JP5614943B2 - Structure - Google Patents

Description

  The present invention particularly relates to a structure applied to a building.

  In recent years, in order to reduce the heat island phenomenon in urban areas, there is a demand for a technique for suppressing the temperature rise of structures. Conventionally, a building described in Patent Document 1 below is known as a related technique in such a field. In this building, a water-retaining ceramic building mat is laid around the air-cooled chiller on the rooftop where the air-cooled chiller is installed. And it has been proposed to reduce the outside air intake temperature of the air-cooled chiller and improve the cooling efficiency by supplying water to the water-retaining ceramic building material mat by the “garden watering” effect.

JP 2001-221547 A

  However, when the temperature of the structure is lowered, further efficiency is required. In view of such a demand, an object of the present invention is to provide a structure capable of efficiently suppressing a temperature rise on the surface of the structure.

The structure of the present invention comprises a building and a porous concrete plate that is installed on the rooftop surface of the building and has air permeability and water retention, and the concrete plate is exposed with the bottom surface facing the rooftop surface. in state, is placed through the spacer on the roof floor, concrete board is obtained by blending 2% by weight of cotton molding, air dry density of the concrete plate and wherein 0.85 der Rukoto To do.

In this structure, since the concrete board is installed on the rooftop floor via a spacer, there is a gap between the concrete board and the rooftop floor, and an air layer is formed in the gap. The temperature of the air in the air layer decreases as the temperature of the night falls, and the air layer is shaded by the concrete plate even in the daytime, so the temperature is relatively difficult to rise. Therefore, the air layer is maintained at a relatively low temperature even in the daytime. Further, since there is an air layer between the concrete slab and the roof floor, less heat transfer to the roof floor from the concrete plate the temperature increases during the day.

Furthermore, since the concrete board has water retention, a water retention layer containing water is formed inside the concrete board. The water retaining layer water is included in, because of the low thermal conductivity of the water, to the rear surface of the concrete plate, and further that the time the heat of the roof floor is conducted is Osoka rapid roof floor High temperature is prevented. As a result, the temperature rise of the rooftop floor surface during the daytime can be kept low.

Moreover, the structure of this invention is good also as the thermal-insulation coating material being apply | coated to the upper surface of a concrete board. In this case, since the temperature rise of the concrete board in the daytime is reduced by the thermal barrier paint, as a result, the temperature rise of the rooftop surface can be further suppressed.

In addition, the structure of the present invention may further include a water spray means for spraying water on the concrete board. If water having a temperature lower than the air temperature is distributed by this watering means, the concrete plate is cooled, and the temperature rise of the rooftop floor surface can be further suppressed.

Further, the structure of the present invention, a building, a concrete slab which is installed on the roof floor of the building has a breathability and water retention, and the air conditioning outdoor unit than concrete slab in the building of the roof is provided above The concrete board is installed on the rooftop floor via a spacer, and the air conditioner outdoor unit sucks cooling air from below through the air intake.

  In this structure, the air conditioner outdoor unit draws cooling air from below. The cooling air passes from the air layer having a relatively low temperature through the inside of the air-permeable concrete plate in the thickness direction and is sent below the air conditioner outdoor unit. In this case, since the air layer is at a relatively low temperature, the cooling air sent below the air conditioner outdoor unit is also at a relatively low temperature. Therefore, the cooling air sucked into the air-conditioning outdoor unit is relatively low temperature, and the cooling efficiency of the air-conditioning outdoor unit can be increased.

  According to the structure of the present invention, the temperature rise on the structure surface can be efficiently suppressed.

It is a perspective view which shows the rooftop part of the building which is 1st Embodiment of the structure of this invention. It is sectional drawing which shows a part of rooftop part of FIG. It is sectional drawing which expands and shows a concrete board. It is sectional drawing which shows a part of roof part of the building of the object of Experiment 3 and 4. It is a graph which shows the temperature transition of the result of an experiment, a horizontal axis shows time and the vertical axis | shaft has shown temperature. It is sectional drawing which shows the rooftop part of the building which is 2nd Embodiment of the structure of this invention.

  Hereinafter, a building as a preferred embodiment of a structure according to the present invention will be described in detail with reference to the drawings.

(First embodiment)
As shown in FIGS. 1 and 2, in a building 1, a large number of rectangular concrete plates 11 are laid vertically and horizontally on a concrete rooftop surface 5 of a building body 3 that receives direct sunlight in the daytime. Yes. The concrete plates 11 are arranged in two rows and three rows with no gaps, and one block consists of six blocks of the concrete plate 11 arranged vertically and horizontally with a gap 15 between them. As shown in FIG. 2, four rubber spacers 13 are attached to the lower surface 11 b of the concrete plate 11 as spacers, and the concrete plate 11 is installed on the rooftop floor surface 5 through the spacer 13. .

  Due to the presence of the spacer 13, there is a gap between the lower surface 11 b of the concrete plate 11 and the rooftop floor surface 5, and an air layer 21 is formed in this gap portion. The thickness of the air layer 21 (that is, the height of the spacer 13) is preferably 1/10 to 1/5 of the thickness of the concrete plate 11. If the height of the spacer 13 is too higher than this, there is a problem that it is easily damaged when a load is applied on the concrete plate 11. For example, here, the thickness of the concrete plate 11 is 50 mm, and the height of the spacer 13 is 10 mm. Further, on the roof of the building 1, there is provided a watering device 17 for spraying tap water on the upper surface 11 a of the concrete plate 11 laid out. The general tap water temperature is about 28 ° C. even in the daytime.

  On the upper surface 11a of the concrete plate 11, a thermal barrier coating layer 12 is formed by applying a thermal barrier coating that exhibits a heat insulating effect. As such a thermal barrier paint, for example, a coating type heat insulating material containing aluminosilicon soda glass described in JP-A-2002-105385 can be employed. In addition, a heat insulating paint corresponding to this can be obtained on the market under the trade name GAINA.

Hereinafter, the concrete board 11 is further demonstrated. The concrete board 11 is a porous concrete board which has water retention and air permeability and is also called “wet porous concrete”. Specifically, the concrete plate 11 is formed into a rectangular plate shape by blending 30% cement, 20% shells, 15% pearlite, 30% water, 2% cotton, and 3% adhesive. And the concrete board 11 is prepared so that air dry specific gravity 0.85, weight water retention 30%, porosity 20%, bending strength 1.8N / mm < ² >, aeration coefficient 0.6m / s / cm, etc. may be shown. Has been. Here, the weight of the concrete plate 11 can be reduced by using a lightweight material such as a shell piece or pearlite. Instead of this, wet porous concrete described in Japanese Patent Application Laid-Open No. 2003-238224 may be employed as the material of the concrete plate 11.

  In order to achieve the effects of the present invention appropriately, the weight retention of the concrete plate 11 is preferably 10% to 30%, and more preferably 15% to 25%. Moreover, it is preferable that the ventilation coefficient of the concrete board 11 is 0.4-3.0 m / s / cm, and it is still more preferable that it is especially 0.6-2.0 m / s / cm. It is possible to adjust the weight retention rate and air permeability coefficient of the concrete plate 11 to desired values by appropriately adjusting the particle size of the shell pieces and pearlite blended in the concrete plate 11.

  Then, the effect by the structure of such a building 1 is demonstrated.

  In this building 1, the concrete board 11 is installed on the rooftop floor 5 via the spacers 13, so there is a gap between the concrete board 11 and the rooftop floor 5, and an air layer 21 is formed in the gap. The The temperature of the air in the air layer 21 decreases as the nighttime temperature decreases, and the air layer 21 is shaded by the concrete plate 11 even in the daytime, so that the temperature is relatively difficult to increase. Therefore, the air layer 21 is maintained at a relatively low temperature even in the daytime. Moreover, since the air layer 21 exists between the concrete board 11 and the rooftop floor surface 5, there is also little heat conduction from the concrete board 11 to which the temperature rises in the daytime to the rooftop floor surface 5.

  Further, since the concrete plate 11 has water retention, a water retention layer containing water is formed inside the concrete plate 11. Since moisture is contained in the water retaining layer and the thermal conductivity of the moisture is low, the time for conducting heat to the lower surface 11b of the concrete board 11 and further to the rooftop floor surface 5 is delayed, so that the rooftop The rapid high temperature of surface 5 is prevented. As a result of the above, according to the configuration of the building 1, the temperature rise of the rooftop floor surface 5 during the daytime can be kept low.

  Moreover, since the thermal barrier coating layer 12 is formed on the upper surface 11a of the concrete plate 11 that receives direct sunlight in the daytime, the temperature rise of the concrete plate 11 during the daytime is reduced by the thermal barrier coating. As a result, the temperature rise of the rooftop floor surface 5 can be further suppressed. In addition, when the temperature is higher than the temperature of the tap water (generally 28 ° C.), the concrete plate 11 is cooled by spreading the tap water on the concrete plate 11 by the water irrigation device 17. The temperature rise of the rooftop floor surface 5 can be further suppressed.

  On the roof of this building 1, it can be considered that the following phenomenon occurs in the daytime. If the nighttime temperature is 26 ° C. and the daytime temperature is 36 ° C., the air layer 21 cooled to 26 ° C. at night is the shade of the concrete plate 11 even in the daytime, as shown in FIG. The temperature of the air layer 21 only rises to about 28 ° C. At this time, the lower surface 11b of the concrete board 11 is also about 28 degreeC. Further, the temperature of the upper surface 11a of the concrete board 11 is about 60 ° C. due to direct sunlight when there is no thermal barrier coating layer 12, but is suppressed to about 50 ° C. by the action of the thermal barrier coating layer 12. .

  There is a temperature difference between the upper surface 11a (temperature of 50 ° C.) and the lower surface 11b (temperature of 28 ° C.) of the concrete plate 11, and the concrete plate 11 has air permeability. Therefore, the concrete is directed from the air layer 21 toward the upper surface 11a. Ascending ventilation Y penetrating the plate 11 in the thickness direction is generated. Note that air is supplied to the air layer 21 through the gap 15. At this time, the rising airflow Y at 28 ° C. reaches about 40 ° C. on the lower surface 11 b and reaches the upper surface 11 a while the temperature rises due to the temperature gradient inside the concrete plate 11. The ascending ventilation has a temperature of 28 ° C. and a humidity of 60% in the vicinity of the lower surface 11b, but water vapor contained in the ascending air Y condenses inside the concrete board 11 having water absorption, and in the vicinity of the upper surface 11a, the temperature is 40 ° C. and the humidity is 50. %. Thus, the temperature immediately above the concrete plate 11 is also relatively low and can be suppressed to about 40 ° C.

  The present inventors conducted an experiment to verify the effect of reducing the temperature rise of the rooftop floor surface 5 in the building 1. In this experiment, the temperature of the lower surface 11b of the concrete board 11 in the building 1 was measured over 2 days (Experiment 1). In addition, by periodically irrigating the concrete plate 11 using the water irrigation device 17, the concrete plate 11 retains 10% by weight, and the other conditions are the same as those in Experiment 1, and the lower surface 11 b is similarly formed. The temperature was measured (Experiment 2).

  For comparison, as shown in FIG. 4, the temperature of the lower surface 11 b of the concrete plate 11 was similarly measured when the concrete plate 11 was directly installed on the rooftop floor surface 5 without using the spacer 13 (experimental). 3). In addition, by periodically irrigating the concrete plate 11 using the water irrigation device 17, the concrete plate 11 retains 10% by weight, and the other conditions are the same as those in Experiment 3, and the temperature of the lower surface 11 b is similarly set. Was measured (Experiment 4). It is considered that the temperature of the lower surface 11b of the concrete plate 11 measured in Experiments 1 to 4 is substantially equal to the temperature of the rooftop floor surface 5.

  FIG. 5 shows the transition of the temperature for two days according to Experiments 1 to 4. For comparison, the transition (graph 5) of the temperature of the rooftop floor surface 5 when the concrete plate 11 is not installed is superimposed on FIG.

  Here, when the result of Experiment 1 is compared with the result of Experiment 3, in Experiment 3, the maximum temperature of the lower surface 11b in the daytime reaches about 34 ° C., whereas in Experiment 1, the maximum temperature of the lower surface 11b is It is suppressed to about 30 ° C. Therefore, it was found that the temperature rise of the rooftop floor surface 5 can be suppressed by installing the concrete plate 11 not directly on the rooftop floor surface 5 but via the spacer 13.

  Further, paying attention to the result of Experiment 2, it can be seen that the maximum temperature of the lower surface 11b in the daytime is suppressed to about 28 to 29 ° C., which is lower than that of Experiment 1. Therefore, it has been found that by using the watering device 17 to flood the concrete plate 11, the temperature rise of the rooftop floor surface 5 can be further suppressed. In addition, when such a concrete board 11 is not installed on the rooftop floor surface 5 at all, the temperature of the rooftop floor surface 5 has reached about 46 degreeC (graph 5).

(Second Embodiment)
As shown in FIG. 6, the building 201 further includes an air-conditioning outdoor unit 207 in addition to the building 1. That is, the outdoor unit 207 of the air conditioning equipment used in the room of the building 201 is installed on the roof of the building 201. The air conditioner outdoor unit 207 is fixed to the rooftop floor surface 5 via the base legs 209 and is located above the concrete plate 11. Inside the housing 207a of the air conditioning outdoor unit 207 is incorporated a radiator 207b that radiates heat from the refrigerant of the air conditioning equipment. An intake port 207c opened downward is provided on the bottom surface of the housing 207a, and an exhaust port 207d opened upward is provided on the top surface of the housing 207. The air-conditioning outdoor unit 207 draws cooling air A from the intake port 207c and exhausts it from the exhaust port 207 by a built-in fan device (not shown), thereby circulating air in the housing 207a to dissipate the radiator 207b. Cool down.

  The cooling air A of the air conditioning outdoor unit 207 is sent from the air layer 21 having a relatively low temperature through the inside of the air-permeable concrete plate 11 in the thickness direction and below the air conditioning outdoor unit 207. And since the temperature rise of the rooftop floor 5 in the daytime and the temperature rise just above the concrete board 11 are suppressed as mentioned above, the cooling air A sent below the air-conditioning outdoor unit 207 is also comparatively comparative. It is low temperature. Therefore, the cooling air A having a relatively low temperature is sucked into the air-conditioning outdoor unit 207 and the radiator 207b is efficiently cooled. As a result, the cooling efficiency of the air-conditioning outdoor unit 207 can be increased.

  The present invention is not limited to the embodiment described above. For example, the present invention can be applied not only to the roof of a building but also to the wall surface of the building. Further, the present invention is not limited to buildings, and can also be applied to a concrete building structure (for example, a bridge girder) that causes a heat island phenomenon. Further, in the embodiment, the spacer 13 is interposed between the concrete plate 11 and the rooftop floor surface 5, but in the present invention, instead of this structure, the concrete plate and the spacer portion are integrally molded. May be. That is, you may integrally mold the leg part of the shape similar to the spacer 13 so that it may protrude below from the lower surface of a concrete board. According to such a structure, the spacer can be easily manufactured.

  The structure of the present invention is suitably used particularly for a concrete building that causes a heat island phenomenon, and makes it possible to efficiently suppress the temperature rise of the rooftop surface.

  DESCRIPTION OF SYMBOLS 1 ... Building (structure), 3 ... Building main body (structure main body), 5 ... Roof top surface (surface of structure main body), 11 ... Concrete board, 12 ... Thermal insulation coating layer, 13 ... Spacer, 17 ... Water spray Apparatus, 207 ... Air conditioner outdoor unit, 207c ... Intake port.

Claims (4)

A building and a porous concrete plate installed on the rooftop surface of the building and having air permeability and water retention;
The concrete plate is installed with a spacer on the rooftop floor surface with the lower surface exposed to the rooftop floor surface ,
The concrete board is formed by blending 2% by weight of cotton,
Air dry specific gravity structures, wherein 0.85 der Rukoto of the concrete slab.   The structure according to claim 1, wherein a thermal barrier coating is applied to an upper surface of the concrete plate.   The structure according to claim 1 or 2, further comprising water-spreading means for spraying water on the concrete board. A building, a concrete plate installed on the rooftop surface of the building and having air permeability and water retention, and an air conditioner outdoor unit provided above the concrete plate on the roof of the building,
The concrete plate is installed on the rooftop surface via a spacer,
The air conditioning outdoor unit is
A structure characterized in that cooling air is sucked from below through an air inlet.

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