JP2023025275A - air conditioning system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To ease a temperature gradient in an indoor space.

SOLUTION: An air conditioning system 50 includes: a ventilation device 61 which suctions indoor air of a ceiling space 28 formed between an upper slab 26 and a ceiling panel 27, suctions outer air, conducts heat exchange between the suctioned indoor air and the suctioned outer air, discharges the suctioned indoor air from the ceiling space 28 to an outdoor space, and supplies the outer air to a room 31 between the ceiling panel 27 and a floor panel 22; a blower 71 which suctions air of the ceiling space 28 and blows the air; and a supply duct 73 which is ducted from the blower 71 to an underfloor space 23 formed between the floor panel 22 and a lower slab 21 and sends the air blown by the blower 71 to the underfloor space 23. A vent hole 42 allowing communication between the room 31 and the ceiling space 28 is provided at the ceiling panel 27. An air outlet 45 allowing communication between the room 31 and the underfloor space 23 is provided at the floor panel 22.

SELECTED DRAWING: Figure 1

COPYRIGHT: (C)2023,JPO&INPIT

Description

The present invention relates to an air conditioning system for air conditioning a room between a ceiling panel and a floor panel below.

Patent Documents 1 to 3 disclose an underfloor air-conditioning system. Specifically, the air above the ceiling is sucked into the air conditioner, the sucked air is conditioned by the air conditioner, the conditioned air is sent from the air conditioner to the underfloor space, and then blown into the room from the floor outlets. be done. A vent is provided in the ceiling, and the air in the room flows into the ceiling through the vent.

JP-A-2000-213777 JP-A-2000-266364 JP 2011-80739 A

By the way, in a room, warm air rises and cold air descends. Therefore, a temperature gradient is generated in the room, and the temperature of the room gradually decreases from top to bottom. Therefore, the temperature in the vicinity of the floor is low, and people in the room feel cold under their feet.

Accordingly, the present invention has been made in view of the above circumstances, and the problem to be solved by the present invention is to alleviate the indoor temperature gradient.

In order to solve the above problems, the air conditioning system draws in the indoor air in the ceiling space formed between the upper slab and the ceiling panel installed below it, draws in the outdoor air, and draws in the inhaled indoor air. a ventilation device that exchanges heat between air and outside air, discharges the indoor air to the outside, and supplies the outside air to a room formed between the ceiling panel and a floor panel laid therebelow; a fan that sucks and blows indoor air in the space above the ceiling; and a duct from the fan to an underfloor space formed between the floor panel and a lower slab provided therebelow. a supply duct for sending air to be blown to the underfloor space, a vent opening communicating between the room and the space under the ceiling is provided in the ceiling panel, and an air outlet communicating between the room and the underfloor space is provided on the installed on the floor panel.

According to the above, the air in the ceiling space is blown to the outlet of the floor panel by the fan and the supply duct, and is blown out from the outlet into the room. Therefore, cold air is less likely to stay near the floor panel.
In addition, indoor air flows into the ceiling space through the vent. Therefore, the air circulates so as to flow from the space above the ceiling to the space below the floor, then the room, through the space below the floor and the room, and then to the space below the ceiling. Therefore, the temperature gradient in the room is relaxed.
When outside air is supplied into the room by a ventilator and air in the ceiling space is sucked in by the ventilator, an air pressure difference is generated between the ceiling space and the room. Therefore, warm air in the vicinity of the ceiling panel flows into the space above the ceiling, and the air is blown into the room from the outlet by the blower. Therefore, air circulation is likely to occur, and the temperature gradient in the room is more moderated.

Preferably, the air conditioning system further includes an airflow controller provided at the outlet for adjusting the direction of the airflow blown out from the outlet.

According to the above, the direction of the airflow can be adjusted according to the indoor temperature environment.

Preferably, said vent is provided in close proximity to a lighting fixture provided in said ceiling panel.

According to the above, the air vent is inconspicuous, and the design of the room is improved.

Preferably, the blower is installed in the ceiling space, and the supply duct is ducted from the ceiling space to the underfloor space along the pillars of the room.

According to the above, the supply duct does not become an obstacle.

According to the present invention, the indoor temperature gradient is relaxed.

1 is a sectional view of a given floor of a building; FIG. It is a top view of the ceiling space of the said predetermined floor.

FIG. 1 is a sectional view of a building 10. As shown in FIG. FIG. 2 is a plan view showing the ceiling space 28 of the floor 11 as viewed in the direction of arrow A in FIG. In this embodiment, the building 10 is assumed to be a multi-story building, and FIG. This floor 11 is provided between a lower slab 21 and an upper slab 26, the floor 11 and the lower floor 12 are partitioned by the lower slab 21, and the floor 11 and the upper floor 13 are partitioned by the upper slab 26. It is A floor panel 22 is laid above the lower slab 21 , and an underfloor space 23 is formed between the lower slab 21 and the floor panel 22 . A ceiling panel 27 is installed below the upper slab 26 , and a ceiling space 28 is formed between the upper slab 26 and the ceiling panel 27 . A wall panel 39 is erected on the floor panel 22, and the space between the floor panel 22 and the ceiling panel 27 is partitioned by the wall panel 39 into a room 31, a machine room 32, a corridor, a toilet, and the like.

A ceiling panel 27 in the room 31 is provided with a plurality of lighting fixtures 41 and a plurality of outlets 43 . The lighting fixtures 41 are arranged along the ceiling panel 27 in a grid pattern or a houndstooth pattern. The outlets 43 are arranged along the ceiling panel 27 in a grid pattern or a houndstooth pattern. A ceiling panel 27 in the room 31 is provided with a vent 42 , particularly in the vicinity of each lighting fixture 41 , that communicates the room 31 with the ceiling space 28 . Since the vent 42 is provided in the vicinity of the lighting equipment 41, the vent 42 is inconspicuous, so that the room 31 with high design can be provided.

The floor panel 22 in the room 31 is provided with a plurality of outlets 45 that communicate the room 31 and the underfloor space 23 . These outlets 45 are arranged along the floor panel 22 in a grid pattern or a houndstooth pattern. Each air outlet 45 is provided with a manually adjustable airflow controller 45a, and the direction of the airflow blown out from the air outlet 45 can be adjusted by the airflow controller 45a. For example, the airflow can be adjusted to an ascending airflow or a radial airflow. A radial airflow refers to an airflow that spreads radially and horizontally around the outlet 45 . The rising air current refers to an air current flowing upward from the outlet 45 . Note that the floor panel 22 may be provided so that the position of the air outlet 45 can be changed according to the preference of the person in the room 31 . Also, the outlets 45 may be provided so as to be individually openable and closable.

An air conditioning system 50 is installed on this floor 11 . The air conditioning system 50 includes a plurality of air conditioners 51, a ventilator 61, ducts 62-65, a blower 71, a return duct 72 and a supply duct 73 in addition to the airflow controller 45a described above.

The air conditioner 51 is a ceiling-embedded cassette type air conditioner. That is, the air conditioner 51 is attached to the ceiling panel 27 in a state of being embedded in the ceiling space 28 through the opening of the ceiling panel 27 and suspended from the upper slab 26 . These air conditioners 51 are arranged along the ceiling panel 27 in a grid pattern or a houndstooth pattern.
The air conditioner 51 blows conditioned air, that is, cooling air or heating air, into the room 31 . The interior of the room 31 is cooled or heated by the air conditioner 51 . For example, the set temperature of the air conditioner 51 is 26° C. during cooling and 22° C. during heating, but is not limited to this.

A temperature gradient occurs in the room 31 and the ceiling space 28 regardless of whether the air conditioner 51 is in cooling operation, heating operation, or stopped. That is, the temperature inside the room 31 and inside the ceiling space 28 gradually increases from the bottom to the top. The temperature in the ceiling space 28 is higher than the temperature in the room 31, and the temperature difference between the ceiling space 28 and the room 31 is, for example, about 2°C. In addition, since the air conditioner 51 generates heat during operation, the temperature in the ceiling space 28 becomes even higher than the temperature in the vicinity of the floor panel 22 in the room 31 .

The air conditioner 51 is not limited to the ceiling-embedded cassette type, and may be changed to, for example, a ceiling suspended type air conditioner or a built-in type air conditioner. A ceiling suspended air conditioner refers to an air conditioner suspended from the ceiling panel 27 . A built-in type air conditioner has an air outlet and an air inlet provided in the ceiling panel 27, the main body of the air conditioner is installed in another place (for example, in the space 28 above the ceiling), and the duct extends from the main body of the air conditioner through the space 28 above the ceiling. It is ducted to the outlet and suction port. The temperature in the space 28 above the ceiling is higher than the temperature in the room 31, even if it is a ceiling-suspended air conditioner or a built-in air conditioner.

A ventilator 61 is installed in the machine room 32 .
One end of the duct 62 is connected to the outside air intake 61a of the ventilator 61, the duct 62 is ducted from the ventilator 61 to the outdoors, and the other end is open to the outdoors.
One end of the duct 63 is connected to the fresh air outlet 61 b of the ventilator 61 . The duct 63 is branched from the ventilator 61 via the ceiling space 28 , and is ducted to the outlet 43 of the ceiling panel 27 .
One end of a duct 64 is connected to the indoor air intake 61c of the ventilator 61, the duct 64 is ducted from the ventilator 61 to the ceiling space 28, and the other end opens in the ceiling space 28.
One end of a duct 65 is connected to the indoor air discharge port 61d of the ventilator 61, the duct 65 is ducted from the ventilator 61 to the outdoors, and the other end is open to the outdoors.

The ventilator 61 draws in fresh outdoor air through a duct 62 and draws in air in the ceiling space 28 (hereinafter referred to as indoor air) through a duct 64 . The ventilator 61 performs heat exchange between the sucked fresh air and the indoor air, and filters the sucked fresh air. The ventilator 61 supplies heat-exchanged fresh air to the room 31 through the duct 63 and the air outlet 43 and exhausts the heat-exchanged indoor air to the outside through the duct 65 . Since the ventilation device 61 performs heat exchange between the fresh air and the indoor air, that is, the fresh outside air is cooled and supplied into the room 31 during cooling, and the fresh outside air is warmed during heating. 31, power consumption of the air conditioner 51 can be suppressed.

When fresh air is supplied to the room 31 by the ventilator 61 and the air in the ceiling space 28 is sucked by the ventilator 61 , the ceiling space 28 has a lower pressure than the room 31 . Therefore, the air in the room 31 flows into the ceiling space 28 through the vent 42 . Since such an airflow is generated, a temperature gradient is generated such that the ceiling space 28 is higher in temperature than the room 31 regardless of the season and regardless of whether the air conditioner 51 is on or off.

The blower 71 is, for example, a sirocco fan, but may be another type of fan. The blower 71 is installed in the ceiling space 28 in a state of being suspended from the upper slab 26 . As shown in FIG. 2 , these fans 71 are arranged at a pitch equal to the interval of one span of the building 10 . One span of the building 10 means the interval between adjacent pillars 14 of the building 10 . Since the interval between adjacent pillars 14 is, for example, 7.2 m, the blowers 71 are arranged at a pitch of 7.2 m.

Although the air volume of the blower 71 is not particularly limited, the air volume of all the blowers 71 may be equal, or the air volume of each of the blowers 71 may be set individually. Also, the blower 71 is operated at a constant air volume regardless of the season and time. For example, when the span of the building 10 is 7.2 m, the air volume of the blower 71 is 500 m ³ /h. Note that the temperature in the room 31, particularly the temperature near the floor panel 22 may be detected by a temperature sensor, and the blower 71 may be feedback-controlled by the controller based on the detected temperature.

A return duct 72 is installed in the ceiling space 28 , one end of the return duct 72 is open to the ceiling space 28 , and the other end of the return duct 72 is connected to the blower 71 . One end of the return duct 72 is provided with a filter 72a such as a wire mesh.
One end of a supply duct 73 is connected to the blower 71 . The supply duct 73 branches in two directions toward two adjacent pillars 14 (see reference numerals 73a and 73b shown in FIG. 2), and is ducted from the ceiling space 28 along the pillars 14 to the underfloor space 23. there is The other end of the supply duct 73 is connected to the blowout unit 74 in the underfloor space 23 . A branched portion 73a of a supply duct 73 ducted from one blower 71 and a branched portion 73b of a supply duct 73 ducted from an adjacent blower 71 are installed per one pillar 14.例文帳に追加

The blower 71 draws in the air in the ceiling space 28 through the return duct 72 and sends the drawn air to the supply duct 73 . The air is sent from the blower 71 to the blowout unit 74 by the supply duct 73 and blown out from the blowout unit 74 to the underfloor space 23 . Since the air blown out from the blow-out unit 74 is the air in the ceiling space 28 with a relatively high temperature, the underfloor space 23 is warmed by the air. Further, the air blown out from the blowout unit 74 flows in the underfloor space 23 and is blown out from the underfloor space 23 into the room 31 through the blowout port 45 .

Due to the operation of the blower 71, the air circulates from the ceiling space 28 to the ceiling space 23 and the room 31 in this order through the ceiling space 23 and the room 31 to the ceiling space 28.

Here, in order to efficiently raise the temperature of the vicinity of the floor panel 22, the airflow controller 45a is manually operated to adjust the airflow blown out from the outlet 45 into a radial airflow. On the other hand, when diffusing the air in the chamber 31, the airflow blown out from the blowout port 45 is adjusted to an upward airflow.

The above embodiment brings about the following advantageous effects.
The circulation of air by the blower 71 alleviates the temperature gradient in the room 31 and makes it difficult for cool air to stay near the floor panel 22 . Therefore, even in the case of cooling in the summer and heating in the winter, even those who are not good at cooling or cold feel comfortable and hardly feel the cold under their feet.

The vicinity of the blower outlet 45 is warmed by the air blown out from the blower outlet 45 . Therefore, if a person who does not like air conditioning or the cold is near the air outlet 45, it is difficult for that person to feel the cold.

A person who is not good at air conditioning or the cold does not easily feel cold, while a person who is not good at heat feels comfortable coolness when directly exposed to the airflow from the outlet 45. - 特許庁This is because the temperature difference between the air blown from the blower outlet 45 and the air in the chamber 31 is, for example, about 2° C. Therefore, the air blown from the blower outlet 45 and the person who is directly exposed to the air convection. This is because heat transfer occurs.

The operation of the ventilation device 61 causes a pressure difference between the ceiling space 28 and the room 31, warm air near the ceiling panel 27 flows into the ceiling space 28 through the vent 42, and the air is blown out by the blower 71. It blows out from 45. Therefore, circulation of air is likely to occur, and the temperature gradient within the chamber 31 is further alleviated.

Since the supply duct 73 is ducted along the column 14, the supply duct 73 does not become an obstacle.

21... Lower slab 22... Floor panel 23... Underfloor space 26... Upper slab 27... Ceiling panel 28... Ceiling space 31... Room 41... Lighting fixture 42... Air vent 45... Air outlet 45a... Air flow controller 50... Air conditioning system 61... Ventilator 71... Blower 73... Supply duct

Claims (4)

The indoor air in the ceiling space formed between the upper slab and the ceiling panel installed below it is sucked in, the outdoor outdoor air is sucked in, heat is exchanged between the indoor air and the outdoor air, and the indoor air is a ventilating device that discharges to the outdoors and supplies the outside air to a room formed between the ceiling panel and a floor panel laid below it;
a fan for sucking and blowing indoor air in the space above the ceiling;
a supply duct that is ducted from the blower to an underfloor space formed between the floor panel and a lower slab provided therebelow, and sends the air blown by the blower to the underfloor space;
a temperature sensor that detects the temperature in the room;
a control device that controls the blower based on the temperature detected by the temperature sensor;
with
a ventilation hole communicating between the room and the ceiling space is provided in the ceiling panel;
An air conditioning system, wherein the floor panel is provided with an air outlet for communicating the room and the underfloor space. 2. The air conditioning system according to claim 1, further comprising an airflow controller provided at said blower outlet for adjusting the direction of the airflow blown out from said blower outlet. 3. An air conditioning system according to claim 1 or 2, wherein said vent is provided in close proximity to lighting fixtures provided on said ceiling panel. The blower is installed in the space above the ceiling,
4. An air conditioning system according to any one of claims 1 to 3, wherein the supply duct is ducted from the ceiling space along the pillars of the room to the underfloor space.

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