JPH0960923A - Air-conditioning system for extremely high-rise building - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an air-conditioning system for an extremely high-rise building which can effectively condition air and reduce running and initial costs, by generating a natural air convection owing to the temperature difference of the cool air in the sky and the warm air in the basement. SOLUTION: An air-conditioning system in an extremely high-rise building as high as about 2,000m, having underground floors is provided with an air pressure controller 18 at the uppermost floor side, an underground air-suction and exhaust device 19 at the underground floor side, an air passage connecting the uppermost floor side and the underground floor side. The air pressure of the uppermost floor side is variably controlled by the air pressure controller 18 and the suction and exhaust of the underground floor side air against the underground side is controlled by a underground air-suction and exhaust device 19. In this way, a required air stream is generated in the air passage by making use of the cold air and the warm air resulting from the air in the sky and the air in the underground, to control the whole air-conditioning from the basements to upper floors in an extremely high-rise building.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention
The present invention relates to an air conditioning system in a super high-rise building of about 000 m.

[0002]

2. Description of the Related Art In recent years, construction of a skyscraper having a steel structure and a curtain wall method of several hundred meters above the ground has been carried out in various places. And recently, 1,000m above the ground
There have been various proposals for the concept of a super-high-rise building that exceeds the above.

[0003]

By the way, the various proposed skyscrapers over 1,000 m above the ground are based on the idea of building one city inside the skyscrapers. . In this way, from the concept of constructing a super-high-rise city, it will be a super-high-rise building with a huge area, so installing air conditioners in each area would result in a huge amount of air conditioners. However, it is not economical from the viewpoint of energy consumption, and therefore the air conditioning system needs some consideration.

Therefore, the object of the present invention is to provide 1,000 above the ground.
By using the cool air above m and the warm air under the ground to generate natural convection of the air flow due to the temperature difference, effective air conditioning can be performed and the initial cost and running cost can be suppressed. It is to provide an air conditioning system for super high-rise buildings.

[0005]

In order to solve the above-mentioned problems, the invention according to claim 1 is an air-conditioning system for a super high-rise building having a ground floor, for example, about 2,000 m above the ground. Atmospheric pressure control device for variably controlling the atmospheric pressure on the top layer side of a super high-rise building, for example, an atmospheric pressure conversion device,
Exhaust air on the ground level side to the ground side, and also an underground air supply / exhaust device for supplying air from the ground side, and the top level side and the ground level by vertically penetrating the super high-rise building. And an air passage connecting to the side. Then, the atmospheric pressure control device (atmospheric pressure conversion device) variably controls the atmospheric pressure on the top layer side, and the underground air supply / exhaust device controls the air supply / exhaust with the underground layer side air. , A desired airflow is generated in the air passage by utilizing cool air and warm air due to a temperature difference between the air on the sky side of the super high-rise building and the air on the underground side, the super high-rise building It is characterized in that it is configured to control the entire air conditioning from the ground level side of the object to the upper level side.

[0006] As described above, the super-high-rise building equipped with the atmospheric pressure control device installed on the top floor side, the underground air supply / exhaust device installed on the ground floor side, and the air passage connecting the top floor side and the ground floor side. Because it is an air conditioning system for air conditioning, it is possible to obtain comfortable air conditioning by convection of the cold air above and the underground air warmed by geothermal heat. For example, in the summer, the atmospheric pressure control device is used for high pressure on the top floor side, and the air on the ground floor side is exhausted underground by the underground air supply / exhaust device, and cold air of 2,000 m above the sky is taken into the air passage from the top floor side. , Let the cold air flow down to the bottom floor. And, in winter, on the contrary, low pressure is applied to the top layer side by the atmospheric pressure control device, and air on the ground level side is underground air-supplied by the underground air supply / exhaust device,
The air warmed by geothermal heat is taken into the air passage from the ground level side, and the warm air is allowed to flow to the top level side of the top floor.

In spring and autumn, the atmospheric pressure control device is used to set the high pressure to a high pressure, and the underground air supply / exhaust device stops the supply / exhaust of air on the ground level side, so that cold air of 2,000 m above the sky level is applied from the top level side. Take in the air passage, let the cold air flow to the bottom floor of the ground floor, take in the air warmed by the geothermal heat of the ground floor into the air passage, and let the warm air flow to the top floor of the top floor, Generate convection of cold and warm air. As described above, comfortable air conditioning according to the four seasons can be obtained by convection between the cold air above and the underground air warmed by the geothermal heat.

The invention according to claim 2 is the air-conditioning system for a super-high-rise building according to claim 1, in which the super-high-rise building has a plurality of multi-story floors in which facility installation areas with a large space are internally provided. For example, honeycomb units each having five layers and having a height of about 50 m and a side length of about 50 m and having an approximately regular hexagonal shape in plan view are arranged adjacent to each other in the lateral direction and connected to each other, and are vertically stacked. The air passages are formed in a substantially regular hexagonal shape that is surrounded by the honeycomb unit and penetrates in the up-down direction, for example, for honeycomb grid lift-up. It features a space structure.

As described above, by forming an air passage which is surrounded by the honeycomb unit, which is a basic unit of a super high-rise building, and which penetrates in the up and down direction and which has a substantially regular hexagonal shape in plan view,
The above-mentioned cold air in the sky and underground air warmed by geothermal heat are taken into the air passage surrounded by the honeycomb unit as necessary, and the super high-rise building from underground to the top floor over 1,000 m above the ground. Air conditioning by natural convection over the entire area can be obtained.

[0010]

BEST MODE FOR CARRYING OUT THE INVENTION Embodiments of an air conditioning system for a super high-rise building according to the present invention will be described below with reference to FIGS. 1 to 9. First, FIG. 1 is a cross-sectional view showing an outline of various facilities in a super high-rise building as an example to which the present invention is applied. This super high-rise building is a super high-rise city "THE
It is called "HEXA COMB" (The Hexacom: a honeycomb based on a hexagonal frame).
00m, underground 300m, the bottom area of 1.77 million m ^2, with a total area of 1km ^2, the service life of 1,000 to tens of thousands at all times to use
It is a huge super-high-rise building of the year.

This super high-rise city "THE HEXA C
OMB is constructed on an island in the suburbs of the city to prevent environmental problems (sun protection, building wind problems, etc.) due to the construction of ultra-high-rise huge buildings, and is accessed by the submarine Shinkansen from the metropolitan area. In addition, a fully circular dewatering decomposition reuse plant (organic waste complete instant dehydration treatment device) is installed inside the low-rise part with a diameter of 1,500 m, and the organic sludge and waste generated in the super high-rise city are By completely reusing and developing the surrounding waters, "GROWTH-SATE
Also known as LLITE (Growth Satellite: a growing satellite city). And this super high-rise city "THE
As will be described later, "HEXA COMB" is based on a honeycomb unit having a regular hexagonal shape in a plan view of 50 m on a side, which has a plurality of multi-story floors (five floors in the example of FIG. 6) and has a facility installation area with a large space inside. There is.

Further, as shown in the figure, a dust energy recovery device and a honeycomb unit manufacturing plant for manufacturing a new honeycomb unit are installed in the lower part in the above-ground part, and in the middle and upper parts, an office area, a natural park (artificial park) Various natural park areas, commercial areas, halls, public facilities, etc. are provided, and various residential areas are provided from the low-rise portion to the middle / high-rise portion and the super-high-rise portion. Further, an atmospheric pressure conversion device is installed on the top of the ultra-high-rise portion. Further, a seawater desalination plant, a wave energy conversion device, an unillustrated underground air supply / exhaust device (see FIG. 9) and the like are installed in the underground portion.

The honeycomb unit is shown in FIGS.
As shown in Fig. 2, the honeycomb grid 12 is a regular hexagon having a side length of 50 m and has a blow-through 13 in the central portion, and as shown in Figs. It is based on a regular hexagonal honeycomb core 2. Super high-rise city "THE HEXA CO
“MB” refers to the main central core portion 1 as shown in FIG. 2 showing the appearance of the super high-rise building in the super high-rise building according to the present invention and FIG. 3 showing the schematic plane of the super high-rise building. , Planarly seven honeycomb cores 2, 2, 2,
It is formed by 2, 2, 2, 2. Around the central core portion 1, there are six honeycomb cores 2, 2 in plan view.
Six sets of peripheral core portions 4, 4, 4, 4, 4, 4 which are surrounded by 2, 2, 2, 2 and have a honeycomb grid lift-up space 3 formed in the center are formed. In this way, the super-high-rise portion 5 is formed.

Below this super-high-rise portion 5, outside the surrounding core portions 4, 4, 4, 4, 4, 4, and also in plan view, six honeycomb cores 2, 2, 2, 2 are provided. Space for lifting up the honeycomb grid 3 in the center, surrounded by 2, 2
Forming 12 pairs of surrounding core portions 6, 6, 6, 6,
6, 6, 6, 6, 6, 6, 6, 6, 6 are formed. Thus, the high-rise portion 7 is formed. The peripheral core portions 4, 4, 4, 4, 4, 4, 4 of the super high-rise portion 5 and the peripheral core portions 6, 6, 6, 6, 6, 6, 6, 6, 6, of the high-rise portion 7
Between 6, 6, 6 and 6, 6 blow-throughs 8, 8, 8,
8, 8, 8 are formed.

The peripheral core portion 6 of the high-rise portion 7
A large number of honeycomb cores 2, 2, 2, 2, ... Are arranged outside the 6, 6, 6, 6, 6, 6, 6, 6, 6, 6, 6, and the middle layer outer shell portion 9 is formed. Is forming. The surrounding core portions 6, 6, 6, 6, 6, 6, 6, 6, of the high-rise portion 7
6, 6, 6 and 6 and the honeycomb core 2 of the middle layer outer shell portion 9
Twelve blow throughs 8,8,2,2,2, ...
8,8,8,8 are formed. Further, a large number of honeycomb cores 2, 2, 2, 2, ... Are arranged outside the honeycomb cores 2, 2, 2, 2, ... Of the middle layer outer shell portion 9 to form a low layer outer shell portion 10. are doing. This lower layer outer shell 1
0 has a shape that substantially follows the contour 11 of a circle having a diameter of 1,500 m.

Next, FIG. 4 is an enlarged view showing an allocation image of the honeycomb core 2 as the honeycomb unit.
As shown in the figure, one side of the honeycomb core 2 is connected to each side of the other honeycomb cores 2 and 2, and further, one side of the honeycomb core 2 is connected to one side of the other honeycomb core 2. In this way, one side portion of the honeycomb core 2 is connected to one side portion of another honeycomb core 2 one after another, so that the honeycomb core 2 is laid out in a planar manner. The honeycomb grid 12 to be described below is also planarly allocated and developed. In addition, FIG. 5 is an enlarged view of the honeycomb grid 12 as a honeycomb unit and the dimensions are also shown. As shown in the figure, the honeycomb grid 12 having a side of 50 m has a vertical direction in a central portion surrounded by facility installation areas. 25m per side that penetrates to
Has a blow-through 13 having a regular hexagonal shape in plan view. The diagonal length of the honeycomb grid 12 is 100 m, and the diagonal length of the honeycomb core is also 100 m.

FIG. 6 shows the tube frame structure and the rigid floor structure of the honeycomb grid 12, and the honeycomb grid 12 removes the oppressive feeling of the pillars in the internal space (the facility installation areas) and the honeycomb grid 12 In order to reduce the weight of the main frame 14, as shown in the figure, the structure of the main frame 14 is basically a double tube structure that encloses the five floors for each floor. Furthermore, a PC (precast / concrete) plate for industrial construction is attached to the main frame 14 of the double tube structure that encloses such 5 floors for each floor, and the rigid floor (ceiling) is installed. 15, 15,
15,15,15,15 and walls 16,16,16,
... is formed. In particular, in order to secure livability, the rigid floor portion 15 that maximizes the rigidity of the floor in each honeycomb unit prevents the three-dimensional undulation of floor vibration, and an ultra-high-rise huge building 2,000 m above the ground. A vibration damping device (not shown) installed at a proper position is operated more effectively.

Here, a polymer-impregnated concrete composite plate is used as the PC plate for forming the hard floor portion 15 and the wall portion 16, and an ultra-high durability frame film is formed on the honeycomb grid 12, and the PC plate is made for 1,000 years. I am trying to obtain a useful life. That is, polymer-impregnated concrete is used as an external integrated formwork of civil engineering structures that require long-term durability such as piers, bridges, bridge towers, dams, etc. It is a high-density and high-strength composite material manufactured by. In particular,
After manufacturing a hardened concrete plate and drying it with hot air, dip the hardened concrete plate in a polymer resin melting tank to impregnate the hardened concrete plate with the polymer resin from the surface and add the polymer resin to the voids of the hardened concrete plate. Let it fill.

The main effects of such polymer-impregnated concrete are: Salt blocking property, 2. Water impermeable, 3.
Freeze-thaw resistance, 4. Neutralization suppression, 5. Wear resistance, 6. Chemical resistance, 7. Impact resistance, 8. For example, protection of the connecting surface is possible. As described above, by using the polymer-impregnated concrete as the coating material of the outer wall of the honeycomb grid 12, particularly, carbon dioxide in the air and other factors that deteriorate the concrete are protected.

By the way, the reinforced concrete itself has 1,0
Use ultra-durable concrete and ultra-durable rebar to give a life of 00 years. That is, ultra-high durability concrete by adding concrete durability improving admixture to concrete is used, and ultra-high durability reinforcing bar such as epoxy resin coated reinforcing bar by electrostatic powder coating is used for reinforcing bar. By using such an ultra-high durability concrete with the addition of a concrete durability improving admixture, it is possible to obtain the effects of improving the drying shrinkage reducing function, the neutralization suppressing function, the watertightness improving function, and the electrostatic resistance. By using ultra-high durability reinforcing bars such as powder coated epoxy resin coated reinforcing bars, the effect of blocking factors such as salt content that corrode the reinforcing bars by the coating of epoxy resin coating can be obtained. And by using the ultra-high durability concrete as described above and ensuring the design cover thickness of the ultra-high durability rebar of 5.5 cm or more, the reinforced concrete as the PC plate has a life of 1,000 years. it can.

Regarding the honeycomb core 2 as well, similar to the above-mentioned honeycomb grid 12, a PC is mounted on the main frame 14 having a double tube structure which encloses five layers for each floor.
Attaching the board, hard floor (ceiling) 15,15,15,
15, 15, 15 and the wall portions 16, 16, 16, ... Are formed. Then, in order to secure the overall rigidity as a three-dimensional city by a super high-rise huge building 2,000 m above the ground and suppress interlayer displacement, the honeycomb core 2 is provided in the central part of the city as shown in FIGS. 2 and 3. The high-rigidity area is constructed to prevent vibrations caused by earthquakes and wind. Although not shown, the foundation is a super high-rise building with a height of 2,000 m above ground and 300 m below ground, thus avoiding the risk of partial collapse of such a long super high-rise building under the effect of localized concentrated loads. In order to do so, the ground will be improved to improve the natural ground.

As shown in FIGS. 2 and 3, the honeycomb unit including the honeycomb core 2 and the honeycomb grid 12 as described above is developed in a plane and laminated to obtain various equipments as shown in FIG. Build a super-high-rise huge building with. In the construction of such an ultra-high-rise huge building, since the honeycomb units (honeycomb core 2 and honeycomb grid 12) are independent of each other, they can be used every time the area is completed by the construction of each honeycomb unit. It is possible to respond to changes in the situation. And, the honeycomb unit (honeycomb core 2 and honeycomb grid 12) can be constructed by using a super huge crane. In particular, as a wind countermeasure as the construction progresses in the sky, the honeycomb grid 12 is
It is designed to be lifted from the honeycomb grid lift-up space 3 inside the building under construction.

That is, FIG. 7 shows a construction image of the honeycomb grid 12 according to the present invention, in which the central portion of the honeycomb grid lift-up space 3 surrounded by the honeycomb core 2 and having a regular hexagonal shape in plan view, A honeycomb grid lift-up intermediate rod 17 (see FIG. 8) having a regular hexagonal shape in plan view corresponding to the blow-through 13 of the honeycomb grid 12 is erected from the above-ground portion (honeycomb unit manufacturing factory of the lower layer portion). Although not shown, the honeycomb grid lift-up intermediate rod 17 is equipped with a lift-up device that engages with the inner surface of the blow-through 13 of the honeycomb grid 12 to lift up the honeycomb grid 12. Further, as described above, the honeycomb units (the honeycomb core 2 and the honeycomb grid 12) are manufactured in the honeycomb unit manufacturing factory of the low-layer portion, and the honeycomb grid 12 of the manufactured honeycomb units has the blow-through 13 Is engaged with the lower end portion (see the process of FIG. 7) of the intermediate rod 17 for lifting up the honeycomb grid.

Then, as shown in FIG. 8 showing the lift-up portion of the honeycomb grid 12 by the honeycomb grid lift-up intermediate rod 17, it is surrounded by six honeycomb cores 2, 2, 2, 2, 2, 2. In the honeycomb grid lift-up space 3, the honeycomb grid 12 engaged with the honeycomb grid lift-up intermediate rod 17 by the blow-through 13 is lifted up by the lift-up device of the honeycomb grid lift-up intermediate rod 17 and rises. (See the process of FIG. 7).
In this way, when the honeycomb grid 12 that rises along the honeycomb grid lift-up intermediate rod 17 reaches a predetermined height, as shown in the process of FIG. 7, the honeycomb grid 12 is lifted from the upper end portion of the honeycomb grid lift-up intermediate rod 17. 12 is separated, and the separated honeycomb grid 12 is moved in parallel to a predetermined position and set in a predetermined place as shown in the process.

2,000 above the ground constructed as described above
Super high-rise huge building "TH
"E HEXA COMB" also functions as a self-sufficient three-dimensional city, and by utilizing the advantages of being built on an island, water and electricity can be supplied from the blessings of the sea. That is, as shown in FIG. 1, domestic water can be supplied by a seawater purification device (seawater desalination plant). In addition, electricity can be supplied by tidal current power generation (wave energy conversion device). Furthermore, such an ultra-high-rise huge building "THE H
In order to treat the waste generated from the three-dimensional city by "EXA COMB", energy can be recovered as an energy source by the waste energy recovery device, and the organic waste that has undergone the process of high-speed reaction microbial decomposition by the organic waste complete instantaneous dehydration processing device. For example, the sludge-converted raw garbage can be made into an odorless fertilizer and recycled by a complete instant dehydration process in which the sludge in the dough is turned into tempura.

Next, an air conditioning system using the natural convection air conditioner shown in FIG. 9 in the above super high-rise huge building "THE HEXA COMB" will be described. 9 (A) is a schematic side view showing a convection image in summer, FIG. 9 (B) is a schematic side view showing a convection image in winter, and FIG. 9 (C) is a convection image in spring / autumn. It is a schematic side view. This air conditioning system is
Atmospheric pressure control device (atmospheric pressure conversion device) 18 that is variably controlled at the top of a super-high-rise huge building at 000 m and 300 m underground, and air that is deployed underground, exhausts air to the underground side, and The above-mentioned honeycomb grid lift-up space 3 that functions as an air passage that vertically penetrates the super high-rise huge building and connects the top layer side and the ground layer side by vertically passing through the underground air supply / exhaust device 19 that supplies air from the underground side.
, Is provided.

According to this air conditioning system, the atmospheric pressure at the top is variably controlled by the atmospheric pressure conversion device 18 such as an air pressure varying device which is an atmospheric pressure control device provided at the top, and the underground air supply and exhaust device 19 is installed underground. By opening and closing the underground air supply / exhaust ports to control the air supply / exhaust with the underground side, the air above the ground and the air above the ground in the super high-rise huge building 2,000m above the ground and 300m underground. By utilizing the cool air and the warm air due to the temperature difference between the two, the desired air flow, that is, the convection of the cool air and the warm air, is generated in the honeycomb grid lift-up spaces 3, 3, 3, ... That also function as an air passage connecting them. Can be generated. In this way, by generating convection of cold air and warm air, it is possible to control the air conditioning of the entire super high-rise huge building from 300 m underground to 2,000 m above ground.

That is, in the summer, as shown in FIG. 9 (A), the atmospheric pressure converting device 18 is used to raise the pressure to a high pressure, and underground air is supplied by the underground air supply / exhaust device 19 to open the underground air supply / exhaust port. By using the middle exhaust, cold air of 2,000 m in the sky is taken into the honeycomb grid lift-up spaces 3, 3, 3, ... From the top, and as shown by arrow A, the cold air is flowed up to 300 m underground. In addition, the entire super high-rise huge building 2,000m above ground and 300m underground can be cooled. Then, in winter, as shown in FIG. 9 (B), contrary to the case in summer shown in FIG. 9 (A), a low pressure and underground air are supplied to the top by the atmospheric pressure conversion device 18. By opening the underground air supply / exhaust port by the exhaust device 19 to supply air underground, air warmed by geothermal heat is taken into the honeycomb grid lift-up spaces 3, 3, 3, ... As shown, the warm air is made to flow to the top floor of 2,000m above the ground, and 300m underground to 2,000m above the ground.
You can warm up the entire super high-rise huge building.

In spring and autumn, as shown in FIG. 9 (C), the pressure is converted to a high pressure by the atmospheric pressure converter 18, while in the case of summer shown in FIG. 9 (A) and FIG.
Contrary to the case of winter shown in (B), the underground air supply and exhaust system 1
By closing the underground air supply / exhaust port by 9 to stop underground air supply / exhaust, the honeycomb grid lift-up space 3, which connects from 2,000 m above the ground to 300 m below the ground 3,
Comfortable air conditioning is obtained by generating convection of the air flow in 3, 3, .... That is, due to the high pressure at the top by the atmospheric pressure converter 18, the cold air of 2,000 m above the sky is fed from the top to the honeycomb grid lift-up spaces 3, 3, 3.
Taken in 3, ..., As shown by the arrow C1, the cold air is flowed to the lowest floor of 300 m underground, and the air warmed by geothermal heat rises in the honeycomb grid lift-up spaces 3, 3, 3 ,. Then, as shown by the arrow C2, the warm air flows to the top floor of 2,000 m above the ground.
Thus, convection of cold air and warm air can be generated in spring and autumn.

In the above embodiments, the honeycomb grid having a regular hexagonal shape in plan view is used. However, the present invention is not limited to this, and the shape of the blowout is circular in plan view. , Square, rectangle,
It may be a triangle or another polygon. In addition, the basic dimensions of the honeycomb unit, the ground height and dimensions of the super high-rise building, the shape in plan view, and the like are also arbitrary, and it goes without saying that specific detailed structures and the like can be appropriately changed. is there. Furthermore, the super-high-rise building to which the air conditioning system of the present invention is applied is not limited to the super-high-rise huge building whose basic unit is the honeycomb unit in the above-described embodiment, and any super-high-rise building Also, the air conditioning system of the present invention can be applied.

[0031]

As described above, according to the air conditioning system for a super-high-rise building according to the first aspect of the present invention, the atmospheric pressure control device installed on the top floor side and the underground air supply / exhaust installed on the ground floor side. Since it is equipped with a device and an air passage that connects the top layer side and the ground layer side, convection between the cold air above and the underground air warmed by geothermal heat is generated as necessary, and in four seasons. Accordingly, comfortable air conditioning can be obtained.
In this way, by utilizing the cool air in the sky and the warm air in the underground to generate natural convection of the air flow due to the temperature difference, it is possible to effectively use natural convection from underground to the top floor in a super high-rise building. It can perform various air conditioning. Therefore, both the initial cost and the running cost can be suppressed.

According to the air-conditioning system for a super high-rise building according to the second aspect of the present invention, an air passage having a substantially regular hexagonal shape in plan view, which is surrounded by a honeycomb unit which is a basic unit and penetrates in the vertical direction, is formed. Since it is formed, the above-mentioned cold air in the sky and the underground air warmed by geothermal heat are taken into the air passage surrounded by the honeycomb unit as necessary, from the underground to the top floor over 1,000 m above the ground. It is possible to obtain air conditioning by natural convection over the entire super-high-rise building of.

[Brief description of drawings]

FIG. 1 is a cross-sectional view showing an outline of various facilities in a super high-rise building as an example to which the present invention is applied.

FIG. 2 is a schematic perspective view showing an appearance of a super-high-rise portion in a super-high-rise building to which the present invention is applied.

FIG. 3 is a schematic plan view of the super high-rise building of FIG.

FIG. 4 is a plan view showing, on an enlarged scale, an allocation image of a honeycomb core as a honeycomb unit.

[Fig. 5] Fig. 5 is a plan view of a single product in which a honeycomb grid as a honeycomb unit is enlarged and its dimensions are also shown.

FIG. 6 is an enlarged perspective view showing a tube frame structure and a rigid floor portion structure of the honeycomb grid of FIG. 5 in a partially cutaway and transparent state.

FIG. 7 is a schematic side view showing a construction image of a honeycomb grid.

8 is an enlarged perspective view showing a lift-up portion of the honeycomb grid in the construction image of FIG. 7.

9A and 9B show an air conditioning system using a natural convection air conditioner according to the present invention in a super high-rise building, in which FIG. 9A is a schematic side view showing a convection image in summer, and FIG. 9B is a convection image in winter. The schematic side view shown is (C), which is a schematic side view showing a convection image in spring and autumn.

[Explanation of symbols]

 1 Central Core Part 2 Honeycomb Core 3 Air Passage 4 Surrounding Core Part 5 Super High-Rise Part 6 Surrounding Core Part 7 High-Rise Part 8 Blowing 9 Middle-layer Outer Shell 10 Low-layer Outer Shell 12 Honeycomb Grid 13 Blowing 18 Pressure Control Device 19 Underground air supply and exhaust system

 ─────────────────────────────────────────────────── ─── Continuation of the front page (72) Inventor Yasutoshi Sakai 2-10-10 Fujimi, Chiyoda-ku, Tokyo Maeda Construction Industry Co., Ltd. (72) Mitsue Tsuruta 2--10-10 Fujimi, Chiyoda-ku, Tokyo Maeda Construction Industry Co., Ltd. (72) Inventor Yuko Tanemura 2-10-10 Fujimi, Chiyoda-ku, Tokyo Maeda Construction Industry Co., Ltd.

Claims (2)

[Claims] 1. An air-conditioning system for a super-high-rise building having a ground level, the atmospheric pressure control device variably controlling the pressure on the top level side of the super-high-rise building, and the air on the side of the ground level Exhaust to the inside, and also an underground air supply / exhaust device that supplies air from the ground side, and an air passage that connects the top layer side and the ground layer side by vertically penetrating the super high-rise building, The air pressure control device variably controls the atmospheric pressure on the top layer side, and the underground air supply / exhaust device controls the air supply / exhaust with the ground layer side to the underground side. Generate a desired air flow in the air passage by utilizing cool air and warm air due to the temperature difference between the air on the sky side of the high-rise building and the air on the underground side, and the ground of the super high-rise building. Controls the entire air conditioning from the floor side to the upper floor side Air conditioning system of the super-skyscraper to Rukoto, the features. 2. The super high-rise building has a large number of honeycomb units, which are substantially regular hexagonal in plan view and have a plurality of multi-story floors, each of which has a large space inside and are connected to one another in a lateral direction. The air passages are arranged and stacked in the vertical direction so as to be connected to each other and stacked in a large number, and the air passages are surrounded by the honeycomb units and are formed in a substantially regular hexagonal shape in plan view penetrating in the vertical direction. The air conditioning system for a super high-rise building according to claim 1, wherein