KR20080014719A - Building circulation system using curtain wall as ventilator - Google Patents

Abstract

A high building circulation system using an exterior curtain wall as a ventilation space is provided to harmonize natural ventilation with forced ventilation to minimize operation cost of a ventilation system. An exterior curtain wall(200) is separated from an outer wall(22) of a high building to surround the outside of the high building. An external air suction port(210) is formed at a low story part of the exterior curtain wall for introducing external air. An upper end of the exterior curtain wall is extended in a horizontal direction to cover a part of an upper part of a roof of the high building. An air current exhaust port(220) is formed between the extended end of the exterior curtain wall and the roof of the high building. A partial side of the high building is not surrounded by the exterior curtain wall to introduce external air into rooms(33) directly through windows and doors(11) of each story.

Description

High-rise building ventilation system using exterior curtain wall as exhaust space {Building Circulation System using Curtain Wall as Ventilator}

The present invention relates to a high-rise building ventilation system that prevents radiant heat from the sun from being transferred to an interior space and utilizes an exterior curtain wall as an exhaust space. More specifically, the present invention relates to a high-rise building exterior wall 22 and a predetermined distance to the outside. Exterior curtain wall 200 is installed so as to surround the outside of the high-rise building; An outside air suction port 210 provided at a lower portion of the exterior curtain wall 200 to receive outside air; An upper end of the exterior curtain wall 200 extends in a horizontal direction to cover a portion of the upper part of the roof top of the high-rise building, and a space between the extended curtain wall 200 end and the roof of the high-rise building includes a slitable opening and closing slit. The airflow outlet 220 is installed, the exterior curtain wall 200 does not surround the entire slope of the high-rise building, rather than the exterior curtain wall 200 is installed on a portion of the high-rise building is opened high-rise building Each floor of the window 11 is characterized in that the outside air is directly introduced into the indoor space (33).

Conventional high-rise buildings connect the air passages provided in each floor to one ventilation chamber, and operate a blower fan to perform forced ventilation for releasing the air collected in the ventilation chamber to the outside, or for each floor. Although the individual ventilation system is applied to each floor to directly discharge the air in the room to the outside air, all of these conventional ventilation systems not only meet the ventilation required in the interior of each floor, Since the device is complicated, installation and operation costs increase, and there is a problem of causing noise and uncomfortable body caused by forced ventilation.

In addition, the upper floors of high-rise buildings (particularly popular residential complexes) increase the indoor operating temperature during the summer due to the sun's radiant heat. There is a problem that can not be formed.

The object of the present invention created to solve the above problems is as follows.

First, it is an object of the present invention to provide a means for minimizing the operating cost of the ventilation system through the combination of natural ventilation and forced ventilation, and to reduce the operating noise and discomfort of the ventilation system.

Secondly, it is another object of the present invention to provide a means for preventing an increase in room temperature due to solar radiation.

Third, another object of the present invention is to provide a means by which the radiant heat of the sun can be used for the stack effect to provide more efficient exhaust.

Fourth, another object of the present invention is to provide a means for blocking the sun from radiant heat and securing a viewing right.

Fifth, it is another object of the present invention to provide a means for ensuring a maximum residential space is not required to be provided with a separate vertical passage for exhaust.

Sixth, it is another object of the present invention to provide a means for preventing the propagation of fire to other floors, and to reduce the winter heating costs by controlling the smoke effect does not occur in winter.

Technical configuration of the present invention created to achieve the above object is as follows.

The present invention relates to ventilation of a high-rise building, the outer wall (22) of the high-rise building exterior curtain wall (200) installed to be spaced apart a predetermined distance to surround the outside of the high-rise building; An outside air suction port 210 provided at a lower portion of the exterior curtain wall 200 to receive outside air; An upper end of the exterior curtain wall 200 extends in a horizontal direction to cover a portion of the upper part of the roof top of the high-rise building, and a space between the extended curtain wall 200 end and the roof of the high-rise building includes a slitable opening and closing slit. The airflow outlet 220 is installed, the exterior curtain wall 200 does not surround the entire slope of the high-rise building, rather than the exterior curtain wall 200 is installed on a portion of the high-rise building is opened high-rise building Each floor of the window 11 is characterized in that the outside air is directly introduced into the indoor space (33).

Technical effects according to the present invention of the above configuration is as follows.

First, it is possible to minimize the operating cost of the ventilation system and to reduce the operating noise and body discomfort of the ventilation system through a combination of natural ventilation and forced ventilation.

In other words, fresh outside air is supplied through the window 11 of the portion where the exterior curtain wall 200 is not installed, and muddy air in the room is provided through the window 11 of the portion where the exterior curtain wall 200 is installed. It is discharged into the space between the wall 200 and the outer wall 22. In this way, the muddy air discharged in the room is lifted up if it is naturally generated by the stack effect and is discharged to the outside through the airflow outlet 220. If the natural airflow is insufficient, a blower ( It is forcibly raised by the 235 is discharged to the outside through the forced discharge port (230).

In other words, it is possible to realize effective ventilation with a minimum operating cost through the combination of the natural ventilation system by the stack effect and the forced ventilation system by the blower.

Second, it is possible to prevent the room temperature rise due to the sun's radiant heat.

In other words, by attaching a sunscreen film 44 to the inner surface of the outer curtain wall 200 or the surface of the shielding glass 100 to block the sun's radiant heat from reaching the indoor space 33 to reduce the indoor cooling cost in summer. It can be greatly reduced.

When the solar thermal barrier film 44 is attached as described above, the temperature of the attachment surface is increased. In the present invention, the solar thermal barrier film 44 is not attached to the windows 11 of the high-rise building. The heat of the inner surface of the exterior curtain wall 200 or the surface of the barrier glass 100 that is heated by attaching it to the separate barrier glass 100 is lifted by the air flow between the exterior curtain wall 200 and the outer wall 22 to the outside air. Bar is emitted structure, it can effectively block the temperature rise of the interior space 33 by sunlight. If the solar heat shielding film 44 is directly attached to the window 11, there is a problem that can block the radiant heat of the sun, but due to the heat of the heated window 11 can not prevent the temperature rise of the indoor space.

Third, more efficient exhaust can be achieved by using the sun's radiant heat for the stack effect.

In other words, when the surface temperature of the inner surface of the outer curtain wall 200 or the blocking glass 100 is increased by the solar thermal barrier film 44, the temperature of the space between the outer curtain wall 200 and the outer wall 22 is increased. As the rising air flows further, the turbid air discharged from the room can be more quickly induced to the upper part of the high-rise building and discharged to the outside through the airflow outlet 220 or the forced discharge port 230.

Fourth, it can block the radiant heat of the sun and secure the right to view.

In other words, the solar heat blocking film 44 does not block all the sunlight, but transmits a part of the visible light, thereby effectively blocking the sun's radiant heat without being violated by the view.

Fifth, it is possible to prevent the fire from spreading to other floors.

In other words, between the exterior curtain wall 200 serving as the exhaust passage and the outer wall 22 of the high-rise building, a fire damper 55 having a rotating slit open and close is provided at the boundary of each floor, so that a fire damper may be used in case of a fire. 55) can be blocked to prevent the flame from propagating to the upper portion by the air stream.

Sixth, it is possible to reduce the winter heating costs by controlling so that the stack effect does not occur in winter.

In other words, in the winter season, the air inlet 210 is closed and the fire damper 55 is blocked to prevent the rise of air flow due to the stack effect in the space between the exterior curtain wall 200 and the outer wall 22 of the high-rise building. That is, the air between the exterior curtain wall 200 and the outer wall 22 of the high-rise building, which are raised by the sunlight, stays without leaving the outside air to maximize the thermal effect and reduce the indoor heating cost. Can be.

Seventh, it is not necessary to be provided with a separate vertical passage for exhaust can ensure the maximum residential space.

Hereinafter, specific embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a cross-sectional view showing a specific embodiment of the present invention, and FIG. 2 is a cross-sectional view showing a planar structure of a specific embodiment of the present invention.

1 and 2, the exterior curtain wall 200 does not surround the entire high-rise building, but three of four surfaces are provided with an exterior curtain wall 200 and the other surface is an exterior curtain wall 200. ) Is not installed.

That is, the exterior surface of the high-rise building receiving sunlight, Seomyeon, and the south side to install the exterior curtain wall 200, the north side may be a structure that does not install the exterior curtain wall 200, all buildings to which the present invention is applied The exterior curtain wall 200 is not necessarily installed on the hibernating, written, and south sides, and the exterior curtain wall 200 is not installed on the north side, and the exterior curtain wall (200) is considered in consideration of the surrounding environment and the conditions in which the high-rise building was constructed. ) May be appropriately selected from the side on which the external curtain wall 200 is not installed.

In other words, when a high-rise building is constructed in the direction as shown in FIG. 3, the exterior curtain wall 200 is installed on two sides facing south, and the exterior curtain wall 200 is not installed on two sides facing north. You may.

The lower layer of the exterior curtain wall 200 is provided with an open air inlet 210 that can be opened and closed.

An upper end of the exterior curtain wall 200 extends in a horizontal direction to cover a part of the upper part of the roof of the high-rise building, and an air flow constituted by an openable damper in a space between the extended exterior curtain wall 200 end and the roof of the high-rise building. The outlet 220 is provided.

Forced discharge port 230 is installed in parallel with the air flow outlet 220 as shown in Figure 1 to form a separate discharge space.

In other words, in the space between the extended exterior curtain wall (200) end and the roof of the high-rise building is provided with a forced discharge port (230) separate from the air flow outlet (220), the air flow outlet (220) is in charge of natural ventilation and forced outlet 230 is responsible for forced ventilation using the blower 235 to artificially induce the rising air.

When the blower 235 forcibly generates an upward airflow and discharges it through the forced discharge port 230, it is preferable to close the rotation slit to block the airflow outlet 220, because when the blower operates the airflow outlet 220. This is because when the air is discharged, the air in the vicinity of the airflow outlet 220 flows back and flows into the airflow outlet 220 again, thereby reducing the effect of forced discharge.

The blower 235 installed in the forced discharge port 230 may be set to operate automatically when the speed of the rising air generated in the space between the exterior curtain wall 200 and the outer wall 22 of the high-rise building falls below a certain value. have.

As the exterior curtain wall 200 is not installed on a part of the high-rise building as described above, as shown in FIG. 1, through the window 11 provided on the part surface where the exterior curtain wall 200 is not installed. Outside air flows directly into the interior space 33, and the muddy air of the interior space 33 passes through the exterior curtain wall 200 and the exterior wall 22 through the window 11 provided on the surface on which the exterior curtain wall 200 is installed. It is discharged into the space between.

In the case of the window 11 provided on the side where the exterior curtain wall 200 is installed, as shown in FIGS. 1 and 4, a rotating shaft is provided at the lower part so that the upper part is opened to the outside so that muddy indoor air is discharged better. It is preferable to.

The turbid air discharged into the space between the exterior curtain wall 200 and the outer wall 22 is lifted by the rising air and is discharged to the outside air through the airflow outlet 220 or the forced discharge port 230.

In other words, the air introduced into the window 11 circulates through the interior space 33 and is led to the space between the exterior curtain wall 200 and the exterior wall 22 to rise by the rising airflow and the airflow outlet 220 or forced. It is a structure that is discharged again to the outside through the outlet 230.

On the inner surface of the glass constituting the outer curtain wall 200, a solar heat shielding film 44 is attached as shown in a partial enlarged view in FIG.

As such, when the solar heat shielding film 44 is attached, the heat of the sun is blocked from reaching the interior space 33. The temperature of the inner surface of the exterior curtain wall 200 to which the solar heat shielding film 44 is attached is increased. .

As such, when the temperature of the inner surface of the exterior curtain wall 200 rises, the temperature between the exterior curtain wall 200 and the outer wall 22 also increases, and this temperature rise causes the air flow to rise due to the stack effect. When the bar is heated, the heated air rises to the upper end of the exterior curtain wall 200 along the upward airflow and is discharged through the airflow outlet 220 or the forced outlet 230.

That is, the solar heat blocking film 44 is used to block the radiant heat of the sun from reaching the interior space 33, and at the same time, cause an air flow in the space between the exterior curtain wall 200 and the exterior wall 22 to increase the temperature. Heat from the inner surface of the exterior curtain wall 200 can be blocked at the same time to be transmitted to the indoor space.

4 and 5 illustrate a case in which the barrier glass 100 is further installed as another specific embodiment of the present invention.

The barrier glass 100 is located in a space between the exterior curtain wall 200 and the outer wall 22 of the high-rise building, and is installed to be spaced apart from each of the exterior curtain wall 200 and the outer wall 22 of the high-rise building.

When the barrier glass 100 is installed, the solar blocking film 44 is attached to the surface (outer side or inner side) of the barrier glass 100.

As described above, the purpose of attaching the sunscreen film 44 to the surface of the barrier glass 100 is also the same as the purpose of attaching the sunscreen film 44 to the inner surface of the exterior curtain wall 200.

That is, the sun's radiant heat is blocked to reach the interior space 33. When the solar heat shielding film 44 is attached to the surface of the barrier glass 100, the surface temperature of the barrier glass 100 is reduced to sunlight. To rise.

As such, when the surface temperature of the barrier glass 100 rises, the temperature between the exterior curtain wall 200 and the outer wall 22 also rises, and the temperature rise causes the air flow due to the stack effect. The warmed air rises to the upper end of the exterior curtain wall 200 along the upward airflow and is discharged through the airflow outlet 220 or the forced outlet 230.

That is, the blocking glass 100 and the solar heat blocking film 44 are used to block the radiant heat of the sun from reaching the interior space 33 and at the same time, the air flow is raised in the space between the exterior curtain wall 200 and the outer wall 22. By causing the heat of the surface of the temperature blocking glass 100 is transferred to the indoor space can also be blocked at the same time.

The shielding glass 100 is spaced apart to maintain a constant distance from the exterior curtain wall 200, as shown in Figure 4, and is spaced apart so as to maintain a constant distance from the outer wall 22 to the outside of the shielding glass 100 It allows the rise of airflow on both the side and the inner side.

As shown in Figs. 1 and 4, a fire damper 55 having an opening and closing pivot slit is installed at each floor boundary of the space between the outer wall 22 and the exterior curtain wall 200 of the high-rise building.

Thus, when the fire damper 55 is installed at each floor boundary part, the fire slit can be closed to prevent propagation of the fire generated in the lower part by the raised airflow to the upper part when the fire occurs.

The fire damper 55 may be set to automatically close the rotating slit by detecting a fire (using a temperature or gas sensor) or may be set to operate only when a separate switch is operated.

The outside air inlet 210 is opened when the windows 11 of the high-rise building is closed and the air conditioner is operated. In this way, when the windows 11 are closed, the outside air supply or indoor air is supplied through the windows 11 of the high-rise building. Since the discharge is not made, the solar air blocking film 44 is attached while the air introduced into the space between the exterior curtain wall 200 and the outer wall 22 rises through the outside air inlet 210 to the outside air inlet 210. The heat of the inner surface of the outer curtain wall 200 or the surface of the blocking glass 100 is discharged to the outside air through the airflow outlet 220 or the forced outlet 230.

As described above, the present invention has been described with reference to specific embodiments of the present invention, but the scope of protection of the present invention is not limited to the embodiments, and the technology for main pipe within the scope of not changing the gist of the technical idea of the present invention. Addition or deletion, design changes such as a simple change of shape, etc. clearly fall within the protection scope of the present invention.

1 is a cross-sectional view showing a specific embodiment of the present invention.

2 is a cross-sectional view showing a planar structure of a specific embodiment of the present invention.

3 is a cross-sectional view showing a planar structure of another specific embodiment of the present invention.

4 is a cross-sectional view showing another specific embodiment of the present invention, showing the case where the barrier glass is installed.

Fig. 5 is a sectional view showing the planar structure in which the barrier glass is installed.

<Description of the symbols for the main parts of the drawings>

100: breaking glass

200: exterior curtain wall

210: outside air intake

220: airflow outlet

230: forced outlet

235: blower

11: Window

22: outer wall

33: indoor space

44: solar thermal barrier film

55: fire damper

Claims (8)

As for ventilation of high-rise building, An exterior curtain wall 200 installed to be spaced apart from the outer wall 22 of the high-rise building by a predetermined distance to surround the outside of the high-rise building; An outside air suction port 210 provided at a lower portion of the exterior curtain wall 200 to receive outside air; An upper end of the exterior curtain wall 200 extends in a horizontal direction to cover a portion of the upper part of the roof top of the high-rise building, and a space between the extended curtain wall 200 end and the roof of the high-rise building includes a slitable opening and closing slit. Has been installed air outlet 220; The exterior curtain wall 200 does not surround the entire slope of the high-rise building, but is opened without the exterior curtain wall 200 installed on a part of the high-rise building so that outside air is opened through each floor window 11 of the high-rise building. High-rise building ventilation system utilizing the exterior curtain wall as an exhaust space, characterized in that directly into the interior space (33). In claim 1, A sunscreen film attached to an inner surface of the glass constituting the exterior curtain wall 200; High-rise building ventilation system utilizing the exterior curtain wall as an exhaust space, characterized in that it further comprises. In claim 1, A barrier glass 100 positioned in a space between the exterior curtain wall 200 and the outer wall 22 of the high-rise building and spaced apart from each of the exterior curtain wall 200 and the outer wall 22 of the high-rise building; And, A sunscreen film 44 attached to the surface of the barrier glass 100; High-rise building ventilation system utilizing the exterior curtain wall as an exhaust space, characterized in that it further comprises. The method of claim 2 or 3, Forced discharge port 230 is installed in parallel with the air flow outlet 220 to form a separate discharge space; And, A blower (235) installed in the forced discharge port (230) forcibly inducing an upward airflow in a space between the exterior curtain wall (200) and the outer wall (22); High-rise building ventilation system utilizing the exterior curtain wall as an exhaust space, characterized in that it further comprises. In claim 4, A fire curtain damper 55 having an open / close rotatable slit is installed on each floor boundary of the space between the outer wall 22 of the high-rise building and the exterior curtain wall 200 as an exhaust space. High-rise building ventilation system utilized. In claim 5, The outside air suction opening 210 is opened when the window 11 of the high-rise building is closed and the air conditioner is operated. High-rise building ventilation system utilizing the exterior curtain wall as an exhaust space when the blower (235) forcibly generates an upward air flow to discharge through the forced discharge port 230, the air flow outlet 220 is closed. In claim 5, The protective damper 55 is a high-rise building ventilation system using an exterior curtain wall as an exhaust space, characterized in that the rotating slit is automatically closed in the event of a fire, and to block the rising air flow by closing the rotating slit by operating a separate switch in winter. . In claim 5, High-rise building ventilation system utilizing the exterior curtain wall as an exhaust space, characterized in that the window (11) provided on the surface on which the exterior curtain wall (200) is installed is provided with a rotating shaft at the bottom.

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