JP2016038178A - Natural ventilation system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a natural ventilation system capable of preventing the occurrence of a draft caused by natural ventilation and furthermore capable of unifying ventilation environment of a space to be ventilated.SOLUTION: A natural ventilation system 10 comprises: an under-floor space 3 positioned below a floor of a space 2 to be ventilated; an outdoor void 20 communicated with an external space 100; an in-floor intake 30 for communicating the external space 100 with an under-floor space 3; a floor communicating port 40 which is formed in an entire surface of the floor of the space 2 to be ventilated and communicates the under-floor space 3 with a space 2 to be ventilated; a void communicating port 50 for communicating the space 2 to be ventilated with the external void 20 to each other; a discharging port 90 to cause the outdoor void 20 to be communicated with the external space 100 to each other. The space 2 to be ventilated is naturally ventilated by enabling air to flow from the external space 100 to the external space 100 through in sequence the in-floor intake 30, the under-floor space 3, the floor communicating port 40, the space 2 to be ventilated, the void communicating port 50, the outdoor void 20 and the discharging port 90.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a natural ventilation system.

  Conventionally, a natural ventilation system for natural ventilation of a ventilation target space has been used. As such a natural ventilation system, a ventilation port for taking outside air from the external space into the ventilation target space and an exhaust port for exhausting air from the ventilation target space to the external space are provided in the ventilation target space. The thing which ventilates by this is common (for example, refer patent document 1).

Japanese Patent Laid-Open No. 07-305874

  However, the natural ventilation system according to Patent Document 1 has a problem of drafting because the wind speed inevitably increases in the vicinity of the ventilation port through which air in the external space directly flows. In addition, sufficient ventilation is performed in the vicinity of the ventilation opening in the ventilation target space, but on the other hand, sufficient ventilation is not performed at a point far from the ventilation opening, resulting in variations in the ventilation environment in the ventilation target space. It was.

  The present invention has been made in view of the above, and it is an object of the present invention to provide a natural ventilation system that can prevent the occurrence of drafts due to natural ventilation and can equalize the ventilation environment of the space to be ventilated. And

  In order to solve the above-described problems and achieve the object, the natural ventilation system according to claim 1 is a natural ventilation system that performs natural ventilation of a ventilation target space, and is located under the floor of the ventilation target space. A space, an outdoor void that communicates with the external space, an in-floor air supply port that interconnects the external space and the underfloor space, and an entire floor of the ventilation target space, the underfloor space A floor communication port that communicates with the ventilation target space, a void communication port that communicates the ventilation target space with the outdoor void, and an exhaust port that communicates the outdoor void with the external space. From the external space to the external space through the air supply port in the floor, the underfloor space, the floor communication port, the space to be ventilated, the void communication port, the outdoor void, and the exhaust port in this order. And air can flow Performing natural ventilation of the ventilation target space by the.

  The natural ventilation system according to claim 2, in the natural ventilation system according to claim 1, by substantially covering the floor communication port, pollutants existing in the external space are passed through the floor communication port. A covering material that prevents entry into the ventilation target space is provided.

  The natural ventilation system according to claim 3 is the natural ventilation system according to claim 1 or 2, wherein the air supply port in the floor is formed so that air can be taken in from the external space from any direction on a horizontal plane. did.

  According to the natural ventilation system of claim 1, since the outside air is taken in through the floor communication port formed on the entire floor of the ventilation target space and natural ventilation is performed, it is possible to prevent the occurrence of drafts due to natural ventilation. In addition, the ventilation environment in the ventilation target space can be made uniform.

  According to the natural ventilation system of the second aspect, since the covering material for preventing the contaminants from entering the ventilation target space is provided, even when the external space contains the contaminants, the ventilation target space The air can be kept clean, and the indoor environment of the ventilation target space can be optimized.

  According to the natural ventilation system of the third aspect, since the air inlet in the floor is formed so that air can be taken from the external space from any direction on the horizontal plane, regardless of the wind direction of the external space, Air in the external space can be taken into the ventilation target space, and the efficiency of natural ventilation can be improved.

It is sectional drawing which shows schematically the natural ventilation system which concerns on Embodiment 1 of this invention. It is AA arrow sectional drawing of FIG. 3A and 3B are cross-sectional views corresponding to the cross section taken along the line AA in FIG. 1, in which FIG. 3A shows the arrangement pattern A, FIG. 3B shows the arrangement pattern B, and FIG. It is a perspective view which shows a floor panel and a coating | covering material. It is a figure which shows the result of the analysis of the ventilation system which does not utilize an outdoor void. It is a figure which shows the result of the analysis of the system using the natural ventilation system which concerns on this Embodiment 1. FIG. It is a figure which shows the result of experiment. It is sectional drawing which shows schematically the natural ventilation system which concerns on Embodiment 2 of this invention. It is sectional drawing which shows schematically the natural ventilation system which concerns on Embodiment 3 of this invention.

  DESCRIPTION OF EMBODIMENTS Hereinafter, embodiments of a natural ventilation system according to the present invention will be described in detail with reference to the drawings. However, the present invention is not limited by this embodiment.

[Basic concept of the embodiment]
First, the basic concept of the embodiment will be described. The embodiment is generally a natural ventilation system that performs natural ventilation of a ventilation target space. Here, “natural ventilation” is a method of performing ventilation by a natural phenomenon such as a wind force or a temperature difference without using a blowing device such as a ventilation fan. In addition, the “space to be ventilated” is a space to be subjected to natural ventilation, and its use is arbitrary. However, in the embodiment, it is a room of a building having a plurality of rooms and is used as an office, for example. It will be described as being done. The specific structure of the ventilation target space is known except for special cases, and detailed description thereof is omitted. In addition, the shape and area of the ventilation target space can be arbitrarily determined.

  Further, a space outside the building having such a ventilation target space is referred to as an “external space”. This external space may be either an outdoor space or an indoor space, but in the present embodiment, it will be described as an outdoor space. It is assumed that there is a flow of air in a certain direction (referred to as “wind” if necessary) in the external space. The direction of the wind in this external space is “wind direction”, and the wind direction in the external space is The speed is referred to as “wind speed” as necessary.

[Specific contents of the embodiment]
Next, specific contents of the embodiment will be described.

(Embodiment 1)
First, the first embodiment will be described.

(Constitution)
First, the structure regarding the natural ventilation system 10 which concerns on this Embodiment 1 is demonstrated. FIG. 1 is a cross-sectional view schematically showing a natural ventilation system 10 according to the first embodiment. FIG. 2 is a cross-sectional view taken along the line AA of FIG. However, FIG. 2 is a simplified cross-sectional view for the purpose of illustrating the flow of air, and components that do not need to be illustrated for achieving the purpose are appropriately omitted. In the following description, the XX ′ direction in each figure is the width direction (X direction is right, X ′ direction is left), and YY ′ direction is the front-rear direction (Y direction is front, Y ′ direction ) And the ZZ ′ direction are referred to as the height direction (the Z direction is upward and the Z ′ direction is downward). In the following drawings, the air flow is shown by arrows.

(Configuration-Basic structure of the building)
First, the basic structure of the building 1 to which the natural ventilation system 10 is applied will be described. This building 1 is a building having a plurality of floors constructed by a known method. However, in the first embodiment, the illustration and description will be given focusing on only a single floor (hereinafter, the target floor), and the other floors (for example, the upper and lower floors of the target floor) are the same. The illustration and description are omitted because the natural ventilation system 10 can be applied. However, in FIG. 1, only a part of the roof slab is cut out.

  In this target floor, a double floor structure in which the floor panel 6 is disposed above the floor slab 5 and a double ceiling structure in which the ceiling panel 8 is suspended below the ceiling slab 7 are employed. In the following, the space between the floor panel 6 and the ceiling panel 8 is referred to as “space to be ventilated” 2, the space between the floor slab 5 and the floor panel 6 is referred to as “under-floor space” 3, the ceiling slab 7 and the ceiling panel. A space between the first and second spaces is referred to as a “ceiling space” 4. In addition, the width and height of each space are arbitrary and are not restricted to the aspect of illustration. For example, the floor area of each space may be different from each other.

(Configuration-natural ventilation system)
Next, the structure of the natural ventilation system 10 which concerns on this Embodiment 1 is demonstrated. As shown in FIG. 1 and FIG. 2 described above, the natural ventilation system 10 generally includes an outdoor void 20, an in-floor air supply port 30, a floor communication port 40, a void communication port 50, an air conditioner 60, and a ceiling air supply. A port 70, a ceiling communication port 80, and an exhaust port 90 are provided.

(Configuration-natural ventilation system-outdoor void)
The outdoor void 20 is a void that communicates at least the ventilation target space 2 and the external space 100 with each other. The outdoor void 20 is arranged along the vertical direction over the entire height of the building 1, and the upper end portion is located in the vicinity of the slab on the roof floor of the building 1 and has an open end (exhaust port 90. Details will be described later. The lower end is located near the foundation of the building 1 and is a closed end. And in planar view, as shown in FIG.1 and FIG.2, it arrange | positions in the center right side position, and it forms so that the ventilation object space 2 located in the left side of the said outdoor void 20 can be ensured widely.

  Here, the shape of the outdoor void 20 is arbitrary as long as it has a cavity through which air can flow. In the first embodiment, the horizontal void 20 is described as a rectangular tubular body. For example, the horizontal section may be a circular or other polygonal tubular body. Further, in the first embodiment, the description will be made assuming that they are arranged along the vertical direction. However, for example, a midway portion of an outdoor void may be curved along the width direction or the front-rear direction.

  A void communication port 50 is formed at an arbitrary position in contact with the ventilation target space 2 in the outdoor void 20, and an exhaust port 90 is formed at the upper end of the outdoor void 20. In such a configuration, the air generated in the external space 100 causes the air in the ventilation target space 2 to be drawn into the outdoor void 20 through the void communication port 50, rises inside the outdoor void 20, and exhausts 90. And discharged to the external space 100. In addition, since the principle by which air flows by such natural ventilation by a wind is well-known, description is abbreviate | omitted. Further, not only natural ventilation but also the chimney effect of the outdoor void 20 promotes the flow of air inside the outdoor void 20.

(Configuration-Natural ventilation system-Floor air supply port)
The in-floor air supply port 30 is an in-floor air supply means for taking the air in the external space 100 into the underfloor space 3 and is a floor for exhausting the air taken into the underfloor space 3 to the external space 100. It is an internal exhaust means. A plurality of the air supply openings 30 in the floor are arranged at predetermined intervals on the entire surface of the outer wall 9 surrounding the underfloor space 3 in the outer wall 9 of the building 1 (that is, the outer wall 9 positioned on the front, rear, left and right of the underfloor space 3). Each air supply port 30 in the floor is formed so as to penetrate the outer wall 9. When the wind blows, air is taken into the underfloor space 3 from the in-floor air inlet 30 located on the windward side, passes through the underfloor space 3, and is located on the leeward floor. 30 is exhausted to the external space 100. Unlike the case where only the part of the outer wall 9 surrounding the underfloor space 3 is formed by forming the in-floor air inlet 30 on the entire surface of the outer wall 9 surrounding the underfloor space 3 in this manner, It is possible to take in the air in the external space 100 from any direction. For example, when the in-floor air inlet 30 is formed only in the outer wall 9 positioned in front of and behind the underfloor space 3 in FIG. 2, when the wind along the front-rear direction blows in the outer space 100, the in-floor air inlet 30 is The air flows through the underfloor space 3, but the air hardly flows into the underfloor space 3 when a wind along the left-right direction blows in the external space 100. On the other hand, when the in-floor air inlets 30 are provided in the outer walls 9 located on the front, rear, left, and right sides of the underfloor space 3, air can flow into the underfloor space 3 when wind blows from any direction in the external space 100. it can. For example, as shown in FIG. 2, even when a northwest wind blows, a part of the outdoor void 20 becomes leeward, but air flows in at least a part of the underfloor space 3.

  Moreover, in order to take in the air of the external space 100 from any direction on the horizontal plane, it is desirable to devise the arrangement of the in-floor air inlets 30 and the arrangement pattern of the outdoor voids 20. Here, FIG. 3 is a cross-sectional view corresponding to the cross-section taken along the line AA in FIG. 1, where FIG. 3A is an arrangement pattern A, FIG. 3B is an arrangement pattern B, and FIG. Indicates an arrangement pattern C. In any of the arrangement patterns, the air flow is illustrated assuming that the eastern wind blows. Here, the arrangement pattern A has the same configuration as that of the natural ventilation system 10 of the first embodiment, and the arrangement pattern B has a configuration in which the outdoor void 20 is arranged so as to occupy the entire right area of the underfloor space 3. In the arrangement pattern C, the outdoor void 20 is arranged so as not to form the in-floor air supply port 30 in a part of the right outer wall 9 of the underfloor space 3 and to cover the remaining part of the outer wall 9 with the outdoor void 20. It is a configuration. As can be seen from these arrangement patterns, in the arrangement pattern B and the arrangement pattern C, the air flow is obstructed by the outdoor voids 20 and the outer wall 9 and the air does not sufficiently flow into the underfloor space 3, but this embodiment 1 In the arrangement pattern A shown, air can flow at least in the underfloor space 3 located on the right side, the front side, and the rear side of the outdoor void 20.

  However, since it can be considered that the direction in which the wind blows is limited depending on the installation environment of the building 1 and the like, in such a case, the in-floor air inlet 30 is not necessarily provided on the entire surface of the outer wall 9 located on the front, rear, left and right. However, it may be provided only where necessary.

(Configuration-Natural ventilation system-Floor communication port)
Returning to FIG. 1, the floor communication port 40 is a floor communication means for communicating the underfloor space 3 and the ventilation target space 2 with each other. The floor communication port 40 is a hole formed on the entire surface of the floor panel 6 so as to penetrate the floor panel 6 vertically.

  Here, a covering material 41 is disposed on the upper surface of the floor panel 6 so as to substantially cover the floor communication port 40. FIG. 4 is a perspective view showing the floor panel 6 and the covering material 41. The covering material 41 is a covering unit that substantially covers the floor communication port 40 to prevent contaminants existing in the external space 100 from entering the ventilation target space 2 through the floor communication port 40. Specifically, the covering material 41 is formed in a three-layer structure in which the lower layer portion 42, the middle layer portion 43, and the upper layer portion 44 are sequentially overlapped to form a set, and a plurality of the covering materials 41 are arranged without gaps over the entire floor slab 5. Arranged above the floor panel 6.

  Below, the structure of the floor panel 6 and the coating | covering material 41 is demonstrated in detail. First, the floor panel 6 is a part which supports the load of the thing arrange | positioned in the ventilation object space 2, and a person, Comprising: The plate-shaped part 6a and the support | pillar 6b are comprised. The plate-like portion 6a is a metal plate-like body having a predetermined square shape in a plan view, and a plurality of floor communication ports 40 penetrating up and down the plate-like portion 6a as shown in the figure. The center of the part 6a is provided radially. Moreover, the support | pillar 6b is a support member for supporting the plate-shaped part 6a, and is a metal cylinder arrange | positioned at the four corners of the plate-shaped part 6a. In this way, the underfloor space 3 is formed between the plate-like portion 6a and the floor slab 5 by arranging the plate-like portion 6a by the plurality of columns 6b.

  The lower layer portion 42 of the covering material 41 is a filter that prevents contaminants from flowing into the ventilation target space 2. The lower layer part 42 is directly mounted on the plate-like part 6 a of the floor panel 6, and is a sheet having a predetermined thickness having the same shape (square) as the plate-like part 6 a of the floor panel 6 in plan view. Here, a plurality of elliptical holes 42a are formed alternately in the lower layer portion 42 as shown in the figure, and the contaminants cannot pass through the portions excluding the elliptical holes 42a. Has been.

  The middle layer portion 43 of the covering material 41 is a filter that further prevents the contaminants from flowing into the ventilation target space 2. The middle layer portion 43 is laminated on the lower layer portion 42, and a sheet having a predetermined thickness whose shape in a plan view is the same shape (square) as the plate-like portion 6 a of the floor panel 6 and the lower layer portion 42 of the covering material 41. It is. Here, in the middle layer portion 43, a plurality of circular fine holes 43a are formed at positions that coincide with the elliptical holes 42a of the lower layer portion 42 described above. The hole 43a in the middle layer portion 43 is finer than the hole 42a in the lower layer portion 42, and air can pass through the hole 43a but cannot pass contaminants, and the air passes through the hole 43a. Part of the contaminant is removed without passing through.

  The upper layer portion 44 of the covering material 41 is a filter that further prevents contaminants from flowing into the ventilation target space 2. The upper layer portion 44 is laminated on the middle layer portion 43, and the shape in plan view is the same shape (square) as the plate-like portion 6a of the floor panel 6, the lower layer portion 42 of the covering material 41, and the middle layer portion 43. A sheet having a predetermined thickness. The upper layer portion 44 can be formed as a known carpet made of, for example, cotton, hemp, synthetic fiber, etc., and constitutes the floor surface of the ventilation target space 2. The upper layer portion 44 also has a function of filtering the air that has passed through the hole 43a of the middle layer portion 43, and can further prevent the contaminants from flowing into the ventilation target space 2.

  By installing the covering material 41 configured as described above on the floor panel 6, it is possible to adopt a configuration in which contaminants are inhibited while allowing air to pass. In addition, the elliptical holes 42a of the lower layer part 42 are alternately arranged, and the floor communication ports 40 of the floor panel 6 are arranged radially, so that the covering material 41 is oriented in any direction. Even if it is installed above, the positions of the holes 42a and the floor communication port 40 partially coincide with each other, so that the installation can be easily performed without worrying about the installation direction.

(Configuration-Natural ventilation system-Void communication port)
Returning to FIG. 1, the void communication port 50 is a communication means for allowing the ventilation target space 2 and the outdoor void 20 to communicate with each other. The void communication port 50 is formed at any position facing the ventilation target space 2 on the side surface of the outdoor void 20, but the floor communication port is necessary for air from the external space 100 to reach the entire ventilation target space 2. It is desirable to form it at a position far from 40, for example, it is desirable to form it at a position near the ceiling panel 8 as shown in the figure. Of course, a plurality of void communication ports 50 may be provided in one ventilation target space 2, and may be provided, for example, at two positions of the outdoor void 20 near the ceiling panel 8 and near the floor panel 6. .

(Configuration-Natural ventilation system-Air conditioner)
The air conditioner 60 is air conditioning means for air conditioning the ventilation target space 2. The air conditioner 60 is a known air-cooled or water-cooled air conditioner disposed in the ceiling back space 4, and heats or cools the air taken in the ceiling back space 4 from the ceiling air inlet 70. By blowing air to the ventilation target space 2, the ventilation target space 2 is air-conditioned. In addition, although the installation place of this air conditioner 60 is arbitrary and in this Embodiment 1, it demonstrates as what is arrange | positioned in the ceiling back space 4 as shown in figure, For example, the air conditioner 60 is arrange | positioned in the underfloor space 3. Instead of the ceiling air supply port 70, an underfloor air supply port (not shown) may be arranged on the floor panel 6 so as to blow conditioned air from under the floor.

(Configuration-natural ventilation system-ceiling air inlet)
The ceiling air inlet 70 is an air outlet that is air-conditioned by the air conditioner 60, and is provided at a plurality of locations on the ceiling panel 8.

(Configuration-Natural ventilation system-Ceiling communication port)
The ceiling communication port 80 is a communication means for allowing the ceiling back space 4 and the ventilation target space 2 to communicate with each other. The ceiling communication port 80 is a known vent provided at an arbitrary position in the ceiling panel 8, and the ceiling back space 4 becomes negative pressure due to suction of the air conditioner 60, so that Air is taken into the ceiling space 4 through the ceiling communication port 80.

(Configuration-Natural ventilation system-Exhaust port)
The exhaust port 90 is an exhaust means for exhausting the air in the outdoor void 20 to the external space 100. The exhaust port 90 is an opening provided in the vicinity of the upper end portion of the outdoor void 20 (that is, in the vicinity of the slab on the roof floor of the building 1). Although the specific position of the exhaust port 90 is arbitrary, it is preferable to allow wind ventilation by installing the exhaust port 90 at a position where the negative pressure is obtained when the wind blows from any direction. In the embodiment, it is installed at a position on the same horizontal plane as the roof of the building 1.

(Function)
Next, the operation of the natural ventilation system 10 described above will be described with reference to FIG. First, the air in the external space 100 is taken into the underfloor space 3 through the in-floor air inlet 30. Then, a part of the air taken into the underfloor space 3 flows inside the underfloor space 3, and another floor provided at a position facing the in-floor air inlet 30 through the underfloor space 3. The air is discharged to the external space 100 through the internal air supply port 30, and the remaining air is taken into the ventilation target space 2 through the floor communication port 40. Here, air can pass through the floor communication port 40, but contaminants cannot pass through the floor communication port 40 due to the function of the covering material 41 described above. Only the clean air that has been produced is supplied. In addition, although the pollutant repelled by the covering material 41 accumulates in the underfloor space 3, a predetermined amount of the pollutant is carried by the air flowing in the underfloor space 3 from the in-floor air inlet 30 to the external space 100. Therefore, it is possible to reduce the trouble of cleaning the underfloor space 3.

  A part of the air taken into the ventilation target space 2 is taken into the ceiling back space 4 through the ceiling communication port 80, air-conditioned by the air conditioner 60, and ventilated through the ceiling air supply port 70. The remaining air is taken into the outdoor void 20 through the void communication port 50. The air taken into the outdoor void 20 in this manner rises inside the outdoor void 20 and is exhausted to the external space 100 through the exhaust port 90 formed at the upper end of the outdoor void 20. Since such air flow is performed, only clean outside air can be taken into the ventilation target space 2. Furthermore, since the floor communication port 40 is formed on the entire surface of the floor panel 6 and air is evenly blown from the floor panel 6 to the ventilation target space 2, it is possible to prevent the draft in the ventilation target space 2. Moreover, natural ventilation which does not require a fan etc. can be performed by the pressure difference by wind and the chimney effect of the outdoor void 20, and high energy saving performance can be obtained.

(analysis)
Next, the result of the analysis for evaluating the performance of the natural ventilation system 10 described above will be described in comparison with the result of the analysis of the ventilation system that does not use the outdoor void 20.

  FIG. 5 is a diagram illustrating a result of analysis of a ventilation system that does not use the outdoor void 20. As shown in FIG. 5, as a ventilation system that does not use the outdoor void 20, wind is applied to the external space 100 with respect to three types of analysis models: an analysis model (a), an analysis model (b), and an analysis model (c). An analysis was conducted to evaluate the performance of ventilation when generated. In FIG. 5 and FIGS. 6 and 7 described later, components corresponding to those in the first embodiment will be described with the same names and the same reference numerals.

Here, in the analysis model (a), a natural ventilation port (100 cm ² / m ² ) is provided at a position corresponding to the ventilation target space 2 on the outer wall 9, and the air in the external space 100 is the natural ventilation port and the ventilation target space 2. This is a model configured to flow to the external space 100 sequentially through other natural ventilation ports.
Further, in the analysis model (b), an in-floor air inlet 30 (100 cm ² / m ² ) is provided in the outer wall 9 surrounding the underfloor space 3 as in the first embodiment, and the analysis model (b) is the same as in the first embodiment. By providing the floor communication port 40 in the floor panel 6, the air in the external space 100 is supplied to the floor air supply port 30, the underfloor space 3, the floor communication port 40, the ventilation target space 2, the floor communication port 40, the underfloor space 3, This is a model configured to flow into the external space 100 through the other floor air supply ports 30 sequentially.
The analysis model (c) has a configuration in which an underfloor partition is added to the configuration of the analysis model (b). The underfloor partition is a partition material that divides the underfloor space 3 into a plurality of spaces, and is a partition material that is vertically formed from the upper surface of the floor slab 5 to the lower surface of the floor panel 6. By forming the underfloor partition, the air taken into the underfloor space 3 through the in-floor air inlet 30 does not directly go out to the external space 100 through the other in-floor air inlet 30. It is conceivable to temporarily pass through the ventilation target space 2 via the floor communication port 40 and then return to the underfloor space 3 and exit to the external space 100 via the other air supply ports 30 in the floor. The improvement of the ventilation frequency of 2 can be aimed at.
Each analysis model includes the outdoor voids 20, but these outdoor voids 20 are not provided with the void communication ports 50, and air flows from the ventilation target space 2 to the inside of the outdoor voids 20. There is no.

  Here, the information corresponding to the item “Ventilation frequency” in FIG. 5 is the ventilation frequency in each direction when the ventilation frequency in each direction is derived by a known analysis method under the conditions of the wind direction in 16 directions and the wind speed of 2 m / s. The average value is shown. The information corresponding to the item “temperature distribution” and the item “wind velocity distribution” includes the temperature distribution and the wind velocity distribution derived by a known analysis method under the conditions of the north-northwest wind direction and the wind velocity of 2 m / s. Each is represented by a plan view with different hatching.

As a result of analysis under such conditions, in the analysis model (a), the ventilation rate is 8.0 times / h, which is sufficiently large, but referring to the temperature distribution, the air inflow portion (north-northwest) When the temperature is low and the wind speed distribution is referenced, it can be recognized that the draft of the ventilation target space 2 cannot be prevented because the wind speed at the air inflow portion is high.
Further, in the analysis model (b), the ventilation frequency is as low as 0.9 times / h, and ventilation is performed only in the underfloor space 3, and sufficient ventilation is not performed in the ventilation target space 2. I understand.
Further, in the analysis model (c), the ventilation frequency is 1.5 times / h, and although the ventilation frequency can be improved over the analysis model (b) by providing an underfloor partition, it is not a sufficient value. It can be recognized that sufficient ventilation is not performed in the ventilation target space 2.
Regarding analysis model (b) and analysis model (c), it is judged that the number of ventilations is small and it is not necessary to confirm the occurrence of draft, and the temperature distribution and wind speed distribution are not obtained. Is omitted.

  Thus, as is clear from the analysis results of the analysis model (a), the analysis model (b), and the analysis model (c), in the ventilation system that does not use the outdoor void 20, the ventilation target space 2 is sufficient. It can be recognized that proper ventilation and prevention of drafting cannot be achieved at the same time.

  Then, the result of the analysis which evaluates the performance of the natural ventilation system 10 using the outdoor void 20 shown in this Embodiment 1 is demonstrated. FIG. 6 is a diagram showing a result of system analysis using the natural ventilation system 10 according to the first embodiment. As shown in FIG. 6, as a ventilation system using the natural ventilation system 10 according to the first embodiment, three types of analysis models of an analysis model (d), an analysis model (e), and an analysis model (f) Was analyzed.

Here, the analysis model (d) is a model configured in the same manner as the natural ventilation system 10 according to the first embodiment, and specifically, the four rounds of the underfloor space 3 as in the first embodiment. A floor air supply port 30 (50 cm ² / m ² ) is provided in the outer wall 9, a floor communication port 40 is provided in the floor panel 6 as in the first embodiment, and the outdoor void 20 is provided in the same manner as in the first embodiment. By providing the void communication port 50, the air in the external space 100 is externally passed through the floor air supply port 30, the underfloor space 3, the floor communication port 40, the ventilation target space 2, the void communication port 50, and the outdoor void 20 in order. This is a model configured to flow into the space 100.
The analysis model (e) is a configuration in which the above-described underfloor partition is added to the configuration of the analysis model (d).
The analysis model (f) has the same configuration as the analysis model (d).

  Here, information corresponding to the item “frequency of ventilation”, the item “temperature distribution”, and the item “wind speed distribution” is substantially the same as the information shown in FIG. 5 described above. However, the analysis conditions differ between the analysis model (d) and the analysis model (e), and the analysis model (f). Specifically, the analysis model (d) and the analysis model (e) were analyzed under the condition of the wind speed of 2 m / s in the same manner as the analysis model (a) to the analysis model (c). In f), the analysis was performed under the condition of a wind speed of 10 m / s (that is, a condition assuming a strong wind).

As a result of the analysis under such conditions, in the analysis model (d), the ventilation frequency is 4.6 times / h, which is sufficiently secured. Furthermore, since air is uniformly supplied from the underfloor space 3 by providing the floor communication port 40 in the entire floor panel 6, the temperature distribution can be ensured uniformly, and the wind speed distribution can also be ensured uniformly. It can be recognized that the draft of the ventilation target space 2 can be prevented.
In the analysis model (e), the ventilation frequency is 4.5 times / h, which is sufficiently secured. However, this ventilation frequency was lower than the ventilation frequency (4.6 times / h) of the analysis model (d), and improvement of the ventilation frequency by adding an underfloor partition could not be confirmed. However, similarly to the analysis model (d), the temperature distribution can be ensured uniformly, and the wind speed distribution can be ensured uniformly low, and it can be recognized that the draft of the ventilation target space 2 can be prevented. .
Further, in the analysis model (f), the ventilation frequency is 10.5 times / h, which is sufficiently secured. Furthermore, the temperature distribution can be ensured uniformly, the wind speed distribution can be ensured uniformly and low, and the natural ventilation system 10 according to the first embodiment can prevent the occurrence of drafts even in strong winds. Can be recognized.

(Experiment)
Subsequently, using a full-scale model that reproduces the building 1 to which the natural ventilation system 10 described above is applied, a mannequin is placed in the ventilation target space 2 of the full-scale model, and the ventilation performance of the natural ventilation system 10 is evaluated. The experiment was conducted. FIG. 7 shows the results of the experiment. As shown in FIG. 7, regarding the natural ventilation system 10 according to the first embodiment, the ventilation frequency is changed to 3 times / h, 6 times / h, and 10 times / h, and the temperature distribution in the ventilation target space 2 is changed. , Measurement of PMV (Predicted Mean Vote) and PPD (Predicted Percentage Dissatisfied), measurement of mannequin equivalent temperature, calculation of unsatisfied person rate by upper and lower temperature difference, calculation of unsatisfied person rate by draft, respectively. The result of the experiment is shown in the column corresponding to each item in FIG. In either case, the experiment was conducted with the temperature of the outside air set at 19 ° C.

  Here, the information corresponding to the item “temperature distribution” represents the temperature distribution obtained by a known method in an elevational view with different hatching for each temperature. In addition, as information corresponding to the item “PMV (PPD)”, PMV and PPD calculated by a known method are described. The numerical value outside the parentheses indicates PMV, and the numerical value within the parentheses indicates PPD. The information corresponding to the item “Mannequin Equivalent Temperature” indicates the equivalent temperature of the mannequin placed in a state of being seated on a chair in the ventilation target space 2. Although this measuring method is arbitrary, it can measure using a glove thermometer etc., for example. The information corresponding to the item “upper and lower temperature difference unsatisfactory rate” indicates the unsatisfactory rate caused by the upper and lower temperature difference obtained by a known method. Each of the above values is based on the ISO standard.

  As is apparent from the experimental results in FIG. 7, it can be seen that the PPD can be kept at 11.9% even when the ventilation frequency is 10 times / h, and that satisfactory thermal comfort can be maintained even in strong winds. Further, it can be seen that the upper and lower temperature difference unsatisfactory rate and the draft unsatisfied rate can be 5% or less regardless of the number of ventilations.

(Effect of embodiment)
As described above, according to the natural ventilation system 10 of the first embodiment, the natural ventilation is performed by taking in the outside air through the floor communication port 40 formed on the entire surface of the floor of the ventilation target space 2. It is possible to prevent the occurrence of drafts and to make the ventilation environment in the ventilation target space 2 uniform.

  Moreover, since the covering material 41 for preventing the contaminant from entering the ventilation target space 2 is provided, the air in the ventilation target space 2 can be kept clean even when the external space 100 contains the contaminant. It is possible to optimize the indoor environment of the ventilation target space 2.

  Further, since the in-floor air inlet 30 is formed so as to be able to take in air from the external space 100 from any direction on the horizontal plane, the air in the external space 100 is subject to ventilation regardless of the wind direction of the external space 100. It can be taken into the space 2 and the efficiency of natural ventilation can be improved.

(Embodiment 2)
Next, the second embodiment will be described. The configuration of the second embodiment is substantially the same as the configuration of the first embodiment except where otherwise specified, and the configuration substantially the same as the configuration of the first embodiment is the same as that used in this embodiment. These symbols are attached as necessary, and the description thereof is omitted.

(Constitution)
Below, the structure regarding the natural ventilation system 200 which concerns on this Embodiment 2 is demonstrated. FIG. 8 is a cross-sectional view schematically showing a natural ventilation system 200 according to the second embodiment.

(Configuration-Basic structure of the building)
First, the basic structure of the building 210 to which the natural ventilation system 200 is applied will be described. The building 210 according to the second embodiment includes a machine room 220 in addition to the ventilation target space 2, the underfloor space 3, and the ceiling space 4 similar to the building 1 according to the first embodiment. Here, the machine room 220 is a known machine facility room in which devices for supplying power to the lighting of the building 210 and the like are arranged. In the present embodiment, the machine room 220 is a space extending from the floor slab 5 to the ceiling slab 7. In addition, the double floor structure and the double ceiling structure are not applied to the machine room 220.

(Configuration-natural ventilation system)
Next, the configuration of the natural ventilation system 200 according to Embodiment 2 will be described. As shown in FIG. 8, the natural ventilation system 200 according to the second embodiment schematically includes an outdoor void 20, an in-floor air supply port 30, a floor communication port 40, a void communication port 50, an air conditioner 60, and a ceiling. The air supply port 70, the ceiling communication port 80, the exhaust port 90, the external air conditioner 230, and the exhaust fan 240 are configured.

(Configuration-Natural ventilation system-External air conditioner)
The air conditioner 230 performs air conditioning by taking in the air of the external space 100, and air-conditioning the ventilation target space 2 by blowing the conditioned air to the ventilation target space 2 through the underfloor space 3. It is a known air-conditioning means, and is disposed inside the machine room 220. By providing the external air conditioner 230, it is possible to cope with a time when the thermal environment of the ventilation target space 2 cannot be comfortably maintained by natural ventilation (for example, a time when the outside air temperature is too low such as in winter). In addition, since the specific structure of this external air conditioner 230 is well-known, detailed description is abbreviate | omitted.

(Configuration-Natural ventilation system-Exhaust fan)
The exhaust fan 240 is an exhaust unit such as a known fan that exhausts the space 2 to be ventilated. The exhaust fan 240 is disposed inside the machine room 220 and sucks air from the ceiling space 4 and exhausts it to the external space 100. It is configured as follows. Since the specific structure of the exhaust fan 240 is known, detailed description thereof is omitted.

  Here, since the external air conditioner 230 and the exhaust fan 240 are devices that are also provided in the conventional underfloor air conditioning system, this embodiment is applied to a building to which the underfloor air conditioning system is applied. The natural ventilation system 200 shown in the second embodiment can be easily constructed by retrofitting the outdoor void 20, the in-floor air supply port 30, and the void communication port 50.

(Function)
Next, the operation of the natural ventilation system 200 described above will be described. First, when the outside air temperature is a temperature at which natural ventilation is possible, natural ventilation can be performed in the same manner as in the first embodiment. That is, the air in the external space 100 passes through the floor air supply port 30, the underfloor space 3, the floor communication port 40, the ventilation target space 2, the void communication port 50, the outdoor void 20, and the exhaust port 90 in order. To flow. On the other hand, when the outside air temperature is a temperature at which natural ventilation is possible, the in-floor air inlet 30 or the outdoor void 20 is closed to block the air flow. Although the specific method of this interruption | blocking is arbitrary, it can interrupt | block by operating the shutter which can be electrically operated, for example attached to the in-floor air inlet 30 or the outdoor void 20. Instead, the external air conditioner 230 and the exhaust fan 240 are operated. As a result, the air in the external space 100 is taken into the external air conditioner 230 to be air-conditioned and supplied to the underfloor space 3. The air supplied to the underfloor space 3 flows to the external space 100 through the floor communication port 40, the ventilation target space 2, the ceiling communication port 80, the ceiling back space 4, and the exhaust fan 240. Thus, in the natural ventilation system 200 shown in the second embodiment, it is possible to perform ventilation using the external air conditioner 230 and the exhaust fan 240 at a time when the outside air temperature is not suitable for natural ventilation.

(Effect of Embodiment 2)
Thus, according to the natural ventilation system 200 of the second embodiment, since the external air conditioner 230 and the exhaust fan 240 are provided, the external air conditioner 230 and the exhaust gas are exhausted when the outside air temperature is not suitable for natural ventilation. Underfloor air conditioning can be performed with the conventional configuration by operating the fan 240.

(Embodiment 3)
Next, the third embodiment will be described. The configuration of the third embodiment is substantially the same as the configuration of the second embodiment except where otherwise specified, and the configuration substantially the same as the configuration of the embodiment is the same as that used in this embodiment. These symbols are attached as necessary, and the description thereof is omitted.

(Constitution)
Below, the structure regarding the natural ventilation system 300 which concerns on this Embodiment 3 is demonstrated. FIG. 9 is a cross-sectional view schematically showing a natural ventilation system 300 according to the third embodiment.

(Configuration-Basic structure of the building)
First, the basic structure of the building 310 to which the natural ventilation system 300 is applied will be described. This building 310 includes a corridor 320 in addition to the ventilation target space 2, the underfloor space 3, the ceiling back space 4, and the machine room 220 similar to those in the second embodiment. Here, in Embodiment 3, a plurality of ventilation target spaces 2 are arranged on the same floor so as to communicate with the corridor 320, and the ventilation target spaces 2 are configured in the same manner. The hallway 320 is a space for spatially communicating a plurality of ventilation target spaces 2 provided on the same floor, and is located at a position between the ventilation target space 2 and the outdoor void 20. It is formed along the horizontal direction.

(Configuration-natural ventilation system)
Next, the configuration of the natural ventilation system 300 according to Embodiment 3 will be described. As shown in FIG. 9, the natural ventilation system 300 according to the third embodiment schematically includes an outdoor void 20, an in-floor air supply port 30, a floor communication port 40, a void communication port 50, an air conditioner 60, and a ceiling. The air supply port 70, the ceiling communication port 80, the exhaust port 90, the external air conditioner 230, and the exhaust fan 240 are configured. Each of these components is configured in the same manner as in the second embodiment. However, the floor communication port 40 is formed only on the floor located between the underfloor space 3 and the ventilation target space 2, and is not formed on the floor located between the underfloor space 3 and the hallway 320.

(Function)
Next, the operation of the natural ventilation system 300 described above will be described. First, the air in the external space 100 is taken into the underfloor space 3 through the in-floor air inlet 30. A part of the air taken into the underfloor space 3 flows inside the underfloor space 3 and is supplied to other in-floor air supply provided at a position facing the in-floor air inlet 30 through the underfloor space 3. The air is discharged to the external space 100 through the air opening 30, and the remaining air is taken into the ventilation target space 2 through the floor communication opening 40.

  A part of the air taken into the ventilation target space 2 is taken into the ceiling back space 4 through the ceiling communication port 80, air-conditioned by the air conditioner 60, and ventilated through the ceiling air supply port 70. 2 and the remaining air flows into the hallway 320. The air that has flowed into the hallway 320 moves along the hallway 320 while being combined with the air that has flowed into the hallway 320 from a plurality of other spaces to be ventilated 2, and the air of the outdoor void 20 through the void communication port 50 provided in the outdoor void 20. Incorporated inside. The air taken into the outdoor void 20 in this manner rises inside the outdoor void 20 and is exhausted to the external space 100 through the exhaust port 90 formed at the upper end of the outdoor void 20.

(Effect of Embodiment 3)
Thus, according to the natural ventilation system 300 of the third embodiment, the single outdoor void 20 can be shared by the plurality of ventilation target spaces 2 by using the corridor 320 as an air passageway. Natural ventilation can be performed without providing a unique outdoor void 20 for each ventilation target space 2 or a huge void in contact with the plurality of ventilation target spaces 2, and the construction cost can be reduced.

[Modifications to Embodiment]
Although the embodiments of the present invention have been described above, the specific configuration and means of the present invention can be arbitrarily modified and improved within the scope of the technical idea of each invention described in the claims. Can do. Hereinafter, such a modification will be described.

(About problems to be solved and effects of the invention)
First, the problems to be solved by the invention and the effects of the invention are not limited to the above contents, and may vary depending on the implementation environment and details of the configuration of the invention. May be solved, or only some of the effects described above may be achieved. For example, even if the generation of drafts cannot be completely prevented by the action of the natural ventilation system 10, 200, 300 according to each embodiment, the generation of drafts can be prevented by a technique different from the conventional technique. The problem of the present invention has been solved.

(About outdoor voids)
In each embodiment, it has been described that only one outdoor void 20 is installed in the building 1, 210, 310. However, the present invention is not limited to this, and a plurality of outdoor voids 20 may be installed.

(About air flow)
In each embodiment, no fan is provided except for the fans provided in the external air conditioner 230 and the air conditioner 60 and the exhaust fan 240, and the wind in the external space 100 and the negative pressure inside the outdoor void 20 are not provided. Although the description has been made on the assumption that air naturally flows, auxiliary fans may be provided in various places as necessary. For example, a fan may be provided in the in-floor air supply port 30, the void communication port 50, or the exhaust port 90 to promote air flow.

(About external air conditioner)
In the second embodiment and the third embodiment, the external air conditioner 230 is installed in the machine room 220. However, it may be arranged in another place such as the ventilation target space 2, the ceiling space 4, or the like. .

(Appendix)
The natural ventilation system of appendix 1 is a natural ventilation system that performs natural ventilation of a ventilation target space, and includes an underfloor space located under the floor of the ventilation target space, an outdoor void communicated with an external space, and the external space. An in-floor air inlet that communicates with the underfloor space, a floor communication port that is formed on the entire floor of the ventilation target space, and communicates the underfloor space and the ventilation target space with each other, and the ventilation A void communication port that allows the target space and the outdoor void to communicate with each other; and an exhaust port that allows the outdoor void and the external space to communicate with each other. Natural ventilation of the ventilation target space is achieved by allowing air to flow to the external space sequentially through the space, the floor communication port, the ventilation target space, the void communication port, the outdoor void, and the exhaust port. Do.

  The natural ventilation system according to supplementary note 2 is the natural ventilation system according to supplementary note 1, wherein the floor communication port is substantially covered so that pollutants existing in the external space are transferred to the ventilation target space through the floor communication port. And a covering material for preventing intrusion.

  The natural ventilation system according to appendix 3 is the natural ventilation system according to appendix 1 or 2, wherein the in-floor air inlet is formed so that air can be taken in from the external space from any direction on a horizontal plane.

(Additional effects)
According to the natural ventilation system described in appendix 1, since natural ventilation is performed by taking in outside air through the floor communication port formed on the entire floor of the ventilation target space, it is possible to prevent the occurrence of drafts due to natural ventilation. In addition, the ventilation environment in the ventilation target space can be made uniform.

  According to the natural ventilation system described in appendix 2, since the coating material is provided to prevent the contaminant from entering the ventilation target space, the air in the ventilation target space is included even when the external space contains the contaminant. Can be kept clean, and the indoor environment of the ventilation target space can be optimized.

  According to the natural ventilation system described in appendix 3, the air inlet in the floor is formed so as to be able to take in air from the external space from any direction on the horizontal plane. The air in the space can be taken into the ventilation target space, and the efficiency of natural ventilation can be improved.

DESCRIPTION OF SYMBOLS 1 Building 2 Ventilation object space 3 Underfloor space 4 Ceiling back space 5 Floor slab 6 Floor panel 6a Plate-like part 6b Column 7 Ceiling slab 8 Ceiling panel 9 Outer wall 10 Natural ventilation system 20 Outdoor void 30 In-floor air inlet 40 Floor communication port 41 Covering material 42 Lower layer part 42a Hole 43 Middle layer part 43a Hole 44 Upper layer part 50 Void communication port 60 Air conditioner 70 Ceiling air supply port 80 Ceiling communication port 90 Exhaust port 100 External space 200 Natural ventilation system 210 Building 220 Machine room 230 External adjustment Machine 240 Exhaust fan 300 Natural ventilation system 310 Building 320 Corridor

Claims (3)

A natural ventilation system for natural ventilation of a ventilation target space,
An underfloor space located below the ventilation target space;
An outdoor void communicating with the outside space;
An in-floor air inlet that communicates the external space and the underfloor space with each other;
A floor communication port formed on the entire floor of the ventilation target space to communicate the underfloor space and the ventilation target space with each other;
A void communication port for communicating the ventilation target space and the outdoor void with each other;
An exhaust port that allows the outdoor void and the external space to communicate with each other;
Air from the external space to the external space sequentially through the air supply port in the floor, the underfloor space, the floor communication port, the space to be ventilated, the void communication port, the outdoor void, and the exhaust port Natural ventilation of the space to be ventilated by enabling flow,
Natural ventilation system. A covering material that prevents the contaminants existing in the external space from entering the ventilation target space through the floor communication port by substantially covering the floor communication port,
The natural ventilation system according to claim 1. The in-floor air inlet is formed so that air can be taken from the external space from any orientation on a horizontal plane.
The natural ventilation system according to claim 1 or 2.

Images