KR101067871B1 - tiled roof assembly having solar cell panel - Google Patents

Abstract

The present invention relates to a tile roof assembly, according to an aspect of the present invention tile roof formed with eaves used in traditional hanok; And a photovoltaic roof assembly comprising a photovoltaic device which is coupled to an end of the eave and photovoltaic and can be an extension of the eave.

Traditional Hanok, Roof Tiles, Solar Power

Description

Tiled roof assembly {tiled roof assembly having solar cell panel}

The present invention relates to a tile roof assembly, and more particularly, a photovoltaic device may be formed on a roof formed with a cornice, so that an antique image of a traditional hanok and a modern image of the photovoltaic device may be mixed. The present invention relates to a tiled roof assembly that allows a photovoltaic device to be stored and taken out to maintain the aesthetics of a traditional hanok.

Traditional Hanok, our old building that has developed through a long history, is now mostly used as a cultural resource. The role of the traditional hanok, which was used as a living and living space, has been designated as a cultural property.

In order to preserve the traditional part as much as possible, such traditional hanok is to preserve not only the traditional hanok itself but also the surrounding environment and facilities as the existing phenomenon.

However, maintaining traditional hanok and surrounding facilities as they are is not the best preservation method for cultural heritage.In order to expand the scope of use and add value as cultural resources, modern air-conditioning systems, air-conditioning and heating facilities, lighting facilities, etc. Technical skills need to be added and complemented.

Recently, many new types of traditional hanok, which combines the advantages of traditional hanok with the convenience of modern life, are also being introduced, and these buildings are used in various places such as general residential spaces, restaurants, and accommodations.

In order to operate modern facilities and equipment used in traditional hanok, power supply is required, and as the energy source, the present invention provides a tiled roof made to harmonize solar power generation, which is an environmentally friendly alternative energy source, with traditional hanok. I would like to.

The present invention has been made in view of the above-described point, an embodiment of the present invention is installed on the roof tile of the traditional hanok with eaves made to supply power to the traditional hanok, and the shape of the roof tile It is also associated with being constructed so as not to harm the aesthetics of traditional Hanok.

One preferred embodiment of the present invention is a roof tile formed with eaves used in traditional hanok; And a photovoltaic roof assembly comprising a photovoltaic device which is coupled to an end of the eave and photovoltaic and can be an extension of the eave.

According to an embodiment of the present invention as described above, first, a photovoltaic device may be formed at the end of the roof where the eaves are formed so that the photovoltaic device may be used in combination with the eaves.

Second, the photovoltaic device is coupled to the back of the eaves to be drawn out, so that the photovoltaic device is not exposed to the outside when the photovoltaic device is not in use.

Third, the solar panel can be formed to be rotatable to enable efficient solar power generation.

1 is a perspective view showing a tile roof assembly according to an embodiment of the present invention.

Tile roof assembly (1) according to a preferred embodiment of the present invention is a tile roof (10) formed with a cornice 11 used in traditional hanok; And a photovoltaic device 20 that is coupled to the end of the eaves 11 to generate photovoltaic power and may be an extension of the eaves 11.

The present invention allows the photovoltaic device 20 to be coupled to the roof of a traditional hanok. However, unlike the conventional solar power panel which is formed separately from the roof on the roof of the building to supply hot water, the photovoltaic device 20 in the present invention is the end of the eave 11 Coupled to the eaves 11 to form an extension.

The photovoltaic device 20 is formed in the form of a wide plate as a whole, the appearance exposed from the outside, is made to be in harmony with the eaves (11). The photovoltaic device 20 refers to a power generation device that obtains electricity using photovoltaic power generation, a technology for directly converting sunlight into electrical energy.

The photovoltaic device 20 may be integrally formed as a single device, but may be configured in such a manner that a plurality of the photovoltaic devices 20 are continuously arranged according to the size and shape of the roof.

By using the morphological characteristics of the photovoltaic device 20 is a state-of-the-art technology is installed on the roof of the traditional hanok, in particular in the form extending from the end of the eaves (11) The modern image of the photovoltaic device 20 can be combined to bring about a unique aesthetic.

In addition, the photovoltaic device 20 may be used as an extension of the eaves 11, and accordingly, a wider shade may be formed at the same time as photovoltaic power generation.

In the case of a traditional hanok in a region where it is difficult to supply power, the utility of the photovoltaic device 20 may be greater in the case of a traditional hanok that requires only a small amount of electric power.

Figure 2 (a) is a perspective view showing a photovoltaic device used in the tile roof assembly according to another embodiment of the present invention.

In addition, Figure 2 (b) and Figure 2 (c) is a perspective view of the photovoltaic device used in the tile roof assembly according to another embodiment of the present invention, which will be described later.

In the tiled roof assembly (1) according to the preferred embodiment of the present invention, the photovoltaic device (20), the bracket 21 is coupled to the eaves (11), the coupling frame is slidingly coupled to the bracket 21 And a first solar panel 23 coupled to the coupling frame 22.

The bracket 21 is configured to couple the photovoltaic device 20 to the cornice 11 and is fixedly coupled to the cornice 11. The bracket 21 is formed to accommodate and withdraw the coupling frame 22 and the first solar panel 23. Since the first solar panel 23 is formed of a rectangular panel as described below, the bracket 21 accommodating the first solar panel 23 is preferably formed in a rectangular frame shape. However, the coupling frame 22 is formed in an open shape in a sliding direction so as not to interfere with the sliding of the first solar panel 23.

The bracket 21 is formed to surround a part of the coupling frame 22. The inner surface of the bracket 21 is preferably formed with a guide groove or guide protrusion for sliding the coupling frame 22, in this case the outer surface of the coupling frame 22 to the guide groove or guide protrusion A corresponding guide protrusion or guide groove is formed. In FIG. 2 (a), both end portions of the coupling frame 22 are inserted into the guide grooves formed on both sides of the bracket 21 to slide.

The coupling frame 22 is slid on the bracket 21 and is housed in the bracket 21 and made to be withdrawn. As shown in Figure 2 (a), the end portion of each of the first link arm (L1) and the second link arm (L2) are rotatably coupled to each other in the bracket (21) and the coupling frame (22). It is coupled to be possible, it is made to slide by the rotation of the first link arm (L1), the second link arm (L2). The drive unit M (including the motor) operated by the control unit C rotates the first link arm L1, and the second link arm L2 connected to the driving unit 22 rotates the coupling frame 22. It is possible to slide on the bracket 21.

The coupling frame 22 has a form surrounding a part of the edge of the first solar panel 23 and is coupled to the edge of the first solar panel 23. The first solar panel 23 is slidable on the bracket 21 by the coupling frame 22.

The first solar panel 23 is a photovoltaic power generation, is formed by combining a conventional solar cell module, and is a part forming the core of the photovoltaic device (20). The first solar panel 23 is preferably formed in the form of a square panel so as to harmonize well with the shape of the roof tile (10). Storage batteries (not shown) and power converters (not shown) required for solar power generation is to be installed under the roof or inside the building.

3 (a) to 3 (c) is a state diagram showing the roof tile assembly in which the photovoltaic device shown in Figures 2 (b) and (c) is used.

In the tiled roof assembly 1 according to the preferred embodiment of the present invention, the bracket 21 is coupled to the back surface of the cornice 11 so that the photovoltaic device 20 is covered by the cornice 11. The coupling frame 22 and the first solar panel 23 are configured to be accommodated in the bracket 21.

The photovoltaic device 20 is coupled to the rear surface of the cornice 11 is covered by the cornice 11 when not in use. It may be necessary to expose only the unique shape of the traditional hanok, or it may be necessary to protect against the risk of damage that may occur due to the photovoltaic device 20 being exposed to the outside. This can be achieved by covering the photovoltaic device 20 under the eaves 11.

The bracket 21 is coupled to the rear surface of the cornice 11, and deep enough to be coupled inward so that the photovoltaic device 20 is covered by the cornice (11). In this case, the coupling frame 22 and the first solar panel 23 are completely accommodated in the bracket 21.

As shown in FIG. 3 (a), the photovoltaic device 20 has an end portion thereof in a state in which the coupling frame 22 and the first solar panel 23 are accommodated in the bracket 21. It is preferable to form so that it enters a little more than the end of the eave (11).

The coupling frame 22 and the first solar panel 23 may be stored and stored inside the bracket 21 and then slid out and used for photovoltaic power generation.

In the tiled roof assembly 1 according to the preferred embodiment of the present invention, the first solar panel 23 is formed of a plurality of unit cell plates, and the unit cell plates are formed to overlap and unfold with each other.

The first solar panel 23 is not formed in a fixed shape, but is composed of a plurality of unit cell panels as shown in FIGS. 2 (b) and 2 (c). The unit panel also consists of a combination of solar cell modules for solar power generation.

Each unit cell plate is formed to have a size that can be accommodated inside the coupling frame 22. The unit cell plate is provided in plurality, one is fixedly coupled in the coupling frame 22, the other is coupled in a sliding form.

One of the unit cell plates is formed with guide grooves formed by bending two stages on both sides, and sliding ends are formed by forming both end portions of the other unit battery plates fitted into the guide grooves.

The unit battery plate is also made to be operated by the control unit (C) and the driving unit (M). In this case, one end of the second link arm L2 is not coupled to the coupling frame 22 as described above, but a center portion thereof is coupled to the coupling frame 22 as shown in FIG. It is formed longer so that it can be rotated. A third link arm L3 is rotatably coupled to an end of the second link arm L2, and the third link arm L3 is rotatably coupled to a unit cell plate protruding from the front of the unit panel. . The unit plates are made to be locked at each end to prevent the unit cells from being completely separated from each other, and all of the unit cells are interlocked according to the withdrawal and storage of the unit cells which are drawn to the front of the unit panels.

As described above, the first solar panel 23 is formed so that a plurality of unit cells may be overlapped, so that the storage space is less limited. Although the space of the back surface of the eave 11 is narrow, the size of the bracket 21 and the coupling frame 22 may be limited, so that the first solar panel 23 having a larger size may be formed.

In addition, in the unfolded state of the unit cell plate, it provides an advantage that the photovoltaic power generation can be made through the first solar panel 23 having a larger area.

4 and 5 is a perspective view showing a tile roof assembly according to another embodiment of the present invention.

Roof tile assembly (1) according to a preferred embodiment of the present invention further includes a secondary power generation device 30 is coupled to the upper side of the tile roof (10) made to photovoltaic power generation.

The secondary power generation device 30 is a device for generating photovoltaic power from the tile roof 10 separately from the photovoltaic device 20. The sub-generation unit 30 is coupled on the upper side of the tile roof (10). If it is difficult to produce the electricity required only by the photovoltaic device 20 can be supplemented through the secondary power generation device (30).

The secondary power generation device 30 may be variously formed to form a predetermined angle with the surface of the roof tile 10 in consideration of the direction of the sun in the roof tile 10, as described later 10) may be formed to adjust the angle formed with the surface.

FIG. 6 is a cross-sectional view illustrating a sub power generator used in a tile roof assembly according to another embodiment of the present invention. FIG.

In the tiled roof assembly (1) according to the preferred embodiment of the present invention, the secondary power generation device 30, the hinge frame of the storage frame 31, hinged to the roof tile 10, the hinge operation of the storage frame (31) It comprises a support rod 32 to guide the fixed frame 31 is fixed on the tile roof 10, the second solar panel 33 formed to be drawn out of the storage frame 31.

The storage frame 31 is hinged to the roof tile 10 and a space is formed to accommodate the second solar panel 33 therein. A hinge coupling portion is formed at one end of the housing frame 31 and an open lead portion is formed at the opposite end to allow the second solar panel 33 to be drawn out.

The hinge coupling portion of the storage frame 31 is coupled adjacent to the benign (兩 城) forming the side wall of the ridge of the roof tile (10). Therefore, the secondary power generation device 30 is hinged based on the position where the ridge of the tile roof 10 is formed.

The support rod 32 has one end coupled to the lead portion of the housing frame 31 and the other end coupled to the surface of the tile roof 10. The support rod 32 is formed to be stretchable, and the storage frame 31 may hinge according to the expansion and contraction of the support rod 32.

The angle formed by the storage frame 31 and the second solar panel 33 can be adjusted according to the degree of expansion and contraction of the support rod 32, and appropriate solar power generation can be made according to the position of the sun.

The second solar panel 33 is made of a combination of the solar cell module, like the first solar panel 23, the solar power generation.

7 (a) to 7 (c) is a state diagram showing the roof roof assembly including the secondary power generator shown in FIG.

In the tiled roof assembly 1 according to the preferred embodiment of the present invention, the second solar panel 33 is formed of a plurality of unit cell plates, and the unit cell plates are formed to overlap and unfold with each other.

Like the first solar panel 23, the second solar panel 33 is composed of a plurality of unit cells, and when stored, the second solar panel 33 is housed in the storage frame 31 and spreads widely in use, and thus solar power generation. Allow the area to be enlarged.

Similarly to the driving method of the first solar panel 23, the second solar panel 33 including a plurality of unit cells may be a link member such as the second link arm L2 and the third link arm L3. Is connected may be made to be able to withdraw and receive.

1 is a perspective view showing a tile roof assembly according to an embodiment of the present invention,

Figure 2 (a) is a perspective view showing a photovoltaic device used in the tile roof assembly according to another embodiment of the present invention,

Figure 2 (b) is a perspective view showing a photovoltaic device used in the tile roof assembly according to another embodiment of the present invention,

Figure 2 (c) is a perspective view showing the back surface of the photovoltaic device shown in Figure 2 (b),

Figure 3 (a) to Figure 3 (c) is a state diagram showing the roof tile assembly in which the photovoltaic device shown in Figures 2 (b), (c) is used,

4 and 5 is a perspective view showing a roof roof assembly according to another embodiment of the present invention,

Figure 6 is a cross-sectional view showing a secondary power generation device used in the tile roof assembly according to another embodiment of the present invention,

7 (a) to 7 (c) is a state diagram showing the roof roof assembly including the secondary power generator shown in FIG.

Explanation of symbols on the main parts of the drawings

1: tile roof assembly 10: tile roof

11: eave 20: photovoltaic device

21: bracket 22: coupling frame

23: first solar panel 30: secondary power generator

31: storage frame 32: support rod

33: second solar panel L1: first link arm

L2: second link arm L3: third link arm

C: control unit M: driving unit

Claims (7)

Tiled roof with eaves used for traditional hanok; And A photovoltaic device coupled to an end of the eave and photovoltaic and capable of being an extension of the eave, The photovoltaic device, A bracket coupled to the cornice, A coupling frame slidingly coupled to the bracket, Tile roof assembly comprising a first solar panel coupled to the inside of the coupling frame. delete The method of claim 1, The bracket is coupled to the back surface of the eave so that the photovoltaic device is covered by the eave, the coupling frame and the first solar panel is a roof tile assembly, characterized in that it is configured to accommodate the inside of the bracket. The method of claim 3, wherein The first solar panel is composed of a plurality of unit cells, Any one of the unit battery plate is formed in the guide groove is formed by bent in two stages on both sides, the roof tile assembly, characterized in that the both ends of the other unit battery plate is formed so as to overlap and unfold each other is configured to be inserted into the guide groove. The method of claim 1, Roof tile assembly further comprises a secondary power generation device is coupled to the upper side of the roof tile to generate photovoltaic power. The method of claim 5, The secondary power generation device, Storage frame hinged to the roof tile, A support rod for inducing a hinge operation of the storage frame and fixing the storage frame on the tile roof; Tile roof assembly comprising a second solar panel formed to be pulled out of the storage frame. The method of claim 6, The second solar panel is composed of a plurality of unit cells, Any one of the unit battery plate is formed in the guide groove is formed by bent in two stages on both sides, the roof tile assembly, characterized in that the both ends of the other unit battery plate is formed so as to overlap and unfold each other is configured to be inserted into the guide groove.

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