JP5711083B2 - Building air conditioning system - Google Patents

Description

  The present invention relates to an air conditioning system for a building such as a house.

2. Description of the Related Art Conventionally, there is known an air conditioning system including an air conditioning panel having a large number of pipe members through which fluid flows and a fluid supply device for circulating a high-temperature or low-temperature fluid inside the numerous pipe members (for example, Patent Document 1).
The cooling / heating panel is installed by fixing upper and lower ends to the floor and ceiling surfaces of the indoor space, and is arranged so as to partition adjacent rooms.

JP 2008-121907 A

By the way, the technique which provides the room which has an atrium part in buildings, such as a house, is widely known.
Therefore, there is a desire to install the air conditioning panel as described above in the room having the atrium.
However, the room having the air vents has a higher ceiling height than the room having no air vents, and therefore it may be difficult to adjust the temperature with the air conditioning panel as described above.

  An object of the present invention is to provide a building air conditioning system capable of effectively adjusting the temperature even in a room having an atrium.

In the first aspect of the present invention, for example, as shown in FIGS. 1 to 11, an upper portion of at least a part of a lower-floor room (for example, the dining room 15) is a blow-off portion 4 that blows from the lower floor to the upper floor. And an air conditioning system for a building in which an air conditioning panel 50 is installed from the lower floor to the upper floor via the atrium 4,
The air conditioning panel 50 includes a vertical portion 51 that is vertically arranged from the lower floor to the upper floor, and a horizontal portion 52 that is horizontally disposed above the blow-off portion 4.
The vertical portion 51 and the horizontal portion 52 are formed by arranging a large number of pipe members 53 through which a temperature adjusting fluid is circulated, spaced apart from each other ,
A roof 8b is disposed above the horizontal portion 52, and a space between the horizontal portion 52 and the roof 8b is a shed space 43.
The roof space 43 is provided with a ceiling fan 16 configured to be rotatable forward and backward so as to be positioned above the horizontal portion 52 .

According to invention of Claim 1, since the vertical part 51 formed of the said many pipe members 53 ... is arrange | positioned perpendicularly | vertically from the lower floor to the upper floor via the said blow-off part 4, The temperature of the upper and lower floor space including the blow-off portion 4 can be adjusted from the side. Further, since the horizontal portion 52 formed by the large number of pipe members 53 is horizontally disposed above the blow-off portion 4, the temperature of the upper and lower floor space including the blow-off portion 4 is adjusted from above. be able to. As a result, even in the upper and lower floor space where the ceiling height is increased by including the atrium portion 4, the temperature can be effectively adjusted from the position of the side surface from above, so that the atrium portion 4 is included. The living environment of the upper and lower floor space can be made comfortable.
In addition, hot air or cold air radiated from the upper part of the horizontal part 52 or the vertical part 51 is sent on the air flow by the ceiling fan 16 or sent downward, or the air in the upper and lower floor space including the blow-off part 4 is sent to the hut It can suppress discharging | emitting to the space 43 side, or stirring the air of the upper and lower floor space containing the said blow-off part 4, and generating a spot in the temperature in this upper and lower floor space can be suppressed. Thereby, the living environment of the upper and lower floor space including this atrium part 4 can be made more comfortable.

According to a second aspect of the invention, for example, as shown in FIGS. 1, 5, 7, in the air conditioning system of a building according to claim 1,
Other spaces in the building adjacent to the attic space 43 (for example, the vents 2, 3, and 5) are provided around the attic space 43 and on the wall 43a constituting the attic space 43. A vent hole 44 leading to is formed.

According to the second aspect of the present invention, the wall 43a that constitutes the attic space 43 and other spaces in the building adjacent to the attic space 43 (for example, the atriums 2, 3, and 5). Since the vent hole 44 is formed, air is taken into the cabin space 43 from the other space through the vent hole 44, and the air in the cabin space 43 is discharged to the other space. You can do it. In addition, if the other space is further open to the outdoors, the air in the cabin space 43 can be discharged to the outdoors.

The invention according to claim 3 is the building air conditioning system according to claim 1 or 2 , as shown in FIGS.
The cooling / heating panel 50 is formed in a U-shape in a side view by the plurality of vertical portions 51, 51... Facing each other and the horizontal portion 52 constructed between the upper ends of the plurality of vertical portions 51, 51. It is characterized by being.

According to the invention described in claim 3 , the cooling / heating panel 50 is formed in a U-shape in a side view by the plurality of vertical portions 51, 51... And the horizontal portion 52. The air can be passed in a direction in which the plurality of vertical portions 51 are not provided. Accordingly, the hot and cold air generated by the cooling / heating panel 50 can be circulated not only in the vertical direction in the upper and lower floor space including the blow-off portion 4, but also in the horizontal direction. The living environment around can be made comfortable.

The invention according to claim 4 is the building air conditioning system according to any one of claims 1 to 3 , for example, as shown in FIGS.
A plurality of the vertical portions 51 are arranged in the vicinity of the outer wall 1c of the lower floor and the upper floor at intervals in the width direction of the outer wall 1c,
Openings 14a and 14b are respectively formed in the outer walls 1c of the lower floor and the upper floor corresponding to gaps 51a formed between the plurality of vertical sections 51 and 51, respectively.

According to invention of Claim 4 , opening part 14a, 14b is each formed in the outer wall 1c of the said lower floor and the upper floor corresponding to the clearance gap 51a formed between these vertical parts 51,51. Therefore, outside air can be taken in from these openings 14a and 14b. As a result, the air in the upper and lower floor space including the atrium part 4 can be agitated to suppress the occurrence of spots in the temperature in the upper and lower floor space, so that the living environment of the upper and lower floor space including the aerial part 4 can be further increased. Can be comfortable.

According to the present invention, since the vertical portion formed by a large number of pipe members is arranged vertically from the lower floor to the upper floor via the blow-off portion, the upper and lower floor space including the blow-off portion can be viewed from the side. The temperature can be adjusted. Moreover, since the horizontal part formed of many pipe members is arrange | positioned in the horizontal direction above the blow-off part, the temperature of the upper and lower floor space including the blow-off part can be adjusted from above. Thus, even in the upper and lower floor space where the ceiling height is increased by including the atrium portion, the temperature can be effectively adjusted from the position of the side surface from above, so the upper and lower floor space including the atrium portion. The living environment can be made comfortable.
Moreover, hot air or cold air radiated from the upper part of the horizontal part or vertical part is sent on the air flow by a ceiling fan, or the air in the upper and lower floor space including the blow-off part is discharged to the back of the shed space. Or agitation of the air in the upper and lower floor space including the blow-off portion, and the occurrence of spots in the temperature in the upper and lower floor space can be suppressed. Thereby, the living environment of the upper and lower floor space including this atrium can be made more comfortable.

It is a perspective view which shows the example of introduction to the building of the air conditioning system which concerns on this invention. It is an expansion perspective view of the air conditioning system shown in FIG. It is a top view of the 1st floor of the building where the air conditioning system was introduced. It is a top view of the 2nd floor. It is a top view of the 2nd floor skip floor. It is AA sectional drawing in FIG. FIG. 6 is a sectional view taken along line BB in FIG. It is CC sectional drawing in FIG. FIG. 2 is a schematic diagram illustrating an outline configuration of an air conditioning system according to the present invention and illustrating an operation when used in summer. FIG. 2 is a schematic diagram illustrating an outline configuration of an air-conditioning system according to the present invention and illustrating an operation when used in a relatively warm winter season. FIG. 2 is a schematic diagram illustrating an operation of the cooling / heating system according to the present invention when used in a severe cold season.

Embodiments of the present invention will be described below with reference to the drawings.
1 and 2 are perspective views showing an example of introduction of an air conditioning system according to the present invention into a building.
In FIG. 1, the code | symbol 1 has shown the building main body, and the code | symbol 50 has shown the air conditioning panel which comprises an air conditioning system.
The cooling / heating panel 50 according to the present embodiment functions as a cooling / heating device that cools and heats the interior of the building body 1, and is provided above at least a part of the lower-floor room of the building body 1 and from above the lower floor. It is installed from the lower floor to the upper floor via the atrium part 4 that blows into the floor.

First, the building body 1 in which the air conditioning panel 50 is installed will be described.
The building main body 1 of the present embodiment is a two-story house, and as shown in FIGS. 1 to 5, the building main body 1 is formed in a substantially rectangular shape in plan view. The building body 1 has four aerial parts 2, 3, 4, and 5 that extend from the substantially central portion in plan view toward the four outer walls 1a to 1d in the east, west, south, and north sides and blow out from the first floor to the second floor. Is provided.

The atrium portion 2 extends from the substantially central portion of the building body 1 toward the east side outer wall 1a. Moreover, as shown in FIG.2 and FIG.8, the 1st floor part 6 which has translucency and / or ventilation is provided in the blow-off part 2 in the boundary part of the 1st floor and the 2nd floor.
As the 1st floor part 6, the glass plate which has translucency, and the grating plate which has translucency and ventilation are used. When a glass plate is used, the glass plate is fitted into a rectangular frame formed of a saddle material. The grating plate is a plate-like member provided with a large number of holes in a lattice shape, and this grating plate is directly used as a floor member.

As shown in FIGS. 3 and 4, the outer wall 1a facing the blow-off portion 2 is provided with a vertically long window 7a on the first floor and a window 7b on the second floor at a position slightly depressed from the outer wall 1a. Yes. That is, a substantially central portion in the left-right direction of the outer wall 1a is formed to be recessed, and windows 7a and 7b are provided on the recessed outer wall. Although the windows 7a and 7b are fitted-in windows, they can be opened and closed.
As shown in FIG. 8, the atrium portion 2 is blown from the floor of the east side corridor on the first floor to directly below the roof ridge, and the upper end portion of the atrium portion 2 is on one roof 8a side of the gable roof. It is bent at a right angle and further bent toward the roof 8a side. A skylight 9 is provided on the roof 8a so as to be openable and closable and communicated with the blow-off portion 2.

  In addition, as shown in FIGS. 5-8, the solar cell panel is provided in the other roof 8b of the gable roof. This roof 8b faces south, and the length from the ridge to the eaves is longer than the length from the ridge to the eaves of one roof 8a. In addition, an air layer is provided between the solar cell panel and the roof 8a, and air in the air layer heated by solar heat is provided on the first floor by hot air ducts 8c arranged above and below by a fan (not shown). It is transported under the floor, stored in the foundation, and used as floor heating utilizing natural energy. The hot air duct 8 c is provided from the roof ridge to the bottom of the floor through the blow-off portion 4.

  As shown in FIGS. 4 and 7, the second floor portion 10 is adjacent to the first floor portion 6 and is flush with the first floor portion 6 at a substantially central portion in plan view of the building body 1. It has been. The second floor portion 10 is constituted by a floor panel and constitutes the floor of the second floor staircase. The second floor 10 is a structural material and is connected to surrounding walls.

The atrium 3 extends from the second floor 10 at the approximate center of the building body 1 toward the outer wall 1b on the west side. Moreover, as shown in FIG.4 and FIG.8, the 1st floor part 11 which has translucency and / or ventilation is provided in the atrium part 3 in the boundary part of the 1st floor and the 2nd floor. The first floor 11 is adjacent to the second floor 10 and is flush with the second floor 10.
As shown in FIGS. 3 and 4, the outer wall 1b facing the blow-off portion 3 is provided with a vertically long window 12a on the first floor and a window 12b on the second floor at a position slightly recessed from the outer wall 1b. . The windows 12a and 12b are fitting-in windows, but may be windows that can be opened and closed.
As shown in FIG. 8, the atrium 3 is blown from the floor of the west corridor on the first floor to directly below the roof ridge, and the upper end of the atrium 3 is located on the side of the roof 8a of the gable roof. It is bent at a right angle and further bent toward the roof 8a side. A skylight 13 is provided on the roof 8a so as to be openable and closable and communicated with the blow-off portion 3.

The atrium 4 extends from the second floor 10 at the approximate center of the building body 1 toward the outer wall 1c on the south side.
Further, as shown in FIGS. 3 and 4, the vertically long window 14 a is provided on the first floor and the window 14 b is provided on the second floor on the outer wall 1 c facing the blow-off portion 4. The windows 14a and 14b are windows that can be opened and closed.
As shown in FIG. 7, the atrium 4 is ventilated from the floor surface of the dining room 15 on the first floor to the roof 8 b.
In addition, a horizontal portion 52 (described later) constituting the cooling / heating panel 50 is disposed below the roof 8b. A space between the horizontal portion 52 and the roof 8b is a shed space 43. In the shed space 43, a ceiling fan 16 configured to be rotatable forward and backward is attached to the roof 8b so as to be positioned above the horizontal portion 52.
Regarding the ceiling fan 16 of the present embodiment, the rotation in the direction of sending the wind downward from the ceiling fan 16 is set as normal rotation, and the rotation in the direction of sending the wind upward from the ceiling fan 16 is reversed. Rotate.

In addition, as shown in FIGS. 1, 5, and 7, a plurality of walls 43 a and 43 b constituting the shed space 43 are provided around the shed space 43.
The walls 43a are provided on both sides of the hot air duct 8c and face the upper space of the second floor 10. In addition, vents 44 and 44 are formed in the walls 43a and 43a, respectively. Therefore, the vent holes 44 and 44 allow the cabin space 43 to communicate with the upper space of the second floor portion 10 adjacent to the cabin space 43. In addition, the outer wall 1c shall be provided in the position facing these walls 43a and 43a.
Further, the wall 43b is provided on the side of the hut space 32c, 34c of the second floor rooms 32, 34 (described later) adjacent to the atrium 4 and the shed space 43 and these shed spaces 32c. , 34c.

The atrium 5 extends from the second floor 10 located substantially in the center of the building body 1 toward the north outer wall 1d.
Moreover, as shown in FIGS. 3-5, the window 17a is provided in the 1st floor, and the windows 17b and 17c are provided in the 2nd floor in the outer wall 1d which faces the blow-off part 5. FIG. The windows 17a, 17b, and 17c are windows that can be opened and closed, and the outer wall 1d provided with the windows 17a, 17b, and 17c protrudes from the left and right outer walls.
As shown in FIG. 7, the blow-through portion 5 is blown from the floor surface of the staircase to just below the roof 8 a, and the upper end portion of the blow-through portion 5 communicates with a skylight 18 provided on the roof 8 a.
A staircase 20 is provided in the blow-off portion 5. The staircase 20 includes a first staircase 20a provided between the floor of the staircase hall on the first floor and the skip floor 21, and the second floor portion 10 constituting the floor of the staircase hall on the second floor. The second staircase 20b is provided between the second staircase 20b and the third staircase 20c is provided between the second floor 10 and the skip floor 22.

The skip floor 21 is provided at approximately half the height of the first floor, and the space between the skip floor 21 and the first floor is a lower floor storage 23 as shown in FIG. ing. The ceiling height of the first floor underfloor storage 23 is about 0.9 to 1.4 m.
The skip floor 22 is provided at approximately half the height of the second floor, and a tatami mat is laid between the skip floor 22 and the skip floor 21 as shown in FIGS. A tatami room 24 and a landing 25 are provided. Further, as shown in FIG. 8, a second-floor storage 26 is provided between the skip floor 22 and the second-floor. The ceiling height of the second floor underfloor storage 26 is about 0.9 to 1.4 m.
As shown in FIGS. 3 and 6, the first floor underfloor storage 23 is provided at the northeast corner of the building body 1, and on the first floor underfloor storage 23, as shown in FIGS. 2 and 8. A tatami room 24 is provided. A child room 27 is provided on the tatami room 24 as shown in FIGS.

Further, as shown in FIG. 4, the second floor underfloor storage 26 is provided at the northwest corner of the building body 1. Under the second floor underfloor storage 26, as shown in FIGS. 3 and 8. An entrance 28 is provided, and a study 29 is provided on the second floor underfloor storage 26 as shown in FIGS. In addition, as shown in FIG. 4, a closet 30 is provided adjacent to the second-floor storage 26. The ceiling of the closet 30 is substantially equal to the ceiling of the study 29. The upper portion of the closet 30 is blown up to the roof 8a, and a skylight 35 is provided on the roof 8a so as to be opened and closed as shown in FIG.
Further, as shown in FIGS. 3 and 8, a living room 31 is provided at the southwest corner of the first floor of the building body 1, and a second-floor room 32 serving as a main bedroom is provided on the living room 31. It has been. As shown in FIGS. 3 and 6, a kitchen 33 is provided at the southeast corner of the building body 1, and a second-floor room 34 serving as a bathroom and a washroom is provided on the kitchen 33. .

Moreover, as shown in FIG. 4, the wall which partitions the hallway comprised of the said 1st floor part 11 and the room 32 is provided with the door 32a, and this room 32 is opened to the hallway by opening this door 32a. It can be opened greatly toward the. Moreover, the door 34a is provided in the wall which partitions the hallway comprised by the 1st floor part 6, and the room 34, and it becomes possible to open the room 34 toward a hallway now by opening this door 34a. ing.
In addition, a plurality of glass partitions 32b and 34b are provided between the rooms 32 and 34 on the second floor and the blow-off portion 4, as shown in FIGS. 1, 2, 4, and 6 to 8. Is provided. These glass partitions 32b and 34b cannot be opened and closed, but have a function as a translucent wall. Therefore, it is not necessary to use glass as in the present embodiment, and another member having translucency may be used.

A balcony 36 is provided adjacent to the room 32 on the outer wall 1 c on the south side of the building body 1. A plurality of louver doors 37 that are slidable in the left-right direction are provided at the tip of the balcony 36. The louver door 37 is formed by attaching a plurality of cross members up and down in parallel at a predetermined interval in a rectangular frame so that light and wind (air) can pass therethrough. Moreover, the louver door 37 is also provided in front of the outer wall 1c which the said blow-off part 4 faces. An outdoor vent 38 is provided between the louver door 37 and the outer wall 1c facing the vent 4.
Furthermore, a balcony structure 40 is provided at the southeast corner of the building body 1. The inside of this balcony structure 40 is the thermal storage soil 41, and the upper surface constitutes the floor surface of the balcony 42 on the second floor. This balcony 42 is provided adjacent to the room 34 on the second floor.

In the building having the above-described configuration, the wind (air) or the like that has entered the windows 14a, 14b provided on the outer wall 1c facing the blow-off portion 4 or the windows 17a, 17b, 17c provided on the outer wall 1d facing the blow-off portion 5 Light spreads up and down through the first floors 6 and 11 and the stairs 20 and also in the lateral direction.
Further, the light that enters the windows 7a and 7b provided on the outer wall 1a facing the blow-off portion 2 and the windows 12a and 12b provided on the outer wall 1b facing the blow-off portion 3 passes through the first floor portion 6 and the stairs 20. Go up and down and go sideways.
Therefore, since light and air can be spread over the upper and lower floors and from the central part of the building body 1 to the outer walls 1a, 1b, 1c, 1d, it is easy to light and ventilate the entire building. Can be secured.

Moreover, since the skylights 9, 13, and 18 are provided in the roof 8a of the building main body 1 so as to communicate with the blowout portions 2, 3, and 5, the blowout portions 2 and 14 are opened from the windows 14a, 14b, 17a, 17b, and 17c. The wind (air) that has entered 3 and 5 can be extracted from the skylights 9, 13, and 18, so that the air circulation in the building body 1 is improved. Moreover, since the light which entered from the skylights 9, 13, and 18 can be introduce | transduced into the blow-off parts 2, 3, and 5, the lighting property in the building main body 1 becomes still better.
Moreover, since the stairway 20 and the 1st floor part 6 are not provided in the blow-off part 4, lighting and ventilation can be ensured more reliably by this blow-off part 4.
Furthermore, since the second floor portion 10 is adjacent to the first floor portions 6 and 11 and is flush with the first floor portions 6 and 11 in the substantially central portion of the building body 1 in plan view, The structural stability of the building body 1 is enhanced even if there are the vents 2, 3, 4 and 5 extending from the substantially central part of the building body 1 in plan view toward the outer wall.
In addition, the first floor portions 6 and 11 constitute a floor portion of the hallway, and doors 32a and 34a are provided on the walls separating the hallway and the rooms 32 and 34 adjacent to the hallway. Therefore, the blow-through portions 2, 3 from the windows 7a, 7b, 12a, 12b, 14a, 14b, 17a, 17b, 17c provided on the outer walls 1a, 1b, 1c, 1d facing the blow-through portions 2, 3, 4, 5 , 4 and 5 can be introduced into the rooms 32 and 34 adjacent to the hallway by opening the door.

Next, the air conditioning panel 50 will be described.
As shown in FIGS. 1 to 11, the air-conditioning panel 50 of the present embodiment is arranged in a horizontal direction above the vertical portion 51 arranged vertically from the lower floor to the upper floor, and above the blow-off portion 4. The horizontal portion 52 is formed. Further, the vertical portion 51 and the horizontal portion 52 are formed by arranging a large number of tube members 53 through which a temperature adjusting fluid is circulated, spaced apart from each other.

In addition, the air conditioning panel 50 is installed from the lower floor to the upper floor via the atrium 4 at the position where the dining room 15 is disposed.
Further, the cooling / heating panel 50 includes a plurality of vertical portions 51, 51... Facing each other and a horizontal portion 52 constructed between upper ends of the plurality of vertical portions 51, 51. Is formed. In other words, in the present embodiment, a plurality of vertical portions 51, 51... Are divided into an outdoor side and a staircase 20 side through the dining room 15 so as to face each other.

Further, a plurality of outdoor-side vertical portions 51 and a plurality of vertical portions 51 on the staircase 20 side are provided at intervals in the height direction and the width direction.
That is, on the outdoor side, four vertical portions 51 are spaced apart on the lower floor side and the upper floor side, and are provided in the vicinity of the outer wall 1c and in the width direction of the outer wall 1c. Further, on the outer wall 1c, the windows 14a and 14b are respectively formed corresponding to the gaps 51a formed between the vertical portions 51 and 51 divided into left and right among the plurality of outdoor vertical portions 51. ing.
Further, on the stairs 20 side, four vertical portions 51 are provided to face the four outdoor vertical portions 51, respectively. Further, the four vertical portions 51 on the staircase 20 side are provided on both sides of the hot air duct 8c.
That is, in the present embodiment, eight vertical portions 51 are used, and two vertical portions 51, 51 are provided on the outdoor side on the lower floor, and two vertical portions are provided on the stairs 20 side. 51, 51 are provided. On the upper floor, two vertical portions 51, 51 are provided on the outdoor side, and two vertical portions 51, 51 are provided on the staircase 20 side.

In addition, the vertical parts 51 and 51 adjacent to an up-down direction are connected by the connection member 54, as shown in FIG.1, FIG.2, FIG.7.
The connecting member 54 is formed in a rectangular plate shape, and is fixed to the lower end portion of the upper vertical portion 51 and the upper end portion of the lower vertical portion 51. As a result, the gap between the vertical portions 51 and 51 adjacent in the vertical direction can be hidden, and the vertical portions 51 and 51 can be shown integrally in the vertical direction.
The connecting member 54 connects the lower floor side vertical portion 51 and the upper floor side vertical portion 51, and is thus provided at a position between the lower floor and the upper floor.

The horizontal portion 52 includes upper ends of two vertical portions 51, 51 provided on the outdoor side of the upper floor, and two vertical portions 51, 51 on the staircase 20 side facing the two vertical portions 51, 51. It is erected between the upper end of the.
The staircase 20 side of the horizontal portion 52 is formed in a concave shape corresponding to the shape of the hot air duct 8c, as shown in FIGS.
Further, as described above, on the outdoor side of the upper floor and the staircase 20 side, a gap 51a is formed between the vertical portions 51 and 51 that are divided into left and right, and a hot air duct 8c is provided. The horizontal portion 52 in the form is also provided above the gap 51a and the hot air duct 8c.

The pipe member 53 constituting the vertical part 51 and the horizontal part 52 is formed of a heat conductive material such as aluminum. In addition, although the cross-sectional shape in the direction orthogonal to the axis of the pipe member 53 of the present embodiment is a rectangular shape, it is not limited to this, and may be a circular shape, an oval shape, a square shape, or the like.
As shown in FIGS. 1, 2, and 7, the pipe members 53 are arranged in parallel with a space therebetween, and the end portions of the pipe members 53 are spaced from each other by a support member 55. It is supported by.

Moreover, in this Embodiment, many pipe members 53 ... which respectively comprise the four vertical parts 51 ... of the said lower floor are many pipe members 53 which each comprise the four vertical parts 51 ... of the said upper floor. ... and the edge is cut.
Further, a large number of pipe members 53 constituting the four vertical portions 51 on the upper floor are integrally formed with a large number of pipe members 53 constituting the horizontal portion 52, respectively.
That is, the two pipe members 53 and 53 constituting the vertical portion 51 facing each other on the upper floor, and the horizontal portion 52 are constructed between the upper ends of the two pipe members 53 and 53. The pipe member 53 is integrally formed, and is formed in a U-shape when viewed from the side.
Then, by arranging a large number of pipe members 53 formed in a U shape in a side view in this manner at a distance from each other, the upper floor vertical portions 51 and the horizontal portion 52 are simultaneously provided on the upper floor. Can do. However, the tube member 53 constituting the horizontal portion 52 of the portion where the gap 51a between the vertical portions 51 and 51 is provided and the portion where the hot air duct 8c is provided is simply a straight tube member 53.
In addition, inside the U-shaped tube member 53 in a side view, the temperature adjusting fluid can be circulated without a stagnation from one end portion of the tube member 53 to the other end portion. That is, the fluid can be circulated by tracing the U-shape.
In the present embodiment, the two pipe members 53, 53 constituting the vertical portion 51 facing each other on the upper floor and the upper ends of the two pipe members 53, 53 are installed and Although the single pipe member 53 constituting the horizontal portion 52 is integrally formed, the present invention is not limited to this and may be formed separately.

Moreover, the above air conditioning panel 50 is connected with the fluid supply apparatus 60 which distribute | circulates high temperature or low temperature water inside this air conditioning panel 50, as shown in FIGS.
The fluid supply device 60 includes a pipe 61, pumps 62 and 63, three-way valves 64 and 65, a fuel boiler 66, and a heat pump 67.
In addition, although many pipe members 53 ... shown in FIGS. 9-11 shall comprise the said vertical part 51 in this Embodiment, it is not restricted to this, The said horizontal part 51 is comprised. It is good as a thing.

The pipes 61 are connected to the upper pipes 611 connected to the upper ends of the multiple pipe members 53 in a state where fluid can be circulated, and to the lower ends of the multiple pipe members 53 in a state where fluid can be circulated. And a lower pipe 612. That is, the holes of the numerous pipe members 53 are continuously connected to the holes of the upper pipe 611 and the holes of the lower pipe 612.
A base end portion of the upper pipe 611 is connected to a three-way valve 64, and the three-way valve 64 is connected to a fuel boiler 66 and a heat pump 67 via connection pipes 613 and 614.
On the other hand, the base end portion of the lower pipe 612 is connected to a three-way valve 65, and the three-way valve 65 is connected to a fuel boiler 66 and a heat pump 67 via connection pipes 615 and 616.
The piping 61 and the numerous pipe members 53 form a first closed path 617 that passes through the fuel boiler 66 and a second closed path 618 that passes through the heat pump 67.

The pump 62 is provided on the connection pipe 613 and is driven when the fuel boiler 66 is used.
The pump 63 is provided on the connection pipe 616 and is driven when the heat pump 67 is used.
The fuel boiler 66 is a device that heats the water in the pipe 61 by burning fuel such as kerosene. The fuel boiler 66 is driven when the outside air temperature is lower than a predetermined temperature at which the heat pump 67 sufficiently exhibits its capability, that is, for example, lower than 0 ° C.
The heat pump 67 includes a compressor, an expansion valve, and a heat exchanger, and utilizes a heat generation phenomenon when the refrigerant is compressed by the compressor and a heat absorption phenomenon when the refrigerant is expanded by the expansion valve. It is a device that heats and cools water in the pipe 61 via a heat exchanger. Such a heat pump 67 is driven when the outside air temperature is equal to or higher than a predetermined temperature at which the heat pump 67 sufficiently exhibits its ability. That is, for example, when the outside air temperature is 0 to 25 ° C., the water in the pipe 61 is heated, and when the outside air temperature exceeds 25 ° C., the water inside the pipe 61 is cooled. Note that alternative refrigerant, CO ₂ gas, or the like can be used for the refrigerant in the heat pump 67. In addition, the predetermined temperature at which the heat pump 67 sufficiently exhibits the capability is not limited to 0 ° C., but is appropriately set according to the size and installation location of the cooling / heating panel 50, the capability of the heat pump 67, and the like.

Next, an embodiment of adjusting the temperature around the upper and lower floor space including the ventilating portion 4 performed by the air conditioning panel 50 will be described.
First, the operation of the air conditioning system in summer will be described with reference to FIG.
In the summer when the outside air temperature is 25 ° C. or higher, for example, the fluid supply device 60 distributes cold water inside the cooling / heating panel 50.
That is, the three-way valve 64 is opened to connect the upper pipe 611 and the connection pipe 614, and the three-way valve 65 is opened to connect the lower pipe 612 and the connection pipe 616. That is, the second closed path 618 passing through the heat pump 67 is formed. And while cooling the water in the piping 61 with the heat pump 67, the pump 63 is driven so that the flow shown by the arrow in the figure may be formed. As a result, the cold water circulates in the numerous pipe members 53... From the top to the bottom, and the indoor space is cooled.

Next, the operation of the air conditioning system in winter will be described with reference to FIGS.
In a relatively warm winter where the outside air temperature is, for example, 0 ° C. or higher, the fluid supply device 60 circulates hot water inside the cooling / heating panel 50 as shown in FIG.
That is, the three-way valve 64 is opened to connect the upper pipe 611 and the connection pipe 614, and the three-way valve 65 is opened to connect the lower pipe 612 and the connection pipe 616. That is, the second closed path 618 passing through the heat pump 67 is formed. And while heating the water in the piping 61 with the heat pump 67, the pump 63 is driven so that the flow shown by the arrow in the figure may be formed. As a result, the hot water circulates in the numerous pipe members 53... From the bottom to the top, thereby warming the indoor space.

On the other hand, in the severe cold season when the outside air temperature is, for example, less than 0 ° C. in winter, the fluid supply device 60 circulates hot water inside the cooling / heating panel 50 as shown in FIG.
That is, the three-way valve 64 is opened to connect the upper pipe 611 and the connecting pipe 613, and the three-way valve 65 is opened to connect the lower pipe 612 and the connecting pipe 615. That is, the first closed path 617 that passes through the fuel boiler 66 is formed. Then, the water in the pipe 61 is heated by the fuel boiler 66 and the pump 62 is driven so that the flow indicated by the arrow in the figure is formed. As a result, the hot water circulates from the bottom to the top of the numerous pipe members 53, so that the indoor space can be warmed at a higher temperature.

  Further, as described above, cold water, hot water, or the like may be circulated inside the air conditioning panel 50, and the ceiling fan 16 may be operated to adjust the temperature in the upper and lower floor space including the blow-off portion 4.

That is, by rotating the ceiling fan 16 in the forward direction, hot air (warm air) or cold air radiated from the horizontal portion 52 or the vertical portions 51 of the upper floor can be sent toward the lower floor. That is, since the multiple pipe members 53... Constituting the vertical part 51 and the horizontal part 52 are arranged in parallel with each other at intervals, it is possible to allow air to pass through the gap between the adjacent pipe members 53 and 53. it can. As a result, hot air or cold air radiated from the tube member 53 can be sent on the airflow downward.
Furthermore, the hot air and cold air sent to the lower floor can be circulated not only in the dining room 15 located below the blow-off portion 4 but also in the lateral direction toward the living room 31 and the kitchen 33 adjacent to the dining room 15.

Further, by rotating the ceiling fan 16 in the reverse direction, the air in the upper and lower floor space including the blow-off portion 4 can be discharged to the shed space 43 side.
Further, the air exhausted to the side of the shed space 43 can be exhausted to the space above the second floor portion 10 through the vent holes 44, 44 formed in the walls 43a, 43a constituting the shed space 43. . And since the upper space of this 2nd floor part 10 is following the said blow-off parts 2, 3, and 5, as shown in FIGS. 5-8, it is discharged | emitted by the upper space of this 2nd floor part 10. FIG. The air can be discharged from the skylights 9, 13, 18, 35 to the outdoors. Thereby, ventilation in the building body 1 can be promoted.

  In particular, by utilizing the property that warm air rises higher, warm air on the lower floor is sent to the upper floor, and warm air on the upper floor is sent to the shed space 43 side. Ventilation in the building body 1 can be performed. At this time, if the ceiling fan 16 is operated in the reverse rotation, the ventilation efficiency can be improved.

  Also, by rotating the ceiling fan 16 in the reverse direction with cold water flowing through the cooling / heating panel 50, it is possible to send cool air to the shed space 43 side. When the temperature becomes high, the temperature of the cabin space 43 can be lowered.

Furthermore, the air in the upper and lower floor spaces including the blow-off portion 4 can be agitated only by rotating the ceiling fan 16 forward or backward, and the temperature in the upper and lower floor spaces is uneven. Can be suppressed.
Further, by alternately performing forward and reverse rotations of the ceiling fan 16 in combination, the air in the upper and lower floor spaces including the blow-off portion 4 can be more efficiently agitated.

  Further, by opening the windows 14a and 14b formed on the outer walls 1c of the lower floor and the upper floor, it is possible to take in outside air from the outside or to discharge air to the outside. As a result, the air in the upper and lower floor spaces including the ventilating portion 4 can be agitated and the ventilation efficiency can be improved.

According to the present embodiment, the plurality of vertical portions 51 formed by the plurality of pipe members 53 are vertically arranged from the lower floor to the upper floor via the blow-off portion 4. The temperature of the upper and lower floor space including the blow-off portion 4 can be adjusted from the side.
Further, since the horizontal portion 52 formed by the large number of pipe members 53 is horizontally disposed above the blow-off portion 4, the temperature of the upper and lower floor space including the blow-off portion 4 is adjusted from above. be able to.
As a result, even in the upper and lower floor space where the ceiling height is increased by including the atrium portion 4, the temperature can be effectively adjusted from the position of the side surface from above, so that the atrium portion 4 is included. The living environment of the upper and lower floor space can be made comfortable.

Further, since the ceiling fan 16 configured to be able to rotate forward and reverse is provided so as to be positioned above the horizontal portion 52, hot air or cold air radiated from above the horizontal portion 52 or the vertical portion 51 is provided. On the airflow generated by the ceiling fan 16, or the air in the upper and lower floor space including the blow-off portion 4 is discharged to the shed space 43 side, or the air in the upper and lower floor space including the blow-off portion 4. It is possible to suppress the occurrence of spots in the temperature in the upper and lower floor spaces.
Thereby, the living environment of the upper and lower floor space including this atrium part 4 can be made more comfortable.

The walls 43a and 43a constituting the cabin space 43 are formed with vents 44 and 44 that communicate with the upper space of the second floor portion 10 adjacent to the cabin space 43 and the vents 2, 3, and 5. Therefore, air is taken into the shed space 43 from the upper space of the second floor portion 10 and the vents 2, 3, and 5 through the ventilation holes 44, 44, or inside the shed space 43. Can be discharged to the upper space of the second floor 10 and the blow-through portions 2, 3, 5.
Moreover, since the said blow-off parts 2, 3, and 5 are connected to the outdoors via the said skylights 9, 13, 18, and 35, the air in the said shed space 43 can also be discharged | emitted outdoors.

Further, since the cooling / heating panel 50 is formed in a U-shape in a side view by the plurality of vertical portions 51, 51... And the horizontal portion 52, the plurality of vertical portions are disposed below the horizontal portion 52. Air can be passed in a direction in which 51, 51... Are not provided.
Accordingly, the hot and cold air generated by the cooling / heating panel 50 can be circulated not only in the vertical direction in the upper and lower floor space including the blow-off portion 4, but also in the horizontal direction. The living environment around can be made comfortable.

Moreover, since the opening parts 14a and 14b are each formed in the outer wall 1c of the said lower floor and the upper floor corresponding to the clearance gap 51a formed between these vertical parts 51 and 51, these opening parts 14a, The outside air can be taken in from 14b.
As a result, the air in the upper and lower floor space including the atrium part 4 can be agitated to suppress the occurrence of spots in the temperature in the upper and lower floor space, so that the living environment of the upper and lower floor space including the aerial part 4 can be further increased. Can be comfortable.

DESCRIPTION OF SYMBOLS 1 Building body 1c Outer wall 4 Vent part 14a Window 14b Window 16 Ceiling fan 43 Hut space 43a Wall 44 Vent 50 Air-conditioning panel 51 Vertical part 52 Horizontal part 53 Pipe member

Claims (4)

The upper part of at least a part of the room on the lower floor is a ventilated part that blows through from the lower floor to the upper floor, and the air conditioning panel is installed from the lower floor to the upper floor through this ventilated part. An air conditioning system,
The air-conditioning panel is composed of a vertical part arranged vertically from the lower floor to the upper floor, and a horizontal part arranged in a horizontal direction above the blow-off part,
The vertical part and the horizontal part are formed by arranging a large number of pipe members through which a temperature adjusting fluid is circulated, spaced apart from each other ,
A roof is arranged above the horizontal part, and the space between the horizontal part and the roof is a shed space,
The building cooling and heating system is characterized in that a ceiling fan configured to be able to rotate forward and backward is provided in the cabin space so as to be positioned above the horizontal portion . In the building air conditioning system according to claim 1 ,
The building is characterized in that it is provided around the attic space, and a wall that forms the attic space is formed with a vent hole that communicates with other spaces in the building adjacent to the attic space. Air conditioning system. In the building air conditioning system according to claim 1 or 2 ,
The air conditioning panel is formed in a U-shape in a side view by a plurality of the vertical parts facing each other and the horizontal part constructed between upper ends of the plurality of vertical parts. Air conditioning system. In the building air conditioning system according to any one of claims 1 to 3 ,
A plurality of the vertical portions are arranged in the vicinity of the outer walls of the lower floor and the upper floor at intervals in the width direction of the outer walls,
The building cooling and heating system is characterized in that openings are formed in the outer walls of the lower floor and the upper floor respectively corresponding to the gaps formed between the plurality of vertical sections.

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