron sheet 11. In addition, the metal material easily absorbs the ambient heat energy, so that the heat inside the iron house accumulates, although it has been set. The heat shield 12, but the actual indoor temperature is still too high and the occupants are uncomfortable.

Accordingly, it is an object of the present invention to provide a ventilated and thermally conductive roof that is permeable to radiant heat.

Therefore, the novel breathable and heat-conductive roof comprises a concave plate and a plurality of outer plates.

The embossed plate has a concave-convex shape, and the grooves on both sides thereof extend in a first direction.

The outer plates are laid apart from each other on the outer side of the uneven plate.

The effect of the novel is that the radiant heat of the sunlight is prevented by the outer plate, so that the embossed plate can be prevented from being directly heated by the sunlight, and the outer side of the louver plate provides a passage for gas circulation, which can take away excess heat energy. In order to slow down the temperature rise in the room, further, by the gap between the outer plates, the passage of the evaporation evaporation of the embossed plate can be provided, and the problem of rust corrosion of the embossed plate can be alleviated.

2‧‧‧ embossed plate

21‧‧‧ Groove

3‧‧‧Outer board

4‧‧‧Pressing

5‧‧‧ Thermal insulation board

6‧‧‧Insulation

L‧‧‧First direction

Other features and effects of the present invention will be apparent from the following description of the drawings, wherein: FIG. 1 is a schematic view of a roof of a conventional iron house; FIG. 2 is an embodiment of a novel gas permeable and heat-resistant roof. FIG. 3 is a longitudinal cross-sectional view of the embodiment; and FIG. 4 is a cross-sectional view of the embodiment.

Referring to Figures 2, 3 and 4, the embodiment of the novel ventilating and heat-conducting roof comprises a embossing plate 2, a plurality of outer plates 3, a plurality of embossing strips 4, a heat insulating plate 5, and a heat insulating material 6.

The embossing plate 2 has a concave-convex shape, and the grooves 21 on both sides thereof extend in a first direction L. The embossing plate 2 is inclined, and the first direction L is not horizontal, and the embossing plate 2 is on the outer side thereof. The depth to width ratio of the groove 21 (i.e., h:d in Fig. 4) is not less than 1:4, preferably 7:22.

In the embodiment, the embossing plate 2 is made of steel, but an aluminum plate with better heat dissipation effect or a multi-layer plate with better air permeability can be used, and the suitable material can be adjusted according to the actual climatic characteristics of the application place, and Not limited to this.

The outer plates 3 are spaced apart from each other on the outer side of the embossing plate 2, and the outer plates 3 have substantially the same inclination angle to the embossing plate 2, wherein the outer plates 3 have a gap of more than 2 cm therebetween, and The outer plate 33 is preferably a wood ore plate because the wood plate has an excellent radiant heat resistance.

The bead 4 is disposed between the uneven plate 2 and the outer plate 3 for separating the uneven plate 2 and the outer plate 3 from each other.

The heat shield 5 is disposed inside the uneven plate 2.

The heat insulating material 6 is filled between the uneven plate 2 and the heat insulating plate 5.

Through the above description, the advantages of the embodiment can be summarized as follows: 1. By arranging the outer panel 3 on the outer side of the embossing plate 2, the radiant heat of the sunlight can be isolated by the air under the outer panel 3 and the outer panel 3. The embossing plate 2 is prevented from being directly heated by the sunlight, and the gas passage is provided by the groove 21 on the outer side of the embossing plate 2, so that cold air can enter from the lower end of the groove 21, and the concave louver 2 is absorbed. The thermal energy then flows upward along the grooves 21 through the upper ends of the grooves 21 to take away the heat energy of the embossed plate 2, so that not only the radiant heat can be avoided but also the heat accumulation in the room can be avoided, and the gas can also be used. The circulation removes excess heat, thus slowing the indoor temperature rise and increasing the comfort of the occupants.

Furthermore, by designing the outer plates 3 to be spaced apart from each other, a passage for moisture evaporation can be provided, whereby the remaining moisture on the embossed plate 2 can pass through the outer plates after the rain Since the gap of 3 is evaporating and escaping, the moisture does not remain on the embossed plate 2, causing the rust plate 2 to rust and erode.

2. By designing the embossed plate 2 as the groove 21 on the outer side thereof, the depth to width ratio is not less than 1:4, whereby the space in which the gas flows in the grooves 21 can be increased to increase the gas convection. The effect of heat.

3. By providing the heat insulating plate 5 and filling the heat insulating material 6 between the uneven plate 2 and the heat insulating plate 5, the heat insulating effect can be enhanced to reduce the temperature rise in the room.

In summary, it is indeed possible to achieve the purpose of the novel.

However, the above description is only for the embodiments of the present invention, and the scope of the present invention cannot be limited thereto, that is, the simple equivalent changes and modifications made by the present patent application scope and the contents of the patent specification are still It is within the scope of this new patent.

2‧‧‧ embossed plate

21‧‧‧ Groove

3‧‧‧Outer board

4‧‧‧Pressing

L‧‧‧First direction

Claims (9)

The utility model relates to a ventilating and heat-conducting roof, comprising: a concave-convex plate which is arranged in an undulating wave shape and is inclined, wherein the grooves on both sides extend in a first direction, the first direction is not horizontal; and the plurality of outer plates are spaced apart from each other Laid on the outside of the embossed plate. The permeable and heat-conductive roof according to claim 1, wherein the outer plates are inclined at substantially the same angle as the embossed plate. The permeable and heat-conductive roof according to claim 1, wherein the outer plates have a gap of more than 2 cm from each other. The permeable and heat-conductive roof according to claim 1, wherein the groove of the uneven plate has a depth to width ratio of not less than 1:4. The ventilating and heat-conducting roof according to claim 1, further comprising a plurality of beadings disposed between the embossing plate and the outer plate, wherein the embossing strips are used to separate the embossing plate and the outer plate from the gap. The permeable and heat-conductive roof according to claim 1, further comprising a heat shield disposed on the inner side of the embossing plate. The permeable and heat-conductive roof according to claim 6, further comprising a heat insulating material filled between the embossed plate and the heat insulating plate. The permeable and heat-conductive roof of claim 1, wherein the outer panels are wood ore plates. The permeable and heat-conductive roof according to claim 1, wherein the embossing plate is made of steel.