KR101195518B1 - Firewall glass window - Google Patents

Abstract

It includes a firewall and a grid-shaped frame installed along the side of the firewall to support the firewall and installed in the building so as to produce energy by combining the solar cell module that generates electromotive force using sunlight on the fire window A fire protection unit, a solar cell installed in the firewall to convert solar energy into electrical energy, an inverter to convert current generated from the solar cell into direct current and alternating current, and a storage battery for storing electrical energy produced from the solar cell And it provides a fire protection window comprising a solar cell module unit including a controller for controlling the charging and output of the electrical energy generated in the solar cell.

Description

Fire protection window {FIREWALL GLASS WINDOW}

The present invention relates to a fire protection window provided in a balcony of a building. More specifically, the present invention relates to fire protection windows capable of generating power using sunlight.

In general, apartments and villas in the form of apartment houses have balconies.

The balcony of the apartment is a separate space from the living room or the room. Recently, as the balcony is allowed to be used as a living room or a room, the balcony is being extended to utilize not only the existing use but also various spaces such as a living room, a warehouse, a playroom, and the like.

Currently, multi-family multi-unit buildings such as apartments and officetels have to take some safety measures in accordance with the Building Act's decree to expand their balconies. An important part of these safety measures is the installation of a firewall between the railings and the living room windows to prevent the spread of fire, that is, the flames from the lower floors in the event of a fire.

In the case of balcony expansion work, it is usually installed on the balcony of the apartment fireproof windows.

On the other hand, in recent years, the use of photovoltaic power generation facilities that can generate electric power using solar energy is gradually becoming common. The solar cell using the solar energy is attracting attention as a new alternative energy source of the future because it uses no-fossil and infinite energy source of solar light without using fossil fuels such as coal and petroleum. It is used to obtain the generated electric power of automobiles and the like.

The solar cell is a semiconductor device that converts light energy into electrical energy using a photoelectric effect, and is composed of two semiconductor thin films each having a positive (+) and a negative (-) polarity. The cells are connected in series / parallel to generate the voltage and current required by the user, and the user can use the power generated by the solar cell.

The solar cell module is installed on an inclined slope such as a roof of a building, a roof, a terrace, and the like to receive a lot of sunlight.

Recently, research on environment-friendly buildings has been actively conducted due to energy saving and carbon emission reduction regulations, and studies have been attempted to use solar energy in windows of buildings.

This provides a fire protection window that can produce energy by combining solar cell modules that generate electromotive force using sunlight.

In addition, it provides a fire protection window to maximize the production efficiency of energy.

To this end, the fire protection window is a firewall, a fire prevention part including a grid-shaped frame installed along a side end of the firewall to support the firewall and installed in a building,

A solar cell installed in the firewall to convert solar energy into electrical energy, an inverter converting current generated from the solar cell into direct current to alternating current, a storage battery and a solar cell storing electrical energy produced from the solar cell Solar module module including a controller for controlling the charging and output of electrical energy generated by

It may include.

The fire protection window may further include a window unit provided on the top of the fire protection unit. In addition, the solar cell may be installed in the window portion.

The firewall may be made of a fireproof glass of a transparent material. The fire protection glass may have a multilayer structure in which at least two or more layers are laminated.

The firewall may be made of an opaque plate.

The solar cell module unit may further include a secondary solar cell installed in the firewall facing the interior of the building, and a reflection plate installed in the firewall to reflect sunlight to the secondary solar cell.

The inverter or storage battery may be installed in the space inside the frame.

The solar cell may have a double-sided structure provided with an auxiliary solar cell on the back.

The solar cell may be installed along the outer circumference of the firewall. The solar cell may be installed in front of the firewall.

On the other hand, the frame is formed at intervals between the grooves into which the firewall is fitted on the inner circumferential surface and horizontal members installed at the top and bottom of the firewall, and grooves connected to the horizontal member ends and fixed to the inner circumferential surface are spaced from each other. And may include a vertical member installed at the side end of the firewall.

The fire protection window may further include a fixing portion for more stably fixing the fire protection portion to the building.

Thus, according to this fire protection window, by installing solar cells that can produce electrical energy by using solar energy on the fire protection glass installed in the building for the purpose of fire prevention, it is possible to independently generate power in the building, which wastes energy. By reducing the use of fossil fuels, it is possible to prevent environmental pollution such as reducing the generation of carbon dioxide.

In addition, it is possible to maximize the energy production efficiency per unit area by reflecting light back to the solar cell using a reflector. Therefore, the installation area of the solar cell can be minimized to maximize the front view of the fire protection glass.

In addition, it is possible to maximize the electrical energy production efficiency by using a high crystallized fire-resistant glass.

1 is a schematic front view showing a fire protection window according to the present embodiment.
2 is a plan sectional view of the fire protection window according to the present embodiment.
3 is a side sectional view of the fire protection window according to the present embodiment.
4 is a schematic view showing the configuration of a solar cell module unit of the fire protection window according to the present embodiment.
5 is a schematic perspective view showing the structure of the solar cell and the reflector in the fire protection window according to the present embodiment.
6 is a schematic perspective view showing another structure of the solar cell and the reflecting plate of the fire door.
7 is a schematic front view showing another embodiment of the fire protection window.
8 is a side cross-sectional view of the fire protection window according to the embodiment of FIG.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art may easily implement the present invention. The present invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein.

The drawings are schematic and illustrate that they are not drawn to scale. The relative dimensions and ratios of the parts in the figures have been exaggerated or reduced in size for clarity and convenience in the figures and any dimensions are merely exemplary and not limiting. And the same structure, element or part that appears in more than one figure the same reference numerals are used in different embodiments to indicate corresponding or similar features.

The terminology used herein is for the purpose of describing particular embodiments only and is not intended to limit the invention. As used herein, the singular forms “a,” “an,” and “the” include plural forms as well, unless the phrases clearly indicate the opposite. As used herein, the term "comprising" embodies a particular characteristic, region, integer, step, operation, element, and / or component, and other specific characteristics, region, integer, step, operation, element, component, and / or group. It does not exclude the presence or addition of.

Embodiments of the invention described with reference to a perspective view specifically illustrate an ideal embodiment of the invention. The embodiment is not limited to the specific form of the illustrated region, but includes, for example, modification of the form by manufacture. The regions shown in the figures are only approximate in nature, and their forms are not intended to depict the exact form of the regions and are not intended to narrow the scope of the invention.

1 is a schematic front view showing a fire protection window according to the present embodiment, Figures 2 and 3 are a plan sectional view and a side cross-sectional view of the fire protection window.

The fire door 10 is installed in contact with both the wall surface 100 and the bottom surface 110 on the outdoor edge of the balcony of the building. As shown, the fire protection window 10 includes a firewall 20 and a grid-like frame 30 installed along a side end of the firewall 20 to support the firewall 20 and installed on a building balcony. The fire protection unit 12 and the solar cell module unit installed in the fire protection unit 12 converts solar energy into electrical energy.

In addition, the fire protection window 10 of the present embodiment is provided with a window portion 14 on the top of the fire protection portion 12, the window portion 14 also has a structure in which the solar cell module unit for converting solar energy into electrical energy also installed It is.

First, the structure of the fire protection part 12 and the window part 14 is as follows.

The firewall 20 of the fire protection part 12 is supported and installed on the balcony wall surface 100 and the bottom surface 110 by a grid-shaped frame 30 installed along the side end. The firewall 20 forms one body with the frame 30.

In this embodiment, the firewall 20 is made of fireproof glass. The fireproof glass is formed of a multi-layered structure having two internal spaces spaced apart from each other. In the following description, the fire protection glass located on the outside of the building among the two fire protection glasses constituting the firewall 20 is referred to as the outer fire protection glass 22, and the fire protection glass located inside is referred to as the inner fire protection glass 24. The firewall 20 is not particularly limited as long as it is a transparent material capable of blocking the flame in addition to the fire protection glass.

The frame 30 includes a horizontal member 32 and a vertical member 34 that are connected along each side end of the firewall 20 while fixing the firewall 20. In this embodiment, the horizontal member 32 and the vertical member 34 is made of aluminum. The frame 30 is a horizontal member 32 and the vertical member 34 is connected to each other to form a grid structure. Each inner surface of the horizontal member 32 and the vertical member 34 is provided with a groove (36) to which the firewall 20 is fitted to be spaced apart.

Here, the horizontal member 32 and the vertical member 34 form a support 38 on both sides of the groove so that each groove 36 is formed. The support 38 is formed of a hollow structure having a hollow rectangular cross section.

In the present embodiment, some components of the solar cell module unit are installed in the internal space of the support 38. The size of the support may be variously modified depending on the structure, shape and size of the component to be inserted is not particularly limited. This will be explained later.

As shown in FIG. 2, the fire protection unit 12 is provided with side fixing parts 40 between the plurality of frames 30 arranged in a row, and supports each frame 30 by connecting them. The side fixing part 40 is installed at a position where the frame 30 and the frame 30 are stacked, and have a T-shaped cross-sectional structure. Each frame 30 of the fire protection unit 12 separated therefrom can increase its fixing force by the side fixing part.

3, the upper end of the fire protection part 12 is fixed by the upper fixing part 42, and the window part 14 is supported by the upper fixing part 42.

The upper fixing part 42 is installed on the upper end of the fire protection part 12 to fix the fire protection part 12 to the balcony more stably.

The upper fixing part 42 is placed on the upper end of the frame 30 and the front and rear ends are bent downward to surround the horizontal member 32 of the frame 30. In addition, the front end of the upper fixing part 42 has a structure extending upward to support the window 14.

The side fixing part 40 and the upper fixing part 42 are variously deformable in the above structure and are not particularly limited.

On the other hand, the window portion 14 includes a glass window 60 having a multi-layer structure, such as the fire protection unit 12 and a rectangular frame 50 for supporting the glass window. In the following description, the glass window located on the outside of the building of the two glass windows is called the outer glass window 62, and the glass window located on the inside is called the inner glass window (64). The glass window may be made of fireproof glass, such as the fire protection unit 12, and may be made of glass used in conventional windows and doors.

The frame 50 includes a horizontal member 52 and a vertical member 54 connected to each side end of the glass window while fixing the glass window 60. In this embodiment, the horizontal member 52 and the vertical member 54 is made of aluminum. The frame 50 is a horizontal member 52 and the vertical member 54 is connected to each other to form a grid structure. Each inner surface of the horizontal member 52 and the vertical member 54 is provided with a groove 56 to which the glass window 60 is fitted to be coupled at intervals. Here, the horizontal member 32 and the vertical member 34 form a support 58 on both sides of the groove so that each groove 56 is formed. The support 58 is formed of a hollow structure having a hollow rectangular cross section. In the present embodiment, some components of the solar cell module unit are installed in the internal space of the support.

In the fire protection part 12 and the window part 14 of the structure mentioned above, the solar cell module part is installed in the fire part 12 and the window part 14, and produces electric energy from sunlight.

As shown in FIG. 4, the solar cell module unit 70 includes a solar cell 72 for converting solar energy into electrical energy, an inverter 74 for converting current generated from the solar cell 72, Storage battery 76 for storing the electrical energy produced from the solar cell 72 and a controller 78 for controlling the charging and output of the electrical energy generated in the solar cell (72).

The inverter 74 converts the direct current generated from the solar cell 72 into alternating current and sends the converted current to a use place. For example, the inverter 74 is connected to an outlet in a building so that various electric appliances can be connected and used. In the present embodiment, the inverter 74 has an internal space of the support body 38 formed in the frame 30 of the fire protection unit 12 and the interior of the support body 58 formed in the frame 30 of the window 14. It is installed in the space.

In addition, the storage battery 76 stores the electric energy generated from the solar cell 72 and outputs power to the inverter according to the signal of the controller if necessary. The storage battery may be set in various ways according to its capacity and may be separately provided inside the frame or outside the main fire window.

 The controller 78 detects the total amount of electric energy generated from the solar cell 72 and the output amount used through the inverter 74 and controls the amount of power according to the use environment. The controller 78 may be installed in the interior of a building, for example, for the convenience of a user, and is not particularly limited. In addition, the wires electrically connecting the solar cell 72, the inverter 74, and the controller 78 may be installed through the inside of the frame 30.

In the present embodiment, the solar cell 72 has an outer circumferential portion of the firewall 20 and an outer circumferential portion of the window portion 14 so that the front surface of the electric energy generation, as shown in FIG. 1, faces the outside of the building. The number of drums is continuously arranged and installed along the frame 30 at. Each solar cell 72 is electrically connected to each other.

The solar cell 72 is a silicon type solar cell or a thin film type solar cell such as amorphous silicon (a-Si: H), microcrystalline silicon (uc-Si: H), CIS (CuInSe), CdTe, etc. Since many techniques are already disclosed, a detailed description thereof will be omitted.

The solar cell 72 has a front surface installed toward the outside, thereby generating electrical energy using sunlight directly irradiated to the solar cell 72.

In addition, as shown in FIG. 5, the solar cell module unit 70 is installed in the firewall 20, and the solar cell module 80 is installed in the firewall 20 and the solar cell module 80 faces the front of the building. It further includes a reflector 82 for reflecting light to the auxiliary solar cell (80).

The solar cell 72, the auxiliary solar cell 80, and the reflecting plate 82 are installed in the window portion 14 in the same manner. Hereinafter, the structure installed in the fire protection unit 12 will be described as an example. . The auxiliary solar cell 80 produces electrical energy from sunlight in the same structure as the solar cell 72. The reflective plate 82 may be used without particular limitation as long as it is a material capable of reflecting sunlight.

In the present embodiment, the solar cell 72 has a structure provided on the outer surface of the outer fireproof glass of the multilayer fireproof glass constituting the firewall (20). As shown in FIG. 5, the auxiliary solar cell 80 is installed on the inner side surface of the outer fire protection glass 22 among the fire protection glasses of the multilayer. The auxiliary solar cell 80 is installed along the outer circumferential portion of the firewall 20 like the solar cell 72.

The reflecting plate 82 is provided on the outer surface of the inner fireproof glass 24 of the multilayer fireproof glass. The reflecting plate 82 is provided along the outer circumferential portion of the inner fireproof glass 24.

The auxiliary solar cell 80 is installed toward the inside of the building to generate electrical energy using the sunlight reflected by the reflecting plate 82. The reflector 82 has a structure that is relatively larger than the height of the auxiliary solar cell 80 and extends upwardly above the upper end of the auxiliary solar cell 80 to sufficiently reflect the sunlight.

Thus, as shown in FIG. 5, sunlight directly irradiated is generated as electrical energy by the solar cell 72. In addition, the auxiliary solar cell 80 disposed at the same position as the solar cell 72 generates electric energy from sunlight reflected by the reflector 82.

Therefore, while minimizing the area occupied by the solar cell 72 in the fireproof glass, it is possible to further increase the production of electrical energy in the same area compared with the conventional.

6 illustrates another embodiment of the solar cell module unit.

According to the above drawings, the solar cell module unit includes a solar cell 84 for converting solar energy into electrical energy, and the solar cell 84 is capable of generating electrical energy on both the front and rear surfaces. It has a double-sided cell structure.

In addition, the solar cell module unit is installed in the firewall 20 includes a reflector 82 for reflecting the sunlight to the solar cell 84. The solar cell 84 and the reflecting plate 82 are installed in the window portion 14 in the same manner, and in the following description, the structure installed in the fire protection portion 12 will be described as an example.

In the present embodiment, the solar cell 84 has a structure installed on the inner surface of the outer fire protection glass 22 of the multilayer fire protection glass constituting the firewall (20). The solar cell 84 is installed along the outer circumferential portion of the outer fire protection glass 22. The reflecting plate 82 is provided on the outer surface of the inner fireproof glass 24 of the multilayer fireproof glass. The reflecting plate 82 is also provided along the outer circumferential portion of the inner fireproof glass 24.

The surface facing the outside of the building (hereinafter referred to as the front surface 86) of both sides of the solar cell 84 to generate electrical energy using the sunlight directly emitted from the sun. The surface of the solar cell 84 facing both sides of the building (hereinafter referred to as the rear surface 88) generates electric energy by using sunlight reflected by the reflector 82. The reflector plate 82 has a structure that is relatively larger than the height of the solar cell 84, and extends upwardly above the upper end of the solar cell 84 to sufficiently reflect sunlight.

Accordingly, as shown in FIG. 6, the front surface 86 generates electric energy from the directly irradiated sunlight using one solar cell 84, and the rear surface 88 is reflected by the reflector 82. It is possible to generate electrical energy from light.

On the other hand, Figures 7 to 8 show a fire door according to another embodiment.

According to the above drawings, the fire protection window 10 includes a fire protection structure 90 of opaque material in which the firewall of the fire protection unit 12 is not fire protection glass.

Except for the firewall 20, the rest of the components are the same as the structure of the fire protection window 10 described above, so the detailed description thereof will be omitted below.

The fire protection structure 90 constituting the firewall 20 of this embodiment has a structure in which the lumber 92, the styrople 94, and the silica board 96 overlap. The fire protection structure 90 is not limited thereto as long as it is a fire protection material, and can be modified into various structures.

The solar cell 72 is attached to the outer side surface of the fire protection structure 90. In this embodiment, the solar cell 72 is provided over the entire outer surface of the fire protection structure 90.

The solar cells 72 installed on the front surface of the fire protection structure 90 are electrically connected to each other. The solar cell is electrically connected to the inverter 74 provided in the frame 30 supporting the fire protection structure 90 as shown in FIG. 8.

Thus, according to this embodiment, it is possible to install a larger number of solar cells 72 on the front of the fire protection structure 90, and generates a greater amount of electrical energy through the installation of a large number of solar cells 72. You can do it.

Here, the solar cell 72 installed in the fire protection structure 90 may be a silicon solar cell or a thin film solar cell as mentioned above. In this embodiment, since the solar cell is installed over the entire fire protection structure, it is possible to secure economical efficiency when installing a thinner solar cell having a lower cost.

While the present invention has been described in connection with what is presently considered to be practical exemplary embodiments, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, Of course.

12: fire department 14: window
20: firewall 22: outer fireproof glass
24: inner fireproof glass 30: frame
70 solar cell module 72,84 solar cell
74: inverter 76: storage battery
78: controller 80: auxiliary solar cell
82: reflector 90: fire protection structure

Claims (8)

It includes a multi-layered firewall in which two fire-resistant glass are spaced apart, and a lattice-shaped frame installed along the side end of the firewall and in contact with both the wall and the bottom of the outdoor edge of the building balcony to support the firewall. A fire protection unit, a solar cell installed in the firewall to convert solar energy into electrical energy, an inverter to convert current generated from the solar cell into direct current and alternating current, and a storage battery for storing electrical energy produced from the solar cell And a solar cell module unit including a controller for controlling the charging and output of the electrical energy generated in the solar cell,
The solar cell module unit is installed on the inner side of the outer fire protection glass of the fire protection glass of the firewall, and installed on the outer side of the inner fire protection glass to reflect the sunlight to the auxiliary solar cell and the secondary solar cell The fire protection window further comprising a reflector extending longer than the top of the secondary solar cell larger than the height of the. delete The method of claim 1,
It further comprises a window portion provided on the top of the fire protection, the window portion comprises a window frame and a grid-shaped frame is installed along the side ends of the glass window to support the glass window, the solar cell module unit of the solar cell is installed on the glass window Fire doors. The method of claim 3, wherein
The solar cell module part further comprises an auxiliary solar cell installed in a glass window facing the interior of the building, and a reflection plate installed on the glass window to reflect sunlight to the auxiliary solar cell. delete The method according to claim 1 or 3 or 4,
The firewall is made of an opaque plate, the solar cell is a fire door that is installed on the entire front of the firewall. It includes a multi-layered firewall in which two fire-resistant glass are spaced apart, and a lattice-shaped frame installed along the side end of the firewall and in contact with both the wall and the bottom of the outdoor edge of the building balcony to support the firewall. A fire protection unit, a solar cell installed in the firewall to convert solar energy into electrical energy, an inverter to convert current generated from the solar cell into direct current and alternating current, and a storage battery for storing electrical energy produced from the solar cell And a solar cell module unit including a controller for controlling the charging and output of the electrical energy generated in the solar cell,
The solar cell is a double-sided cell structure that is installed on the inner side of the outer side of the fire-proof glass of the firewall, both front and rear to produce electrical energy, the solar cell is installed on the outer side of the inner side of the fire glass The fire protection window further comprising a reflector reflecting on the back of the cell and extending over the top of the solar cell, the reflector being larger than the height of the solar cell. The method according to claim 1 or 7,
The inverter or the storage battery is a fire protection window provided in the space inside the frame.

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