JP6023113B2 - Building ventilation structure - Google Patents

Description

  The present invention relates to a building ventilation structure having a double skin structure including an outer surface portion and an inner surface portion.

  Patent Document 1 discloses an exhaust structure in which float glass is disposed on the outer side surface portion, multilayer glass is disposed on the inner side surface portion, and a blind is provided in a space between the float glass and the multilayer glass. . With such an exhaust structure, an updraft of air is efficiently generated by the absorption heat of sunlight by the blind.

  Patent Document 2 discloses an exhaust structure having a double skin structure on a bay window of a building.

JP 2005-90187 A Japanese Utility Model Publication No. 64-53392

  However, the exhaust structure disclosed in Patent Document 1 is disadvantageous in terms of space utilization and taxation because the position of wall receding is the outer glass surface. On the other hand, since the exhaust structure disclosed in Patent Document 2 uses a bay window of a building, it is advantageous in terms of space utilization and taxation, but because the height of the exhaust structure is low, sufficient ascending airflow does not occur, There is a problem that forced ventilation by an electric fan is required, and the construction cost and running cost increase.

  This invention makes it a subject to provide the building ventilation structure which can suppress construction cost and running cost in view of said situation.

  In order to solve the above problems, the building ventilation structure of the present invention has a double skin structure ventilation path composed of an outer surface part and an inner surface part, an outside air introduction part for taking outside air into the ventilation path, and an inside of the ventilation path. The bay window includes a discharge unit that discharges the taken-out outside air and a natural ventilation path that communicates with the discharge unit.

  If it is said structure, since natural ventilation is performed by the natural ventilation path connected to the said discharge part, construction cost and running cost can be suppressed. Moreover, since it can be configured as a bay window, it is advantageous in terms of space utilization and taxation. Furthermore, it becomes possible to produce at low cost by making the bay window prefabricated.

  The cross-sectional area on the center side of the natural ventilation path communicating with the discharge portion may be smaller than the cross-sectional area of the end opening of the natural ventilation path. According to this, the ventilating effect reduces the pressure of the discharge section and promotes the discharge of the outside air taken into the ventilation path, so that natural ventilation is efficiently performed.

  The natural ventilation path may be provided in a lateral arrangement from one side of the roof of the bay window to the other side. According to this, the roof of the bay window can be effectively used. Moreover, the natural wind which flows along the wall surface of a building can be used efficiently.

  A heat buffer layer may be formed on the indoor side of the ventilation path by the partition member provided in the ventilation path. According to this, the heat buffer layer can suppress the heat in the ventilation path from being transmitted to the indoor side.

  Indoor air may pass through the thermal buffer layer and be exhausted from the ventilation path. For example, when indoor air cooled by an air-conditioning indoor unit is directly discharged to the outside by a ventilation fan or the like, the cooled air is wasted. If the cooled indoor air is configured to pass through the thermal buffer layer, the cooled indoor air can be effectively used to suppress an increase in temperature of the thermal buffer layer.

  You may have a water supply part which supplies water to the said partition member. According to this, cooling in the ventilation path can be performed by the heat of vaporization of the water.

  A drain portion for discharging water generated in the natural ventilation path from the natural ventilation path may be provided. According to this, it can prevent that the said water dripping in the said ventilation path from the said discharge part connected to the said natural ventilation path.

  If it is this invention, since natural ventilation is performed, construction cost and running cost can be suppressed. Since it can be configured as a bay window, it is advantageous in terms of space utilization and taxation, and further mass production and cost reduction by prefabrication are possible. In addition, when a bay window unit is used, installation at the time of renovation becomes easy. Also. If it is the structure from which a venturi effect is acquired, there exists an effect that natural ventilation can be performed efficiently.

1 is a schematic sectional view showing a building ventilation structure according to an embodiment of the present invention. It is a schematic front view of the building ventilation structure of FIG. It is a schematic top view of the building ventilation structure of FIG. It is explanatory drawing which showed the building ventilation structure of other embodiment of this invention. It is explanatory drawing which showed the other example of the natural ventilation path in the building ventilation structure of embodiment of this invention.

Embodiments of the present invention will be described below with reference to the accompanying drawings.
As shown in FIG. 1, the building ventilation structure 1 of this embodiment includes a double-skin ventilation path 2 composed of an outer surface portion 21 and an inner surface portion 22, an outside air introduction portion 3 that takes outside air into the ventilation passage 2, and The exit window 11 provided on the outer wall surface of the building is provided with a discharge part 4 for discharging the outside air taken into the ventilation path 2 and a natural ventilation path 5 communicated with the discharge part 4. A blind 23 that can be opened and closed is provided on the outdoor side of the inner side surface portion 22. The blind 23 receives a solar heat and rises in temperature to generate an updraft in the ventilation path 2.

  As shown in FIGS. 2 and 3, the ventilation path 2 is formed by the main body window portion of the bay window 11. The outer surface portion 21 in the ventilation path 2 is formed of a trapezoidal transparent window that can be opened or closed. Moreover, the said inner surface part 22 consists of a double transparent window which can be opened and closed or cannot be opened and closed. On the upper side of the main window portion of the bay window 11, a bay window roof 12 having a width wider than the width of the main window portion is provided.

  The outside air introduction part 3 is formed so as to penetrate the lower plate 11a of the bay window 11 in the vertical direction. Thus, when the said external air introduction part 3 is formed in the perpendicular direction, it is not necessary to provide the structure of a water reservoir in the said lower side board 11a. On the other hand, the outside air introduction unit 3 is provided with, for example, an insect net or a mesh.

  The discharge portion 4 is formed so as to protrude in the vertical direction from the upper plate 11b of the bay window 11, that is, from the top plate portion of the bay window roof 12, to the back side of the top plate. The opening area of the discharge part 4 is smaller than the opening area of the outside air introduction part 3, but is not limited thereto. There are no particular obstacles to the airflow in the ventilation path 2 from the outside air introduction part 3 to the discharge part 4, and gravity ventilation is performed smoothly.

  The natural ventilation path 5 is formed by a duct provided in a space behind the top plate of the bay window roof 12, and is provided in a lateral arrangement from one side surface of the bay window roof 12 to the other side surface. In this embodiment, the natural ventilation path 5 is formed symmetrically, but is not limited to this. Openings 5a at both ends of the natural ventilation path 5 are located on both side surfaces of the bay window roof 12, and each opening 5a is provided with a louver or the like so as to prevent rainwater from entering. And the cross-sectional area of the center side of the said natural ventilation path 5 connected to the said discharge part 4 is made smaller than the cross-sectional area of the opening part 5a of the both ends of the said natural ventilation path 5, and a venturi effect is acquired. . Further, the natural ventilation path 5 has a tapered shape in which the cross-sectional area gradually decreases from the opening 5a to the center side, so that the airflow in the natural ventilation path 5 is not easily disturbed. .

  If it is said structure, since natural ventilation is performed by the natural ventilation path 5 connected to the said discharge part 4, construction cost and running cost can be suppressed. Moreover, since it can comprise as the bay window 11, it becomes advantageous on space utilization or a tax system. In addition, the cross-sectional area on the center side of the natural ventilation path 5 communicating with the discharge part 4 is smaller than the cross-sectional area on the end side of the natural ventilation path 5, Since the atmospheric pressure is reduced and the discharge of the outside air taken into the ventilation path 2 is promoted, natural ventilation is efficiently performed. Moreover, since the said natural ventilation path 5 is provided in the horizontal arrangement from the one side surface of the said bay window roof 12 to the other side surface, the said bay window roof 12 can be utilized effectively. Moreover, the natural wind which flows along the wall surface of a building can be used efficiently.

  Next, another embodiment will be described with reference to FIG. In the building ventilation structure 1 </ b> A of this embodiment, the thermal buffer layer 20 is formed on the indoor side of the ventilation path 2 by the partition member 6 provided in the ventilation path 2. The said partition member 6 consists of a curtain or a blind etc. which can be wound up, for example. The interval between the partition member 6 and the inner side surface portion 22, that is, the thickness of the heat buffer layer 20, is wider than the interval between the blind 23 and the inner side surface portion 22 in the building ventilation structure 1. Air is made to flow easily in the buffer layer 20.

  An indoor air introduction path 20a is formed on the upper side of the thermal buffer layer 20, and indoor air is taken into the thermal buffer layer 20 from the upper side, and the ventilation path 2 (the outer side surface portion 21) from the lower side. And the partition member 6) and is discharged from the discharge portion 4. In this embodiment, indoor air sucked by the ventilation fan 7 provided on the indoor wall is taken into the thermal buffer layer 20 through the exhaust passage 7a. When the wind is weak, indoor air taken into the heat buffer layer 20 may be discharged from the outside air introduction unit 3 to the outdoors.

  Thus, when the said heat buffer layer 20 is formed, it can suppress that the heat | fever in the ventilation path 2 is transmitted indoors. Here, if the indoor air cooled by the air-conditioning indoor unit is directly discharged to the outdoors by the ventilation fan 7, the cooled air is wasted. If the cooled indoor air is configured to pass through the thermal buffer layer 20, the cooled indoor air is effectively used to suppress the temperature rise of the thermal buffer layer 20 and to enter the heat indoors. Can be suppressed. In addition, when the indoor air heated by the air conditioning indoor unit is taken into the heat buffer layer 20, energy waste is reduced.

  In the building ventilation structure 1 </ b> A, a water supply unit 8 that supplies water to the partition member 6 is provided above the partition member 6. In this embodiment, the water supply unit 8 supplies water discharged from a drain pipe of an air conditioner provided indoors to the partition member 6. Of course, the water supply unit 8 may supply water from the water supply pipe to the partition member 6. Moreover, you may provide the valve | bulb for controlling the supply of the said water. Thus, if it is the structure which supplies water to the said partition member 6, the inside of the ventilation path 2 can be cooled with the heat of vaporization of the said water.

  FIG. 5 shows another example of the connection between the discharge part 4 and the natural ventilation path 5. In this example, the second natural ventilation path 5A is provided on the center side (small cross-sectional area) of the natural ventilation path 5, and the upper end portion of the discharge part 4 communicates with the second natural ventilation path 5A. ing. The cross-sectional area of the second natural ventilation path 5 </ b> A is smaller than the cross-sectional area on the center side, and a ventilation path is also formed between the second natural ventilation path 5 </ b> A and the natural ventilation path 5. By having such a multi-pipe ventilation path structure, airflow passing through the natural ventilation path 5 is easily rectified, and ventilation efficiency is improved.

  In the example shown in FIG. 5, a drain portion 5 b that discharges water (including condensed water and infiltrated rainwater) generated in the natural ventilation path 5 from the natural ventilation path 5 is provided in the natural ventilation path 5. It is provided downward on the center side (small cross-sectional area). For example, a tube (not shown) is connected to the water discharge end of the drain portion 5b, and water is discharged to the outdoors under the bay window by this tube. The tube is led to the lower end of the roof of the bay window 12, or the lower end of the drain pan (not shown) arranged below the drain 5b is positioned at the lower end of the roof of the bay window 12, and from the lower end of the roof. It can also be drained outdoors.

  As mentioned above, although embodiment of this invention was described with reference to drawings, this invention is not limited to the thing of embodiment shown in figure. Various modifications and variations can be made to the illustrated embodiment within the same range or equivalent range as the present invention.

DESCRIPTION OF SYMBOLS 1 Building ventilation structure 11 bay window 12 bay window roof 2 ventilation path 20 thermal buffer layer 21 outer side surface part 22 inner side surface part 23 blind 3 outside air introduction part 4 discharge part 5 natural ventilation path 5A 2nd natural ventilation path 6 partition member 7 ventilation fan 8 water supply part

Claims (7)

A double skin structure ventilation path composed of an outer side surface part and an inner side surface part, an outside air introduction part that takes outside air into the ventilation path, a discharge part that discharges outside air taken into the ventilation path, and the discharge part communicated with each other A building ventilation structure characterized in that a natural ventilation path is provided in a bay window, and the taken-in outside air is discharged to the outside from the opening of the natural ventilation path .   The building ventilation structure according to claim 1, wherein a cross-sectional area of a central side of the natural ventilation path communicating with the discharge portion is smaller than a cross-sectional area of an end opening of the natural ventilation path. .   The building ventilation structure according to claim 1 or 2, wherein the natural ventilation path is provided in a lateral arrangement from one side surface to the other side surface of the roof of the bay window.   The building ventilation structure according to any one of claims 1 to 3, wherein a thermal buffer layer is formed on an indoor side of the ventilation path by a partition member provided in the ventilation path. Ventilation structure.   The building ventilation structure according to claim 4, wherein indoor air passes through the thermal buffer layer and is discharged from the ventilation path.   6. The building ventilation structure according to claim 4, further comprising a water supply unit that supplies water to the partition member.   The building ventilation structure according to any one of claims 1 to 6, wherein a drain portion for discharging water generated in the natural ventilation path from the natural ventilation path is provided. Construction.

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