JP5430973B2 - Temperature rise suppression system - Google Patents

Description

  The present invention relates to a temperature rise suppression system that suppresses an increase in ambient temperature by being provided on a floor surface of a building rooftop or a balcony.

  For the purpose of suppressing the heat island phenomenon, a technology is known in which porous ceramics is laid on the floor of buildings, balconies, etc., and the temperature of the building is suppressed by the heat of vaporization of the water retained by the porous ceramics. (For example, refer to Patent Document 1).

JP 2003-105883 A

  By the way, in the conventional temperature rise suppression system, a water spray pipe is stretched over the entire floor surface such as a rooftop or a balcony, and water can be supplied over a wide area to the porous ceramics laid on the floor surface. However, if the sprinkling pipes are stretched over the entire floor surface, the labor and cost of piping construction will be increased.

  An object of the present invention is to provide a temperature rise suppression system that can easily supply water to the entire floor surface without piping a sprinkler pipe to a floor surface such as a rooftop or a balcony unlike the conventional one.

The invention according to claim 1 is, for example, as shown in FIGS. 1 to 8, in a temperature rise suppression system that suppresses a rise in ambient temperature by being provided on the floor 2 a of the roof of the building 1 or the balcony 2,
The floor surface 2a is provided with a water gradient that decreases from the building-side end of the floor 2a toward the outer-side end,
On the floor surface 2a, a plurality of side wall members 11 having a predetermined length are arranged along the gradient direction of the floor surface 2a and at a predetermined interval in a direction perpendicular to the gradient direction of the floor surface 2a. In addition, a plurality of partition members 12 having a predetermined height are installed between the plurality of side wall members 11, 11 at a predetermined interval along the length direction of the plurality of side wall members 11, 11. Further, a waterproof sheet 13 is laid on a portion surrounded by the plurality of side wall members 11 and 11 and partition members 12 and 12 respectively installed between both end portions in the length direction of the plurality of side wall members 11 and 11. A plurality of water storage units 10, 10 are arranged along the gradient direction of the floor surface 2a,
A plurality of block members 14 having water retention performance and permeation performance are laid in the plurality of water storage units 10 and 10,
Water supply means 15 for supplying water to the water storage unit 10 is provided in the vicinity of the water storage unit 10 located above the gradient direction of the floor surface 2a.
Below the floor surface 2a in the gradient direction, there is provided a drain hole 16 for discharging water overflowing from the water reservoir 10 located below the floor surface 2a in the gradient direction ,
The block material 14 is formed so that the upper surface of the block material 14 is overhanging the lower portion by setting the upper surface of the block material 14 to have a larger area than the lower surface.
When the block members 14 and 14 are adjacent to each other, the upper portions of the adjacent block members 14 and 14 are in contact with each other, and the cavity 14c formed between the opposing side portions of the adjacent block members 14 and 14 is: An accommodation space for accommodating the partition member 12 is provided.

In addition, as the said block material 14, without adding sand and without adding the additive which supplements intensity | strength, it is 50-62 weight% of pumice (dry specific gravity is 0.4) of particle size 3-20mm, and Portland cement. For example, a mixture of 50% to 38% by weight of water and 40% to 50% by weight of water mixed and kneaded with ready-mixed concrete placed in a mold can be mentioned.
In addition, for example, natural fibers such as coconut, non-woven fabric, glass wool or rock wool formed may be used.

According to the invention described in claim 1, a plurality of the side wall members 11 are arranged on the floor surface 2 a, a plurality of the partition members 12 are installed between the plurality of side wall members 11, 11, By laying a waterproof sheet 13 in a portion surrounded by the side wall members 11 and 11 and partition members 12 and 12 installed between both end portions in the length direction of the plurality of side wall members 11 and 11, the floor surface Since the plurality of water storage units 10, 10 are arranged side by side along the gradient direction of the floor surface 2a on 2a, the plurality of water storage units 10, 10 are provided in a wide area with respect to the floor surface 2a. Will be. Furthermore, since water has a property of depriving the surroundings of a predetermined amount of heat when it evaporates, a plurality of the block members 14 are spread over a plurality of water storage portions 10 and 10 provided in a wide area with respect to the floor surface 2a. Therefore, when the water permeated into and held by the block material 14 evaporates, it evaporates while taking away the heat around the block material 14, so that unlike the conventional case, a water spray pipe is provided on the floor surface 2a. Even without piping, it is possible to suppress an increase in the temperature of the floor surface 2a or to lower the temperature in a wide range with respect to the floor surface 2a. As a result, the rise in the temperature of the balcony 2 can be suppressed or the temperature can be lowered, and further, the rise in the temperature of the building 1 can also be suppressed, so that a comfortable living environment can be formed. It becomes.
The floor surface 2a is provided with a water gradient that decreases from the building-side end portion to the outer-side end portion of the floor surface 2a, and the plurality of water storage portions 10 and 10 are arranged in the gradient direction of the floor surface 2a. Therefore, it is only necessary to supply water from the water supply means 15 provided in the vicinity of the water storage portion 10 located above the gradient direction of the floor surface 2a. The water can be easily distributed from the water storage unit 10 located at the lower side to the water storage unit 10 located below, and the water overflowing from the water storage unit 10 located below the gradient direction of the floor surface 2a 16 can be reliably discharged. Furthermore, since the depth of the water stored in the plurality of water storage portions 10 can be reduced by setting the height of the partition member 12 low, the gradient direction of the floor surface 2a from the water supply means 15 can be reduced. The water supplied to the water storage unit 10 located above the water storage unit 10 located below the floor surface 2a in the gradient direction can be more easily distributed, and the bad odor caused by the water retention Generation of germs and insects can be surely prevented.
Further, the block member 14 is formed so that the upper surface of the block member 14 is overhanging the lower portion by setting the upper surface of the block member 14 to have a larger area than the lower surface. By adjoining the block members 14, 14, the upper portions of the adjacent block members 14, 14 come into contact with each other and the lower portions are separated from each other. Thus, the cavity 14c can be formed.
Moreover, since this cavity 14c is used as a storage space for storing the partition member 12, the block member 14 is stored in the storage spaces 10 and 10 in a state in which the partition member 12 is stored in the storage space. Can be laid without gaps.
Furthermore, since the said cavity 14c is formed between the side parts which the said adjacent block materials 14 and 14 oppose, it will lead in the said water storage part 10 vertically and horizontally. As a result, the inside of the cavity 14c can be used as a water flow path, so that unlike the conventional case, water can be easily introduced into the plurality of water storage portions 10 and 10 without providing a watering pipe on the floor surface 2a. Can be spread.

The invention according to claim 2 is the temperature rise suppression system according to claim 1, for example, as shown in FIGS.
A lawn 14a is planted on the upper surface of at least one block member 14 among the plurality of block members 14, 14.

According to the invention described in claim 2, the lawn 14 a is planted on the upper surface of at least one of the plurality of block members 14, 14. Therefore, the temperature rise around the floor 2a on which the block material 14 is provided can be suppressed.
Moreover, since the upper surface of the block material 14 can be covered with the turf 14a in this way, the portion where the block material 14 on which the turf 14a is planted can be greened, and the appearance is excellent.

The invention according to claim 3 is the temperature rise suppression system according to claim 1 or 2, as shown in FIGS. 2 and 7, for example.
A ceramic tile 14b is attached to the upper surface of at least one block member 14 among the plurality of block members 14, 14.

According to the invention described in claim 3, since the ceramic tile 14b is a porous body, even if the ceramic tile 14b is attached to the upper surface of the block material 14, the ceramic tile 14b penetrates and is held in the block material 14. Water can be reliably evaporated through the ceramic tile 14b.
Moreover, since the ceramic tile 14b is attached to the upper surface of at least one block member 14 among the plurality of block members 14, 14, the upper surface of the block member 14 can be given a quaint finish, and the appearance Excellent in properties. Furthermore, by arranging the block material 14 to which the ceramic tile 14b is attached and the block material 14 to which the grass 14a is provided, the appearance can be further improved.

The invention according to claim 4 is the temperature rise suppression system according to any one of claims 1 to 3 , for example as shown in FIG.
An irrigation pipe 17 that is connected to the water supply means 15 and that pours water into the water reservoir 10 is disposed in the cavity 14c.

According to the invention described in claim 4 , for example, even if the area of the water reservoir 10 is large, the irrigation pipe 17 connected to the water supply means 15 can be disposed in the cavity 14c. The water supplied from the water supply means 15 can be quickly and reliably stored in the water storage unit 10.

The invention according to claim 5 is the temperature rise suppression system according to any one of claims 1 to 4 , as shown in FIGS. 4, 5, and 8, for example.
The gradient of the floor surface 2a is set to about 1/50.

According to the invention described in claim 5 , since the slope of the floor surface 2a is set to about 1/50, the floor surface 2a is in a relatively gently inclined state. Accordingly, the depth of water stored in the plurality of water storage units 10 and 10 can be reliably reduced, so that the water storage unit 10 located above the water supply means 15 in the gradient direction of the floor surface 2a can be used. The supplied water can be more easily distributed to the water storage section 10 located below the floor surface 2a in the gradient direction, and the generation of bad odors, germs and insects caused by the retention of the water is more sure. Can be prevented.

The invention according to claim 6 is the temperature rise suppression system according to any one of claims 1 to 5 , for example, as shown in FIGS.
The block member 14 is integrally fixed and accommodated in a resin case 20;
The case 20 includes a bottom plate portion 21 having a plurality of holes 21 a, 21 a... That communicates the inside and the outside of the case 20, and a side plate portion that rises along the side surface of the block member 14 from the peripheral edge of the bottom plate portion 21. 22.

According to the sixth aspect of the present invention, the block member 14 is integrally fixed and accommodated in the resin case 20, so that the block member 14 is not accommodated in the case 20. Thus, the thickness of the block member 14 can be reduced. As a result, the amount and weight of the block material 14 and the labor and cost associated with the manufacture of the block material 14 can be reduced. Further, even if the thickness of the block material 14 is reduced, the block material 14 is fixedly accommodated in the case 20 and thus it is possible to ensure strength.
Moreover, since the case 20 is made of resin, it is preferable because it is easy to mold and can be formed thin.
Further, the bottom surface and the side surface of the block material 14 can be covered by the bottom plate portion 21 and the side plate portion 22 of the case 20 so that the top surface of the block material 14 can be exposed. Can be used in the same manner as when the case is not stored in the case 20.
Further, since the bottom plate portion 21 has a plurality of holes 21a, 21a... Communicating the inside of the case 20 with the outside, the bottom plate portion 21 is supplied to the water storage section 10 through the plurality of holes 21a, 21a. It is possible to reliably infiltrate and retain the water that has been discharged into the block member 14, and to reliably drain the water in the case 20 to the water storage unit 10. That is, water can be reliably circulated between the case 20 and the water reservoir 10.

The invention according to claim 7 is the temperature rise suppression system according to claim 6 , as shown in FIGS. 10, 11, and 15, for example.
The bottom plate portion 21 is formed in a quadrangular shape, and the side plate portion 22 rises from the four side edges of the bottom plate portion 21 along the side surfaces of the block material 14 to thereby form four side surface portions 23, 24, 25. , 26,
The side plate portion 22 includes projecting portions 23a and 24a provided to project from the central portions in the width direction of the two side surface portions 23 and 24 among the four side surface portions 23, 24, 25 and 26, and the remaining two. Each of the side portions 25 and 26 has recesses 25a and 26a provided at the center in the width direction,
When arranging the cases 20 next to each other, the protrusions 23 a (24 a) of one case 20 out of the cases 20, 20 adjacent to each other can be fitted into the recesses 25 a (26 a) of the other case 20. It is characterized by being.

According to the invention described in claim 7 , the side plate portion 22 is provided so as to protrude from the center portion in the width direction of the two side surface portions 23, 24 among the four side surface portions 23, 24, 25, 26. Convex portions 23a, 24a and concave portions 25a, 26a provided at the center portions in the width direction of the remaining two side surface portions 25, 26, respectively, and are adjacent to each other when the cases 20 are arranged side by side. Of the cases 20 and 20, the convex portion 23 a (24 a) of one case 20 can be fitted into the concave portion 25 a (26 a) of the other case 20, so that the joints of the adjacent cases 20 and 20 are connected. Therefore, the plurality of block members 14 can be spread on the water storage unit 10 easily and accurately.

The invention according to claim 8 is the temperature rise suppression system according to claim 6 or 7 , as shown in FIG.
Of the four side surface portions 23, 24, 25, 26 of the side plate portion 22 of the case 20, at least the side surface portion 23 (24, 25, 26) located on the lower side in the gradient direction of the floor surface 2a A plurality of holes 27, 27... Communicating between the inside 20 and the outside are formed.

According to the invention described in claim 8 , the water storage section 10 has a side surface portion 23 (at least on the lower side in the gradient direction of the floor surface 2a) because the water level is higher in the lower gradient direction of the floor surface 2a. 24, 25, 26) are formed with a plurality of hole portions 27, 27... For communicating the inside of the case 20 with the outside. The supplied water can be more reliably permeated and retained in the block member 14, and the water in the case 20 can be more reliably drained to the water storage unit 10. That is, water can be circulated more reliably between the case 20 and the water storage unit 10.

The invention according to claim 9 is the temperature rise suppression system according to any one of claims 1 to 8 , for example, as shown in FIGS.
The partition member 12 is formed in a triangular prism shape,
The height from the bottom surface to the top corner of the partition member 12 is set to 5 mm to 20 mm.

According to the ninth aspect of the present invention, since the partition member 12 is formed in a triangular prism shape, for example, the waterproof sheet 13 laid on the partition member 12 is laid as compared with a quadrangular columnar partition member. The area can be reduced.
Moreover, since the height from the bottom surface of this partition member 12 to the top corner is set to 5 mm to 20 mm, the depth of water stored in the plurality of water storage units 10 and 10 is more reliably reduced. Can do. Thereby, the water supplied from the water supply means 15 to the water storage unit 10 positioned above the floor surface 2a in the gradient direction is more easily transferred to the water storage unit 10 positioned below the floor surface 2a in the gradient direction. It is possible to more easily prevent the generation of malodors, germs and insects caused by the retention of water.

According to the present invention, a plurality of side wall members having a predetermined length are disposed at predetermined intervals along a gradient direction of a floor surface such as a rooftop of a building or a balcony, and in a direction orthogonal to the gradient direction of the floor surface. In addition, a plurality of partition members having a predetermined height are installed between the plurality of side wall members at a predetermined interval along the length direction of the plurality of side wall members. And a plurality of water storage units arranged in parallel along the gradient direction of the floor surface by laying a waterproof sheet in a portion surrounded by a partition member installed between both end portions in the length direction of the plurality of side wall members. Therefore, the plurality of water storage units are provided in a wide area with respect to the floor surface. Furthermore, since water has the property of taking away a predetermined amount of heat from the surroundings when it evaporates, a plurality of block materials are spread over a plurality of water storage portions provided in a wide area on the floor surface. When the water that permeates into the water evaporates, it evaporates while taking away the heat around the block material.Unlike conventional methods, the floor surface of the rooftop or balcony is not equipped with a sprinkling pipe. In a wide range with respect to the surface, an increase in the temperature of the floor surface can be suppressed or the temperature can be lowered. Thereby, the rise in the temperature of the balcony can be suppressed or the temperature can be lowered, and further, the rise in the temperature of the building can also be suppressed, so that a comfortable living environment can be formed.
In addition, since the floor surface is provided with a water gradient that decreases from the building-side end portion to the outer-side end portion of the floor surface, and a plurality of water storage portions are arranged side by side along the gradient direction of the floor surface. By simply supplying water from the water supply means provided in the vicinity of the water storage section located above the floor slope direction, the water storage section located above the floor slope direction is changed to the water storage section located below. Water can be easily distributed, and the water overflowing from the water storage portion located below the floor slope direction can be reliably discharged from the drain hole. Furthermore, by setting the height of the partition member low, the depth of the water stored in the plurality of water storage units can be reduced, so that the water storage unit located above the gradient direction of the floor surface from the water supply means The supplied water can be more easily distributed to the water storage section located below the gradient direction of the floor surface, and it is possible to reliably prevent the generation of malodors, germs, and insects caused by the retention of water. .

It is a perspective view which shows the balcony of the building in which the temperature rise suppression system of this invention is provided. It is a perspective view which shows the balcony of the building in which the temperature rise suppression system of this invention is provided. It is a perspective view which shows a part of water storage part. It is a sectional side view which shows the form which lays a waterproof sheet. It is a sectional side view which shows the state which spread the block material in the water storage part. It is a front view which shows an example of a block material. It is a front view which shows an example of a block material. It is the schematic which shows the form at the time of utilizing bath water as a water supply source. It is a sectional side view which shows the state which has arrange | positioned the irrigation pipe in the cavity. It is a partial expanded plan view which shows the case which accommodates a block material. It is a perspective view which shows the state which has arrange | positioned the case in which the block material was accommodated. It is a sectional side view which shows an example of the arrangement | positioning state of the case in which the block material was accommodated, and a partition member. It is a sectional side view which shows an example of the arrangement | positioning state of the case in which the block material was accommodated, and a partition member. It is a fragmentary sectional side view which shows the case where the rib was formed in the baseplate part. It is a fragmentary perspective view which shows the case where the several hole part was formed in the side-plate part.

  Embodiments of the present invention will be described below with reference to the drawings.

  As shown in FIGS. 1 to 8, the temperature rise suppression system according to the present embodiment suppresses the surrounding temperature rise by being provided on the floor 2a of the rooftop of the building 1 or the balcony 2, etc. The floor 2a is provided with a water gradient that decreases from the end of the floor 2a toward the outer end of the building. On the floor 2a, a plurality of water storage units 10 and 10 are provided. The plurality of water storage units 10, 10 are laid in parallel along the gradient direction of the floor surface 2a, and a plurality of block members 14 having water retention performance and permeation performance are laid down. The gradient direction of the floor surface 2a A water supply means 15 for supplying water to the water storage section 10 is provided in the vicinity of the water storage section 10 located above the water storage section 10, and below the floor surface 2a in the gradient direction, Water overflowing from the water reservoir 10 located below the gradient direction Drain hole 16 for discharging to the outside.

Here, although the temperature rise suppression system of this Embodiment shall be provided in the floor 2a of the balcony 2 of the said building 1, it is not restricted to this, You may provide on the rooftop of a building To do. The roof of the building when the temperature rise suppression system is installed on the roof of the building is in the form of a flat roof. In addition, when providing the temperature rise suppression system in the said balcony 2, it is desirable that this balcony 2 is a roof balcony with high load resistance.
1 and 2 and 8, the building 1 is provided with an entrance / exit 1a for moving between the inside of the building 1 and the balcony 2 so as to face the balcony 2. Yes.

The slope of the floor surface 2a is set to about 1/50, and the floor surface 2a is in a relatively gently inclined state. Thereby, the depth of the water stored in the plurality of water storage units 10, 10 can be set shallower.
That is, the depth of water stored in the plurality of water storage units 10 and 10 can be set depending on how much the water gradient of the floor surface 2a is set. For example, if the floor surface 2a has a water gradient of about 1/100, the water depth can be reduced compared to 1/50, and if the floor surface 2a has a water gradient of about 1/20. , The water depth can be made deeper than in the case of 1/50.

On the other hand, the plurality of water storage portions 10 and 10 are side wall members 11 having a predetermined length along the gradient direction of the floor surface 2a and at a predetermined interval in a direction perpendicular to the gradient direction of the floor surface 2a. A plurality of partition members 12 having a predetermined height are arranged between the plurality of side wall members 11, 11 at a predetermined interval along the length direction of the plurality of side wall members 11, 11. Further, a waterproof sheet 13 is provided at a portion surrounded by the plurality of side wall members 11 and 11 and partition members 12 and 12 respectively installed between both end portions in the length direction of the plurality of side wall members 11 and 11. Are arranged side by side on the floor surface 2a.
In addition, since the depth of the water stored in the water storage section 10 is inclined so that the floor surface 2a itself on which the water storage section 10 is provided becomes lower from the building side end toward the outside side, The building-side end of each water reservoir 10 is shallower and the outer-side end is deeper.

  Further, as shown in FIGS. 1 to 3, the side wall member 11 is made of an angle material that is long along the gradient direction of the floor surface 2a, and the bottom of the angle material is formed on the floor surface 2a. The rising portion becomes the side wall portion of the water storage portion 10.

  In addition, as shown in FIG. 1, the partition member 12 is disposed in a direction orthogonal to the gradient direction of the floor surface 2 a, and as described above, between the plurality of side wall members 11, 11, The plurality of side wall members 11, 11 are constructed so as to be arranged in parallel along the length direction at a predetermined interval. Therefore, the interval between the plurality of side wall members 11 is substantially equal to the length of the partition member 12.

Moreover, this partition member 12 is formed in the triangular prism shape, as shown in FIGS. That is, the bottom surface is provided on the floor surface 2a, and at least one of the other two surfaces is a surface constituting the water reservoir 10, and these three surfaces are orthogonal to the gradient direction of the floor surface 2a. It is long along the direction.
And since the said partition member 12 is formed in triangular prism shape in this way, the installation area of the waterproof sheet 13 laid on this partition member 12 can be reduced compared with the partition member of square pillar shape, for example. .
Further, if the partition member 12 is formed in a triangular prism shape in this way, the apex angle portion of the partition member 12 can be recognized as the end portion of the water storage unit 10.
Furthermore, it is preferable that the partition member 12 has a triangular prism shape because the structural strength is higher than that when the partition member 12 is formed in a plate shape.

Moreover, the height from the bottom face of the partition member 12 of the present embodiment to the apex portion is set to 5 mm to 20 mm. Accordingly, the depth of water stored in the plurality of water storage units 10 and 10 can be more reliably reduced, so that the water storage unit 10 located above the water supply means 15 in the gradient direction of the floor surface 2a. It becomes easier to spread the water supplied to the water storage unit 10 located below the floor surface 2a in the gradient direction.
In this way, by making the water storage section 10 shallower and spreading the water to the plurality of water storage sections 10, 10, it is possible to reliably generate odors, germs, and insects caused by the water staying in the water storage section 10. Can be prevented.

Furthermore, the water depth of the said several water storage parts 10 and 10 can be adjusted by using the thing from which the height of this partition member 12 differs.
In the present embodiment, the height from the bottom surface to the top corner of the partition member 12 is set to 5 mm to 20 mm, so that the building side end is shallower and the outer side end is deeper. The water depth of the water storage part 10 is set so that the average water depth is about 1 cm. Moreover, if the water depth of each water storage part can be set to be about 1 cm on average, the height from the bottom surface of the partition member 12 to the apex angle part is set to 6 mm to 18 mm. Also good.
Here, as described above, the amount of water stored in each of the water storage units 10 is set to an average depth of about 1 cm. The average depth of about 1 cm is, for example, summer In the numerical value setting, the number of days required for the water stored in each water storage unit 10 to evaporate is about 1 to 3 days. That is, as described above, by setting the height from the bottom surface to the top corner of the partition member 12 to 5 mm to 20 mm, more specifically, 6 mm to 18 mm, water stored in each water storage section 10 is stored. The water depth can be set to about 1 cm.
In addition, when setting the height from the bottom surface of the partition member 12 to the apex angle portion to 5 mm to 20 mm or 6 mm to 18 mm and setting the water depth of each water storage portion 10 to about 1 cm, the floor It is assumed that the water gradient of the surface 2a is set to about 1/50, or a steep or gentle gradient than 1/50.

Further, as described above, the waterproof sheet 13 includes the plurality of side wall members 11 and 11 and the partition members 12 and 12 respectively installed between both end portions in the length direction of the plurality of side wall members 11 and 11. It is laid in the part surrounded.
The portion of the waterproof sheet 13 that contacts the side wall member 11 is welded or bonded to the side wall member 11 as shown in FIG. 3, and the portion that contacts the partition member 12 is as shown in FIG. These are attached to the partition member 12 by a double-sided tape 13a.

  Further, the end of the waterproof sheet 13 may be waterproofed with a caulking material or the like. Further, as shown in FIG. 4, the overlapping end portions of the waterproof sheet 13 are welded or adhered to each other after being overlapped to maintain waterproofness.

  On the other hand, as the block material 14 of the present embodiment, for example, pumice having a particle size of 3 to 20 mm (dry specific gravity is 0.4) 50 to 62 without mixing sand and without adding an additive to supplement strength. A mixture of 40% to 50% by weight of water and a mixture of 50% to 38% by weight of Portland cement and ready-mixed ready-mixed concrete in a mold can be mentioned. Pumice varies slightly in dry specific gravity depending on the production area, but there is no significant difference.

Moreover, when a compounding ratio is represented by a volume, water 20-30 volume% is sprayed with respect to the compound of pumice (dry specific gravity 0.4) 70-85 volume% and Portland cement 30-15 volume%. Kneaded.
Furthermore, the water content specific gravity of concrete using pumice as such aggregate is about 60% of concrete using only natural aggregate such as cement and crushed stone and Portland cement, and the dry specific gravity is about 50%.

Regarding the water retention performance, the water content specific gravity of the block material 14 using pumice as an aggregate is about 1200 kg / m ² , and can retain water of about 300 kg / m ³ or more. Moreover, as for the permeation performance, water that cannot be retained by pumice is permeated, so that the same performance as concrete using natural aggregate can be obtained.
That is, when the block material 14 using such pumice as an aggregate is used as a paving material for a paved surface, for example, when the block material 14 is paved with a thickness of 50 mm, the moisture content is 60 kg / m ² and is dried. Since the specific gravity is 45 kg / m ² , it is possible to retain 15 liters of water and have excellent performance.
In addition, as the block material 14 of the present embodiment, for example, natural fibers such as palm, non-woven fabric, glass wool or rock wool, or the like may be used.

Further, the block member 14 is set to be slightly higher than the rising portion of the side wall member 11 as shown in FIG. 2, and is higher than the partitioning member 12 as shown in FIG. Is set to
Further, as shown in FIGS. 5 to 7, the block material 14 is configured such that the upper surface of the block material 14 is larger than the lower surface by setting the upper surface of the block material 14 to be larger than the lower surface. It is formed to overhang. That is, in the present embodiment, the side wall portion of the block member 14 is formed in an inverted truncated pyramid shape that is inclined so that the upper portion is positioned outward from the lower portion.
Then, by adjoining the block members 14 and 14, the upper portions of the adjacent block members 14 and 14 come into contact with each other and the lower portions are separated from each other, so that the adjacent block members 14 and 14 face each other. The cavity 14c can be formed between the side portions.

In the present embodiment, the cavity 14c is an accommodation space for accommodating the partition member 12, as shown in FIG. Therefore, the block member 14 can be spread over the plurality of water storage portions 10 and 10 without any gaps in a state where the partition member 12 is accommodated in the accommodation space. That is, it is difficult to visually recognize the cavity 14c from the appearance.
Furthermore, since the said cavity 14c is formed between the side parts which the said adjacent block materials 14 and 14 oppose, it will lead in the said water storage part 10 vertically and horizontally. As a result, since the inside of the cavity 14c can be used as a water flow path, for example, water can be easily distributed in the water storage section 10 without piping a sprinkling pipe on the floor surface 2a.
In addition, although the sprinkler pipe is not provided, for example, as shown in FIG. 9, a watering pipe 17 connected to the water supply means 15 may be provided in the cavity 14 c. Thereby, for example, even if the area of the water storage unit 10 is large, the water supplied from the water supply means 15 is poured into the water storage unit 10 by the irrigation pipe 17, and water can be quickly and rapidly supplied to the water storage unit 10. Can be stored reliably.

  In addition, when the partition member 12 has a prismatic shape, for example, as shown in FIG. 13, for example, the upper portion of the block member 14 is projected outward from the lower portion. It is preferable that the cavity 14c be formed so that the side wall portion of the block material 14 is cut out in a concave shape. That is, when the block member 14 in the case where the partition member 12 is prismatic is viewed from the side, the block member 14 is substantially T-shaped.

  In addition, as shown in FIGS. 6 and 7, the block material 14 of the present embodiment is one in which grass 14a is planted on the upper surface of the block material 14 or one in which a ceramic tile 14b is attached. ing.

According to the block material 14 having the turf 14a planted on the upper surface, the turf 14a can cover the upper surface of the block material 14, so that the temperature rise around the floor surface 2a on which the block material 14 is provided. Can be suppressed.
Moreover, since the upper surface of the block material 14 can be covered with the turf 14a in this way, the portion where the block material 14 on which the turf 14a is planted can be greened, and the appearance is excellent. .
In addition, when planting the turf 14a on the upper surface of the block material 14, it is desirable to use the waterproof sheet 13 provided with root prevention performance.

According to the block material 14 with the ceramic tile 14b attached to the upper surface, the ceramic tile 14b is a porous body, so even if such a ceramic tile 14b is attached to the upper surface of the block material 14, The water permeated and held in the block material 14 is surely evaporated through the ceramic tile 14b.
Moreover, since the ceramic tile 14b is attached to the upper surface of the block material 14, the upper surface of the block material 14 can be made into a graceful finish, and the appearance is excellent.
Furthermore, by arranging the block material 14 to which the ceramic tile 14b is attached and the block material 14 to which the grass 14a is provided, the appearance can be further improved.

On the other hand, as shown in FIGS. 1 and 2, the water supply means 15 is provided in the vicinity of the water storage portion 10 located above the floor surface 2a in the gradient direction, and is connected to a water supply source and receives water. A discharge portion 15a to be discharged and a hose 15b connected to the discharge portion 15a and having a tip inserted from a cavity 14c between the adjacent block members 14 and 14 and provided in the water storage portion 10 are provided. .
The water supply source is, for example, a bath 15c shown in FIG. 8, a storage tank for storing rainwater, or the like, and is appropriately selected.

Here, when water is supplied to the water storage unit 10, there may be a problem such as an increase in cost if the water supply is used as a water supply source. Therefore, rainwater and domestic wastewater from the bath 15c, kitchen, etc. are used as the water supply source.
In the present embodiment, for example, the description will be made assuming that the bath 15c is used as a water supply source.

Moreover, when using bath water in this way, it is desirable to purify the bath water by the purifying means 15e that filters the bath water.
The purification means 15e is built in, for example, a hot water supply device 15d provided in connection with a bath 15c. The hot water supply device 15d can be purified by the purification means 15e while circulating the water in the bath 15c and performing temperature control.

In addition, a pump 15f is provided in the vicinity of the purification means 15e to supply the bath water purified by the purification means 15e to the discharge port 15a.
The pump 15f can be controlled by, for example, a control means 15g provided in the room, so that purified bath water can be used appropriately. Further, by such a control means 15g, the discharge amount and time setting from the discharge port 15a may be set together with the pump 15f.

Thus, since the bath water is purified by the purification means 15e for filtering the bath water, dust, hair, germs and the like contained in the bath water can be removed. Thereby, clogging of the discharge port 15a and the water distribution pipe, contamination of the block material 14 and the like can be prevented.
And since the domestic wastewater, such as bath water, is utilized as the water supplied to the said water storage part 10 as mentioned above, the usage-amount of water can be reduced compared with the case where only a water supply is used as a water supply source. Therefore, cost can be reduced. In addition, rainwater may be used in combination with bath water, thereby further reducing the amount of water used. At this time, it is preferable to sterilize and disinfect rainwater.

Further, when the bath water is used as the water supplied to the water storage unit 10 as described above, the bath water can be efficiently evaporated as long as the bath water is warm. The rise in temperature can be efficiently suppressed or lowered.
In the cold season such as winter, when the bath water is cooled before being supplied to the water storage unit 10, the water may be reheated using a radiator or the like, for example.

The discharge amount from the discharge port 15a and the pump 15f are controlled by the control means 15g. In addition to this, for example, a timer is provided at the discharge port 15a, and water is discharged by this timer. The discharge time may be managed. Here, when the bath 15c is used as the water supply source, it is necessary to control the timer and the pump 15f in conjunction with each other. However, when the water supply is used as the water supply source, the discharge time (amount) is managed only by the timer. It can be performed.
In addition, if water stays in the plurality of water storage units 10 and 10 at a high temperature, it may promote the generation of malodors, germs, and insects. Therefore, from the water supply means 15 to the plurality of water storage units 10. , 10 is preferably supplied when high temperature days continue in summer, spring, and autumn.

Further, when rainwater is used as a water supply source, it may be used after the rainwater is temporarily stored in a storage tank, but the rain poured from the sky may be simply stored in the water storage unit 10.
That is, when storing water in the water storage unit 10, using bath water as shown in FIG. 8, storing rainwater in a storage tank, storing rainwater directly in the water storage unit 10, etc. It is desirable to save water and save energy. That is, for example, sprinklers and conventional water spray pipes require excessive water pressure when spraying water over a wide range or spreading water to the end of the pipe, but in this embodiment, the water storage It is only necessary to store water in the part 10.

  On the other hand, as shown in FIG. 1, the drain hole 16 is provided at the lower end of the floor surface 2a in the gradient direction. In addition, the lower end part of the gradient direction of the floor surface 2a is a drainage band 16a that is long in a direction orthogonal to the gradient direction of the floor surface 2a, and the drainage hole 16 is formed in a part of the drainage band 16a. Is provided. The drainage zone 16 a is configured to incline toward the drainage hole 16 and easily drains not only water overflowing from the water storage unit 10 but also rainwater flowing around the water storage unit 10. The drainage zone 16a may be formed in a groove shape that is one step lower than the floor surface 2a.

As shown in FIG. 2, the drain hole 16 is covered with a cover 16b for concealing the drain hole 16 and preventing clogging with dust from the outside.
Furthermore, the height to the upper surface of the cover 16b is set to be substantially equal to the upper surface of the block member 14 spread on the water storage section 10 located below the floor surface 2a in the gradient direction. And the gravel (not shown) etc. are spread | laid on the floor surface 2a around these water storage parts 10 and 10 except this cover 16b, etc., and the surrounding wall of these water storage parts 10 and 10 and the said balcony 2 The groove between 2b is filled. At this time, the gravel laid in the groove is made substantially equal to the cover 16b of the drain hole 16 and the block material 14 laid in the plurality of water storage portions 10 and 10, so that the inside of the balcony 2 Since the level difference can be reduced, it is excellent in safety and appearance.

Next, a mode until the temperature supplied around the balcony 2 is suppressed by evaporating the water supplied from the water supply means 15 will be described.
In addition, on the floor surface 2, a plurality of water storage portions 10, 10 are formed in advance and arranged side by side, and a plurality of the block members 14 are spread on the plurality of water storage portions 10, 10. Shall. That is, the balcony 2 is in a state as shown in FIG.

First, the water supplied from the supply means 15 is poured into the water storage section 10 (upper stage) located above the floor surface 2a in the gradient direction through the hose 15b. The water is supplied until all of the plurality of water storage units 10 and 10 are filled.
The water poured into the water storage unit 10 reaches the water storage unit 10 through the cavities 14c between the plurality of block members 14 and 14 spread in the water storage unit 10.

  The water that has spread into the water reservoir 10 located above the floor surface 2a in the gradient direction overflows from the apex portion of the partition member 12 located below the floor surface 2a in the gradient direction of the water reservoir 10; It will be poured into the water storage part 10 (middle stage) one step lower than the water storage part 10 located above the gradient direction of the floor surface 2a.

Further, the water poured into the water storage section 10 in the middle stage is distributed in the water storage section 10, and further, the water distributed in the water storage section 10 is the gradient direction of the floor surface 2 a of the water storage section 10. It overflows from the apex part of the partition member 12 located below the water and poured into the water storage part 10 (lower stage) located below the gradient direction of the floor surface 2a.
Then, the water that has spread to the lower reservoir 10 overflows from the apex portion of the partition member 12 located below the floor surface 2a in the gradient direction of the reservoir 10, and the overflowed water It will flow to the hole 16.

In addition, water is poured into each of the water storage units 10 and 10 at the same time, and at the same time, the water penetrates into the plurality of block members 14 and 14 spread on each of the water storage units 10 and 10. It is assumed that the block members 14 and 14 are water-retained.
Then, water supplied from the water supply means 15 is poured into the plurality of water storage units 10 and 10, and water is retained in the plurality of block members 14 and 14, so that excess water is supplied to the drain holes 16. The supply of water from the water supply means 15 is stopped when

  The water retained in the plurality of block members 14, 14 starts to evaporate. As described above, since water has a property of depriving the surroundings of a predetermined amount of heat when evaporating, water evaporates while depriving the surrounding heat of the plurality of retained block materials 14, 14. As a result, it is possible to suppress the temperature rise or to reduce the temperature of the plurality of water storage units 10, 10 provided with the plurality of block members 14, 14 or the balcony 2. Therefore, the temperature rise of the building 1 can be suppressed by suppressing the temperature rise of the balcony 2.

When the evaporation of water proceeds and the water in the plurality of water storage units 10 and 10 is reduced, water is supplied from the water supply means 15 so that the water in the plurality of water storage units 10 and 10 is filled again. To. It is assumed that the temperature rise of the building 1 is suppressed by repeating the above operation.
Moreover, since the said entrance / exit 1a is provided facing the said balcony 2, the external air which passes the balcony 2 by which the temperature rise was suppressed can be flowed in into the inside of the building 1 from this entrance / exit 1a. This makes it possible to efficiently take outside air having a relatively low temperature from the balcony 2 into the building 1, particularly in warm seasons such as summertime, thereby forming a comfortable living environment.

Further, as shown in FIGS. 10 to 15, the block member 14 may be used by being integrally fixed and housed in a resin case 20. In this way, if the block member 14 is integrally fixed and stored in the case 20, the thickness of the block member 14 can be reduced as compared with the case where the block member 14 is not stored in the case 20. As a result, the amount and weight of the block material 14 and the labor and cost associated with the manufacture of the block material 14 can be reduced. Further, even if the thickness of the block material 14 is reduced, the block material 14 is fixedly accommodated in the case 20 and thus it is possible to ensure strength. That is, the block material can be prevented from being broken or chipped.
Moreover, since the case 20 is made of resin, it is preferable because it is easy to mold and can be formed thin.

In addition, such a resin case 20 is formed in a square shape, and includes a bottom plate portion 21 having a plurality of holes 21 a, 21 a... That communicates the inside of the case 20 with the outside, and the bottom plate portion 21. A side plate portion 22 that rises along the side surface of the block member 14 from four side edges.
Since the bottom plate portion 21 and the side plate portion 22 of the case 20 can cover the bottom surface and the side surface of the block member 14, the top surface of the block member 14 can be exposed, and the block member 14 can be The block material 14 can be used in the same manner as when the case 20 is not housed in the case 20.

Further, the plurality of hole portions 21a, 21a,... Of the bottom plate portion 21 are formed in, for example, a 1 cm square shape. As described above, since the bottom plate portion 21 has a plurality of holes 21a, 21a,..., The water supplied to the water reservoir 10 through the holes 21a, 21a,. The water can be reliably permeated and retained, and the water in the case 20 can be reliably drained to the water storage section 10. That is, water can be reliably circulated between the case 20 and the water reservoir 10.
Even though the plurality of holes 21a, 21a, ... are formed in the bottom plate portion 21 in this way, the block material 14 in the previous stage (that is, the stage before solidification) that is put into the case 20 is Since it has an appropriate viscosity, it does not fall off from these holes 21a, 21a.

Further, the side plate portion 22 has four side portions 23, 24, 25, 26 by rising from the four side edges of the bottom plate portion 21 along the side surfaces of the block member 14.
And this side-plate part 22 has the convex parts 23a and 24a which each protrude from the width direction center part of the two side surface parts 23 and 24 among these four side surface parts 23, 24, 25 and 26, and the remainder. The two side surface portions 25 and 26 have recesses 25a and 26a provided at the center in the width direction.
Accordingly, when the cases 20 are arranged side by side, the convex portion 23a (24a) of one case 20 among the cases 20, 20 adjacent to each other can be fitted into the concave portion 25a (26a) of the other case 20. It has become.

The side plate portion 22 includes an inclined portion 22a that rises obliquely upward from the four edges of the bottom plate portion 21, a horizontal portion 22b that extends in the horizontal direction from the upper end portion of the inclined portion 22a, and the horizontal portion 22b. And a rising portion 22c rising upward from the extended end portion.
In the present embodiment, the side surface portions 23, 24, 25, and 26 are the four sides of the rising portion 22c located on the upper side of the side plate portion 21, as shown in FIGS. Point to the side.

Since the side plate portion 22 is formed as described above, a plurality of cases 20 are arranged to form a cavity 14c as an accommodation space between the adjacent cases 20 and 20, as shown in FIG. can do. Therefore, these adjacent cases 20 and 20 are arranged so that the rising portions 22c come into contact with each other in a state where the partition member 12 is accommodated in the cavity 14c which is an accommodation space.
As shown in FIG. 13, when a quadrangular prism-shaped partition member 12 </ b> A is used, it is preferable to use a case 20 </ b> A having a shape different from that of the case 20. That is, the case 20A is substantially T-shaped in a side view, and the partition member 12A can be accommodated in a cavity 14c formed between the cases 20A and 20A.

  On the other hand, as shown in FIGS. 10, 11 and 15, the convex portions 23a, 24a are formed in a substantially triangular shape protruding outward from the side surface portions 23, 24 in plan view. The recesses 25a and 26a are formed in a substantially triangular shape protruding from the side surface portions 25 and 26 toward the inside of the case 20 in plan view. The convex portions 23a and 24a are formed in a size that matches the concave portions 25a and 26a, so that the convex portions 23a and 24a and the concave portions 25a and 26a can be fitted to each other. Yes.

  As described above, the side plate portion 22 includes the convex portions 23a and 24a provided so as to protrude from the center portions in the width direction of the two side surface portions 23 and 24 among the four side surface portions 23, 24, 25 and 26, respectively. Since the recesses 25a and 26a are respectively provided at the center portions in the width direction of the remaining two side surface portions 25 and 26, the joints of the cases 20 and 20 adjacent to each other can be easily and accurately performed. A plurality of block members 14 can be easily and accurately spread on the water storage unit 10.

  In order to further improve the strength of the case 20, a plurality of ribs 21b may be formed on the bottom plate portion 21, as shown in FIG. The plurality of ribs 21b, 21b,... Are provided between adjacent holes 21a, 21a, and are formed long along the surface direction of the bottom plate portion 21. That is, the side plate portion 22 may be formed from the side surface portion 23 side to the side surface portion 25 side, or the side plate portion 22 may be formed from the side surface portion 24 side to the side surface portion 26 side. Further, it may be formed in a substantially mesh shape so as to avoid the plurality of holes 21a, 21a.

Further, as shown in FIG. 15, among the four side surface portions 23, 24, 25, 26 of the side plate portion 22 of the case 20, at least the side surface portion 23 located on the lower side in the gradient direction of the floor surface 2 a, A plurality of holes 27, 27... Communicating the inside of the case 20 with the outside may be formed.
That is, when water is introduced into the water reservoir 10, the water level becomes higher on the lower side in the gradient direction of the floor surface 2a. For this reason, if a plurality of hole portions 27, 27... Communicating between the inside of the case 20 and the outside are formed at least on the side surface portion 23 positioned on the lower side in the gradient direction of the floor surface 2a, The water supplied to the water storage unit 10 can be more reliably permeated and retained in the block member 14 through the holes 27, 27... And the water in the case 20 can be supplied to the water storage unit 10. It can drain more reliably. That is, there is an advantage that water can be circulated more reliably between the case 20 and the water reservoir 10.

According to the present embodiment, a plurality of the side wall members 11 are arranged on the floor surface 2 a, a plurality of the partition members 12 are installed between the plurality of side wall members 11, 11, and the plurality of side wall members 11 are further arranged. , 11 and a portion of the plurality of side wall members 11, 11, and a partitioning member 12, which is installed between both end portions in the length direction, a waterproof sheet 13 is laid on the floor surface 2 a. Since the plurality of water storage units 10 and 10 are arranged in parallel along the gradient direction of the floor surface 2a, the plurality of water storage units 10 and 10 are provided in a wide area with respect to the floor surface 2a. Become. Furthermore, since water has a property of depriving the surroundings of a predetermined amount of heat when it evaporates, a plurality of the block members 14 are spread over a plurality of water storage portions 10 and 10 provided in a wide area with respect to the floor surface 2a. As a result, when water permeated into and held by the block material 14 evaporates, it evaporates while taking away the heat around the block material 14. The rise in the temperature of the surface 2a can be suppressed or the temperature can be lowered. As a result, the rise in the temperature of the balcony 2 can be suppressed or the temperature can be lowered, and further, the rise in the temperature of the building 1 can also be suppressed, so that a comfortable living environment can be formed. It becomes.
The floor surface 2a is provided with a water gradient that decreases from the building-side end portion to the outer-side end portion of the floor surface 2a, and the plurality of water storage portions 10 and 10 are arranged in the gradient direction of the floor surface 2a. Therefore, it is only necessary to supply water from the water supply means 15 provided in the vicinity of the water storage portion 10 located above the gradient direction of the floor surface 2a. The water can be easily distributed from the water storage unit 10 located at the lower side to the water storage unit 10 located below, and the water overflowing from the water storage unit 10 located below the gradient direction of the floor surface 2a 16 can be reliably discharged. Furthermore, since the depth of the water stored in the plurality of water storage portions 10 can be reduced by setting the height of the partition member 12 low, the gradient direction of the floor surface 2a from the water supply means 15 can be reduced. The water supplied to the water storage unit 10 located above the water storage unit 10 located below the floor surface 2a in the gradient direction can be more easily distributed, and the bad odor caused by the water retention Generation of germs and insects can be surely prevented.

DESCRIPTION OF SYMBOLS 1 Building 2 Balcony 2a Floor 10 Water storage part 11 Side wall member 12 Partition member 13 Waterproof sheet 14 Block material 15 Water supply means 16 Drain hole

Claims (9)

In the temperature rise suppression system that suppresses the surrounding temperature rise by being provided on the floor of the building rooftop or balcony,
The floor surface is provided with a water gradient that decreases from the building-side end of the floor to the outside-side end,
On the floor surface, a plurality of side wall members having a predetermined length are arranged along the gradient direction of the floor surface and at a predetermined interval in a direction orthogonal to the gradient direction of the floor surface. A plurality of partition members having a predetermined height arranged in parallel at a predetermined interval along the length direction of the plurality of side wall members, and further, the plurality of side wall members and the plurality of side wall members. A plurality of water storage portions are arranged in parallel along the gradient direction of the floor surface by laying a waterproof sheet in a portion surrounded by a partition member erected between both end portions in the length direction of the side wall member. ,
A plurality of block materials having water retention performance and permeation performance are laid in these water storage sections.
A water supply means for supplying water to the water storage part is provided in the vicinity of the water storage part located above the gradient direction of the floor surface,
Below the slope direction of the floor surface, a drainage hole for discharging water overflowing from the water storage part located below the slope direction of the floor surface is provided ,
The block material is formed such that the upper surface of the block material is overhanging the lower part by setting the upper surface of the block material to be wider than the lower surface,
When the block members are placed next to each other, the upper portions of the adjacent block members are in contact with each other, and the cavity formed between the opposing side portions of the adjacent block members is a storage space for storing the partition member. The temperature rise suppression system characterized by being said. The temperature rise suppression system according to claim 1,
A temperature rise suppression system, wherein grass is planted on an upper surface of at least one block material among the plurality of block materials. In the temperature rise suppression system according to claim 1 or 2,
A temperature rise suppression system, wherein a ceramic tile is attached to an upper surface of at least one block material among the plurality of block materials. In the temperature rise suppression system as described in any one of Claims 1-3 ,
An irrigation pipe connected to the water supply means and for pouring water into the water reservoir is disposed in the cavity. In the temperature rise suppression system as described in any one of Claims 1-4 ,
The temperature rise suppression system characterized in that the gradient of the floor surface is set to about 1/50. In the temperature rise suppression system according to any one of claims 1 to 5,
The block material is integrally fixed and stored in a resin case,
The case includes a bottom plate portion having a plurality of holes communicating the inside and the outside of the case, and a side plate portion that rises from a peripheral portion of the bottom plate portion along a side surface of the block member. Temperature rise suppression system. In the temperature rise suppression system according to claim 6 ,
The bottom plate portion is formed in a quadrangular shape, and the side plate portion has four side portions by rising from the four side edges of the bottom plate portion along the side surfaces of the block material,
The side plate portion includes a convex portion provided so as to protrude from the center portion in the width direction of the two side surface portions of the four side surface portions, and a recess portion provided in the center portion in the width direction of the remaining two side surface portions. Have
A temperature rise suppression system characterized in that, when the cases are arranged side by side, a convex portion of one case among the cases adjacent to each other can be fitted into a concave portion of the other case. The temperature rise suppression system according to claim 6 or 7 ,
Among the four side surface portions of the side plate portion of the case, at least a side surface portion positioned on the lower side in the gradient direction of the floor surface is formed with a plurality of holes that communicate the inside and the outside of the case. A temperature rise suppression system that is characterized. In the temperature rise suppression system as described in any one of Claims 1-8 ,
The partition member is formed in a triangular prism shape,
The temperature rise suppression system characterized in that the height from the bottom surface of the partition member to the apex angle portion is set to 5 mm to 20 mm.

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