JP2018112362A - Air conditioning equipment and building equipped with the same - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an air conditioning system using radiation panels, capable of making a ceiling surface neat by simplifying a ventilation structure.SOLUTION: Radiation panels 1 have radiation plates 2 and pipes 3, and the inside of a room is radiation-heated or cooled by allowing a fluid as a heat medium to flow in the pipes 3. A clearance is formed between adjacent radiation panel rows, and side edges of the adjacent radiation panels 1 are supported by a horizontal flange 19 of a hanging tool 17. As lower faces of the radiation panels 1 are unevenly formed, clearances 24, 25 as ventilation spaces are respectively formed between the radiation panel 1 and the hanging tool 17. An upper part of a group of radiation panels 1 defines a buffer space for ventilation 26, and the indoor air is sucked to the buffer spacer for ventilation 26 from the clearances 24, 25. As the space between the radiation panel 1 and the hanging tool 17 can be utilized as the ventilation space, the number of components can be reduced, and neat appearance can be provided.SELECTED DRAWING: Figure 6

Description

  The present invention relates to an air conditioning facility using a radiation panel and a building equipped with the same. The air conditioning equipment includes both a single function only for heating or cooling and a double function capable of performing cooling and heating.

  There is a radiant air conditioning system (radiant air conditioning system) that uses a liquid (fluid) such as water as a heat medium and cools or heats it with a radiant panel cooled or heated by the liquid. There is an advantage such as lack of comfort and is becoming popular. In this radiant air-conditioning facility, temperature management is performed by managing the temperature of the water flowing through the radiant panel. However, since there is no indoor ventilation function or humidity control function, a ventilation means is also provided.

  The ventilation means is generally a set of air supply and exhaust, but it is common to provide an air supply or exhaust port in the ceiling, and as an example, Patent Document 1 discloses an air blower with a fan. It is disclosed that a duct is opened between adjacent radiating panels to open an exhaust duct on a wall surface.

Japanese Patent No. 4079269

  In terms of performing air supply or exhaust evenly, it is reasonable to provide an air supply or exhaust port on the ceiling surface. However, in the configuration of Patent Document 1, since the air blower pipe is provided with a fan, the air blower pipe is opened only in a part of the ceiling surface, and therefore, the function of spreading the conditioned air uniformly throughout the room is inferior. It can be said.

  Also, whether it is an air supply port or an exhaust port, it is conventionally formed in a square shape or a circular shape in a plan view and is arranged only on a part of the ceiling part. In order to provide this, it is normal to leave a space between the adjacent radiant panels so that the air supply port or exhaust port can be accommodated, and the part where the air supply port or exhaust port is not placed is covered with a cover. For this reason, a large dead space is generated in order to provide the air supply port or the exhaust port. As a result, the laying area of the radiating panel is reduced, and the air conditioning function may not be improved.

  In addition, even if it is a cover, whether it is an air supply port or an exhaust port, people enter the field of view when they raise their faces. .

  Furthermore, it has been found that when air is stirred under the radiant panel, the film heat transfer coefficient increases and air conditioning efficiency can be increased. Therefore, air conditioning efficiency can be improved by stirring air using ventilation or the like. It can be said that the energy can be used effectively. For example, as in Patent Document 1, when the air is blown directly down from the air blowing pipe, the ventilation air is blown downward, and the air is stirred below the radiant panel. There is still room for improvement in terms of effective use of energy.

  The present invention has been made to improve the current situation.

The present invention includes various configurations, and typical examples thereof are specified in the respective claims. Of these, in the invention of claim 1, in the air conditioning equipment,
The ceiling part is provided in the suspension as a structure having a radiation panel group in which radiation panels having a square shape in plan view are arranged vertically and horizontally and a suspension that supports the side edge of the adjacent radiation panel. The horizontal flange supports the side edge of the radiating panel from below, and forms a ventilation space for indoor ventilation between the radiating panel and the hanger.

The invention of claim 2 is a development example of claim 1, and in this invention,
The entire ceiling space above the ceiling portion is formed as a ventilation buffer space communicating with the ventilation space, and an air supply duct or a discharge duct for ventilation is opened in the buffer space.

The invention of claim 3 embodies claim 1 or 2,
While the hanger has a vertical part rising upward from the horizontal flange,
Each of the radiating panels has a concavo-convex surface so that two parallel end faces are concavo-convex end faces, and a large number of radiating panels are arranged so that the concavo-convex end faces face the vertical part of the suspension. The ventilation space is formed by utilizing the uneven shape on the lower surface of the radiating panel, with a space between the uneven end surface of the radiating panel and the vertical portion of the hanger.

The invention of claim 4 also embodies claim 1 or 2, and in this invention,
While the hanger has a vertical part rising upward from the horizontal flange,
The lower surface of the radiating panel is a flat surface, and a space is provided between the end surface of the radiating panel and the vertical portion of the hanger, and a spacer is interposed between the lower surface of the radiating panel and the vertical portion of the hanger. Thus, the ventilation space is formed. In addition, the form (punching metal specification) with many small holes is also contained in the radiation | emission panel in which the lower surface is a flat surface.

  The present invention includes a building, and the building is provided with the air conditioning equipment according to any one of claims 1 to 4.

  In the present invention, since the ventilation space formed between the radiating panel and the hanger is used as an air supply port or an exhaust port, the air supply port or the exhaust port can be formed over a wide range of the ceiling surface. For this reason, it is possible to easily supply air evenly into the room and exhaust air evenly from the room, which contributes to improvement in ventilation performance.

  In addition, since the air supply and exhaust ports are formed by using the radiant panel and the hanger, which are indispensable elements for air conditioning equipment, it can contribute to cost reduction by omitting or reducing members. . In addition, since it is not necessary to provide a wide space between groups of adjacent radiating panels, it is possible to increase the arrangement area of the radiating panels, thereby improving the air conditioning performance.

  Furthermore, the hanging tool also has a function of a joint material that makes the gap between adjacent radiating panels invisible from below, but the suspending tool needs only to have a width sufficient to suspend the radiating panel. You can improve the aesthetics by refreshing the ceiling. That is, it is possible to abolish the arrangement of long and wide belt-like covers between groups of adjacent radiating panels, and thus it is possible to improve the aesthetic appearance.

  Furthermore, when the ventilation space is used as an air supply port, the air flows along the lower surface of the radiant panel and then changes its direction downward. It will tend to flow along the lower surface of the radiant panel and then flow into the ventilation space. In any case, air flows along the lower surface of the radiant panel along with ventilation, so Since the film heat transfer coefficient can be increased by stirring the air conditioning efficiency, the air conditioning efficiency can be improved.

  When the entire ceiling space is used as a ventilation buffer space as in claim 2, the structure can be simplified and the cost can be further reduced. In addition, since it is more reliable to supply air to every corner of the room and to exhaust air from every corner of the room, it is possible to easily realize uniform ventilation of the room.

  In the structure of Claim 3, since the ventilation space can be formed by using the unevenness of the lower surface of the radiating panel, a special member for forming the ventilation space is not necessary, and therefore, the cost suppressing effect is excellent.

  As for the radiant panel, there are users who want a flat bottom surface, but if the configuration of claim 4 is adopted, a ventilation space can be easily formed even for a radiant panel having a flat bottom surface such as a flat plate type or a punching metal type. Therefore, the application target can be expanded.

It is a perspective view of the room interior of the building according to the embodiment. It is sectional drawing which looked at the building from the same direction as FIG. (A) is a top view of a radiation panel, (B) is a BB view of (A). FIG. 4 is a cross-sectional view taken along the line IV-IV in FIG. 3 (the cross-sectional display of the radiation plate and pipe is omitted). It is a partial top view of a ceiling part. 5A is a cross-sectional view taken along line AA in FIG. 5, FIG. 5B is a cross-sectional view taken along line BB in FIG. 5, and FIG. 5C is a cross-sectional view taken along line CC in FIG. (A) is a principal part longitudinal front view of 2nd Embodiment, (B) is a principal part longitudinal front view of 3rd Embodiment. (A) is a principal part longitudinal side view of 4th Embodiment, (B) is BB sectional drawing of (A), (C) is a principal part longitudinal side view of 5th Embodiment. (A) is sectional drawing of 6th Embodiment, (B) is sectional drawing of 7th Embodiment. It is a figure which shows 8th Embodiment, (A) is a typical front view, (B) is a typical top view. It is principal part sectional drawing of 9th Embodiment.

(1). First Embodiment Next, an embodiment of the present invention will be described with reference to the drawings. First, a first embodiment shown in FIGS. 1 to 6 will be described. 1 and 2, the outline of the building and the air conditioning equipment is displayed. As shown in these figures, the ceiling of the room is composed of a large number of radiating panels 1 arranged in the front, rear, left and right (vertical and horizontal). I have.

  The radiating panel 1 has a rectangular shape as clearly shown in FIG. 3, and radiating panel rows are formed by arranging the radiating panel by arranging the long sides in contact with each other in the front-rear direction, and the radiating panels adjacent to the left and right There is a certain space (gap, space) between the rows.

  In the present embodiment, as described above, front / rear / left / right words are used to specify the direction, but the direction along the short side of the radiating panel 1 is the front / rear direction, and the direction along the long side of the radiating panel 1 is Defined as directions (these directions are for convenience of explanation). The front view is a state seen from the front-rear direction, and the side view is a state seen from the left-right direction. As a precaution, the directions are clearly shown in FIGS.

  As shown in FIGS. 3 and 4, the radiating panel 1 includes six radiating plates 2 arranged in parallel in the front-rear direction, and a pipe 3 mounted on the upper surface thereof. The radiation plate 2 has an elongated shape that is long in the left-right direction, and the radiation panel 1 is also formed in a rectangular shape that is long in the left-right direction. Each radiation plate 2 has three rows of semicircular downward projections 4 arranged side by side. Therefore, the lower surface of each radiation plate 2 has a concave-convex shape in a side view, and the radiation panel 1 has a concave-convex shape in a side view, and the end surface 1a (see FIG. 3) on the short side of the radiation panel 1 is The concavo-convex end face 1a is formed.

  As shown in FIG. 4, in each radiation plate 2, one long side edge of the front and rear long side edges is a stepped portion 2 a, and the other long side edge side edge is a stepped portion 2 b. By superimposing the adjacent raised portions 2a and the lowered portions 2b, the radiating panel 1 has an appearance like a single plate as a whole.

  On the other hand, the pipe 3 is bent zigzag in a plan view, and the straight portion of the pipe 3 is fitted to the downward protrusion 4 at the center of each radiation plate 2. An upward rib 5 for holding the pipe 3 is formed on the downward protrusion 4 at the center of each radiation plate 2. Accordingly, the pipe 3 is fitted into the downward projection 4 by forcibly deforming the upward rib 5 (forced fitting).

  A portion of the pipe 3 bent in a U shape is exposed on the downward protrusion 4. Moreover, the one end part 3a and the other end part 3b of the pipe 3 are bent so as to extend in parallel with one short side part of the radiation plate 2, as shown in FIG. 3, and the one end part 3a and the other end part 3b are It faces in the opposite direction. Then, one end 3a of the pipe 3 in one radiating panel 1 adjacent to the front and rear, and the other end 3b of the pipe 3 in the other radiating panel 1 are connected to each other by a joint pipe 6 indicated by a dotted line in FIGS. Connected with.

  The pipe 3 is overlapped with a longitudinally pressing frame 7 from above. The holding frame 7 has a U-shaped configuration that opens downward (see FIG. 2), and a plurality of slit engagement grooves 8 are formed on the front and rear side plates, while the front and rear longitudinal side edges of the radiation plate 2 are An engaging rib 9 that fits into the slit engaging groove 8 is formed integrally, and a claw formed on the tip edge of the engaging rib 9 is engaged with the step portion of the slit engaging groove 8, thereby holding the holding frame. 7 holds the pipe 3 against the radiation plate 2 and connects the six radiation plates 2 in a single plate shape.

  The portion of the holding frame 7 that contacts the pipe 3 is cut out in a trapezoidal shape with a downward opening. Three holding frames 7 are arranged at the left and right end portions and the left and right intermediate portions of the radiating panel 1, and nuts 10 are welded to the lower surfaces of the top and bottom end portions of the top plate in the holding frame 7 located at the intermediate portion. It is fixed by. The number of holding frames 7 can be set arbitrarily.

  Then, as shown in FIG. 2, the intermediate support frame 13 is suspended by the first suspension bolts 12 suspended from the ceiling slab 11, and the holding frame 7 is suspended by the second suspension bolts 14 fixed to the intermediate support frame 13. Has been. Therefore, the second suspension bolt 14 is screwed into the nut 10 fixed to the holding frame 7, and is fixed from above with another nut 15.

  The radiation plate 2 employs an extruded product made of a metal such as aluminum or a resin, but is an injection molded product, a metal die-cast product, a metal sintered product, or a sheet metal processed product made of a resin. Various materials and forms can be used. The radiating panel 1 can be constituted by a single radiating plate 2, and when it is constituted by a plurality of radiating plates 2, the number of the radiating panels 1 can be arbitrarily assumed. The pipe 3 is the same, and a laminated product of metal and resin can be adopted in addition to a single layer product of metal or resin. Adopting a three-layer structure product in which the metal layer is sandwiched between the inside and the outside by the resin layer is preferable because of excellent corrosion resistance and anti-condensation effects.

(2). Suspension support structure A radiating panel row is constituted by a large number of radiating panels 1 arranged in the front and rear, and a plurality of rows of radiating panel rows are arranged side by side, but FIG. 5 and FIG. 6 (A) (B ), There is a space (space) between the radiating panel rows adjacent to the left and right, and a hanging tool (T bar) 17 is disposed at this position. Moreover, the hanger 17 is also arrange | positioned also outside the radiation panel 1 located in the right end of right and left.

  As clearly shown in FIG. 6, the hanger 17 has a vertical portion 18 and left and right horizontal flanges 19 integrally connected to the lower end thereof, and the edge of the radiation panel 1 is supported from below by the horizontal flange 19. Has been. Accordingly, the horizontal flange 19 has a function of suspending the radiating panel 1 and a function of a joint for closing the gap between the radiating panels 1. The hanger 17 employs an extruded product made of a metal such as aluminum or a synthetic resin, but a sheet metal product or the like can also be employed.

  A thick portion 20 is formed at the upper end of the vertical portion 18 of the hanger 17, and the thick portion 20 is held by a holding portion 22 formed at the lower end of a longitudinally extending intermediate suspension plate 21. 21 is suspended from the intermediate support frame 13 by the third suspension bolt 23 and the nut 10. It is also possible to directly suspend the lifting tool 17 by the intermediate support frame 13 without using the intermediate suspension plate 21. Further, it is possible to suspend the holding frame 7 and the hanging tool 17 with the first hanging bolt 12 without using the intermediate support frame 13 (in these cases, a horizontal piece is attached to the upper end of the hanging tool 17. It is necessary to provide suspension bolt fixing parts such as).

  A first gap 24 having a certain distance (for example, several mm to several tens of mm) is provided between the uneven end face 1 a of the radiation plate 2 and the vertical portion 18 of the hanger 17. Moreover, since the lower surface of the radiation plate 2 is uneven when viewed from the side, only the lower end of the downward projection 4 is placed on the horizontal flange 19 of the hanger 17, and accordingly, the suspension plate is suspended from the short side portion of the radiation plate 2. A large number of second gaps 25 are formed between the horizontal flange 19 of the tool 17 and separated by the downward projecting ridges 4 arranged in the front-rear direction, and the first gap 24 and the second gap 25 communicate with each other. ing. The first gap 24 and the second gap 25 form a ventilation space for ventilation. The construction error is absorbed by the presence of the first gap 24.

  As shown in FIG. 2, the trunk edge 11a is arrange | positioned beside the radiation panel 1 located in the wall, and the horizontal flange 19 of the one side in the hanger 17 has contacted the trunk edge 11a from the downward | lower direction. The hanger 17 can also be formed in an L shape with only one horizontal flange 19.

  A space behind the ceiling above the ceiling portion formed of the radiating panel 1 is a ventilation buffer space 26 that communicates only with the ventilation spaces (24, 25). As shown in FIG. 2, in this embodiment, the ventilation space (24, 25) in the ceiling portion is used as an exhaust port, and the suction duct 28 of the exhaust device 27 is opened in the ventilation buffer space 26. . An air supply unit 29 is disposed in the room, and the air supply unit 29 and the air supply device 30 are connected by an air supply duct 31.

  The air supply duct 31 passes through the ventilation buffer space 26, but may be configured not to pass through the ventilation buffer space 26 by penetrating a wall or the like. In addition, the exhaust device 27 or the air supply device 30 can be disposed in the ventilation buffer space 26.

(3). Summary of the first embodiment In this embodiment, since the space at the position of the hanger 17 is used as an exhaust port, a dedicated exhaust duct or the like opened in the room is not necessary. The part can be refreshed and can contribute to cost reduction. Moreover, since the location of each suspension tool 17 becomes an exhaust port, the exhaust port is formed over the wide range of the ceiling part, As a result, the whole room can be ventilated evenly.

  Further, since the second gap 25 that constitutes the exhaust port is opened sideways, the indoor air flows in the horizontal direction along the lower surface of the radiating panel 1 as indicated by an arrow in FIG. Tend to be sucked into the second gap 25. That is, indoor air is sucked into the second gap 25 after flowing so as to lick the lower surface of the radiating panel 1.

  Therefore, the air below the radiation panel 1 is agitated, and the film heat transfer coefficient can be increased. That is, if there is a stagnation of air below the radiating panel 1, the heat transfer performance may be reduced due to the presence of the boundary film, and as a result, the air conditioning efficiency may decrease. As a result of the destruction, the heat transfer coefficient of the air below the radiant panel 1 is increased, thereby improving the air conditioning efficiency. The same applies to the case where the ventilation space is used as an air supply port (discharge port).

(4). Other Embodiments Next, other embodiments shown in FIGS. 7 and 8 will be described. In the second embodiment shown in FIG. 7A, a filter 32 made of a breathable material such as a nonwoven fabric is interposed in the first gap 24. In this case, when the ventilation space is used as the air supply port, dust existing in the ceiling back space can be prevented from scattering into the room. Moreover, it is possible to prevent wind noise. If the filter 32 is replaced with a shielding member, the ventilation space can be eliminated. Therefore, the opening area of the ventilation space in the ceiling can be easily adjusted.

  In the third embodiment shown in FIG. 7B, a hollow portion 33 is formed in the vertical portion 18 of the hanger 17, and air is ejected laterally from the hollow portion 33. For this reason, the side plate of the hollow portion 33 has an air supply hole 34 opened in the second gap 25. The uneven end face 1 a of the radiation plate 2 is in contact with or in close contact with the vertical portion 18 of the hanger 17. In this embodiment, since the straightness of air is high, the function of flowing air along the lower surface of the radiation plate 2 is high.

  FIG. 8 shows an embodiment in which the radiating plate 2 of the radiating panel 1 is formed as a flat plate and the pipe holding portion 35 is formed integrally therewith. Among these, in the fourth embodiment shown in (A) and (B), a large number of block-like spacers 36 are arranged at appropriate intervals between the radiation plate 2 and the horizontal flange 19 of the hanger 17. The spacer 36 is fixed by adhesion or the like so as not to drop off.

  In the fourth embodiment shown in (A) and (B), the spacer 36 is formed in a square block shape, but in the fifth embodiment shown in (C), the spacer 36 is formed in a waveform in a side view. Yes. Of course, the spacer 36 may have other forms. Furthermore, the spacer 36 can be formed integrally with the hanger 17.

  In 6th Embodiment shown to FIG. 9 (A), many LED chips 37 are arrange | positioned in the groove part of the lower surface of the radiation panel 1 as an illuminating device. With this configuration, since it is not necessary to provide a large space for providing a lighting device between adjacent radiating panels 1, a ventilation space is formed on the side of the radiating panel 1. The feeling can be further improved.

  In the seventh embodiment shown in FIG. 9A, an organic EL plate 38 is disposed on the lower surface of the hanger 17 as an example of a lighting device, and is configured as a surface-emitting illumination. Also in this example, the refreshing feeling of the ceiling part can be further improved. It is also possible to have the LED chip 37 and the organic EL plate 38 together.

  In the eighth embodiment shown in FIG. 10, exhaust and air supply are performed at the ceiling. That is, in the ceiling portion having a group of six rows of radiating panels 1, the portion between the second and third radiating panel rows from the left and right ends is set as the wide spacing portion 39 for air supply and illumination, An appropriate number of square or circular air supply ports 40 are arranged in the front-rear direction in the wide space portion 39, and a lamp (not shown) is arranged between the air supply ports 40. While the air supply duct 41 is connected, the portion where the radiating panel 1 is suspended by the lifting tool 17 forms an exhaust port. Also in this embodiment, the entire ceiling space is a ventilation buffer space 26 for exhaust.

  In this embodiment, outside air blows down from the air supply port 40, then changes direction in the room and is exhausted from the position of the hanger 17. Therefore, an air flow like convection is formed in the room. In addition, while the area of the air supply port 40 is small, the total sum of the ventilation space at the position of the suspension 17 is large, so the flow rate of air blown down from the air supply port 40 is much higher than the flow rate of air discharged from the ventilation space. It is getting bigger. Therefore, the air blown down from the air supply port 40 is not sucked into the ventilation space near the air supply port 40 and spreads widely in the room.

  In this embodiment, the branched exhaust duct 42 extends to the ventilation buffer space 26, and exhaust is sucked at a plurality of locations in the ventilation buffer space 26. If there is a certain area, it can be said that it is preferable to open the tip of the exhaust duct 42 at a plurality of locations in the ventilation buffer space 26 in this way. It is also possible to make only one exhaust duct 42 and open it at the center of the ventilation buffer space 26.

  In the embodiment of FIG. 10, the entire ceiling space is configured as an exhaust buffer space 26. However, the ceiling space is divided into an intake buffer space and an exhaust buffer space, and intake and exhaust air are separated. It is also possible to perform from the ceiling. In this case, the intake air is ejected from the ventilation space at the position of the hanger 17. Naturally, the boundary between the intake buffer space and the exhaust buffer space is partitioned by a seal member.

  In forming the ventilation space at the position of the hanger 17, it can be said that the total of the ventilation space is preferably set to an appropriate value according to the volume of the room. Therefore, it is necessary to block the end face of the radiating panel 1, but in this respect, as shown in FIG. 11 as the ninth embodiment, by sticking to the end face of the radiating panel 1 with an adhesive tape (or adhesive tape) 43. The ventilation space can be easily closed. Between the end face of the radiating panel 1 and the vertical portion 18 of the hanger 17, an elastic sealing material such as a sponge may be sandwiched.

  Although some embodiments of the present invention have been described above, the present invention can be embodied in various ways. For example, when the lower surface of the radiating panel is formed in a concavo-convex shape, various concavo-convex shapes such as a configuration in which a large number of ribs project downward, a configuration in which square concavo-convex portions are continuous, or a corrugated shape can be employed. The radiation panel 1 may have a square shape in plan view, and the pipe may be formed in a spiral shape in plan view, for example. Furthermore, it is also possible to form a liquid passage (fluid passage) in the radiation plate integrally (built in) without forming the radiation plate and the pipe separately.

  The present invention can be embodied in a radiation panel type air conditioning facility. Therefore, it can be used industrially.

DESCRIPTION OF SYMBOLS 1 Radiation panel 1a Uneven shape end surface 2 Radiation plate 3 Pipe 4 Downward protrusion 7 Holding frame 11 Ceiling slab (ceiling foundation)
12 First suspension bolt 13 Intermediate support frame 14 Second suspension bolt 17 Suspension tool (T bar)
DESCRIPTION OF SYMBOLS 18 Vertical part 19 Horizontal flange 21 Intermediate suspension board 23 3rd suspension bolt 24 1st clearance gap which comprises ventilation space 25 2nd clearance gap which comprises ventilation space 26 Ventilation buffer space 27 Exhaust device 28 Suction duct 29 Air supply port unit 30 Air supply device 31 Air supply duct

Claims (5)

The ceiling part is provided in the suspension as a structure having a radiation panel group in which radiation panels having a square shape in plan view are arranged vertically and horizontally and a suspension that supports the side edge of the adjacent radiation panel. The side edges of the radiating panel are supported from below by horizontal flanges,
And, a ventilation space for indoor ventilation is formed between the radiating panel and the hanging tool,
Air conditioning equipment. The entire back space above the ceiling is formed as a ventilation buffer space communicating with the ventilation space, and an air supply duct or a discharge duct for ventilation is opened in the buffer space.
The air conditioning equipment according to claim 1. While the hanger has a vertical part rising upward from the horizontal flange,
Each of the radiating panels has a concavo-convex surface so that two parallel end faces are concavo-convex end faces, and a large number of radiating panels are arranged so that the concavo-convex end faces face the vertical part of the suspension. The ventilation space is formed by using the uneven shape of the lower surface of the radiating panel by providing a gap between the uneven shape end surface of the radiating panel and the vertical part of the hanging tool.
The air conditioning equipment according to claim 1 or 2. While the hanger has a vertical part rising upward from the horizontal flange,
The lower surface of the radiating panel is a flat surface, and a space is provided between the end surface of the radiating panel and the vertical portion of the hanger, and a spacer is interposed between the lower surface of the radiating panel and the vertical portion of the hanger. By forming the ventilation space,
The air conditioning equipment according to claim 1 or 2.   The building provided with the air-conditioning equipment in any one of Claims 1-4.

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