JP7032778B2 - The ceiling of the building, the hangings used for it, and the air conditioning equipment for the ceiling - Google Patents

Description

The present invention relates to a ceiling portion having a structure in which a ceiling material is suspended by a hanging tool, a hanging tool used for the ceiling portion, and an air conditioning facility for a ceiling portion having a structure in which a radiating panel is suspended and supported by the hanging tool.

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. It is widely used because it has advantages such as excellent comfort.

There are various forms of the radiation panel. For example, as disclosed in Patent Document 1, there is a type in which the lower surface is formed into an uneven shape in which peaks and grooves (valleys) are alternately arranged. Since the radiant panel has a large heat transfer area as compared with a flat structure, it has an advantage that the air conditioning efficiency can be improved.

In addition, this type of radiant panel is formed in a rectangular shape in a plan view, and many of them are laid out vertically and horizontally. The long sides are in contact with each other, and the short sides are arranged so that there is a gap between the short sides, and the short sides are supported by a hanging tool called a T-bar. In the construction of the ceiling part, the support structure using the T-bar is widely used in the top of the light sky structure, and the support structure of the radial panel follows the structure of the general ceiling part.

When the ceiling portion is configured by using the T-bar, one problem is that when a person looks up at the ceiling surface, he / she may feel a sense of discomfort due to the difference in the material between the ceiling material and the T-bar. Regarding this point, Patent Document 2 discloses that the ceiling material and the T-bar are spatter-coated to make the appearance of both common.

Further, in Patent Document 3, in order to prevent a shadow from being formed in the gap between the flange of the T-bar and the ceiling material, the flange of the T-bar is covered with a transparent cover member from below, and both lengths of the cover member are covered. It is disclosed that an upward piece facing the lower surface of the ceiling material is projected from the edge portion and a transparent upward piece (transparent portion) is used to close the gap to prevent the generation of shadows.

Japanese Unexamined Patent Publication No. 2008-275227 Japanese Unexamined Patent Publication No. 10-68191 Japanese Unexamined Patent Publication No. 2006-282005

FIG. 8 shows a structure in which a radiation panel 1 ′ whose lower surface is formed unevenly as in Patent Document 1 is supported by a T bar 12 ′. In this structure, in the radial panel 1', the lower end of the downward ridge 4'is supported by the flange 13'of the T-bar 12', so that the downward groove 20' is directed toward the vertical portion 14'of the T-bar 12'. Although it is intruded, the lighting in the room does not reach the end of each downward groove 20'in the radiating panel, so the end of each downward groove 20'is a shadow S as shown by a dot in (B). Therefore, when a person looks up at the ceiling , shadows S appear in dots along the longitudinal direction of the T-bar 12', and there is a concern that the person may feel uncomfortable.

Patent Document 3 also has a problem that a shadow is formed between the flange of the T bar and the ceiling material. Therefore, it is conceivable to eliminate the shadow S generated in FIG. 8 by the means of Patent Document 3, but the radiation panel 1 Since the vertical depth of the'downward groove 20'is quite large, it is difficult to say that shadows can be prevented by blocking the downward groove 20 with the upward piece of the transparent cover member. There is concern that the downward groove 20'looks like a dark tunnel through the.

The present invention has been made in the wake of such a situation, and is intended to realize a structure of a ceiling portion that does not give a sense of discomfort even when a person looks up.

The invention of the present application includes various configurations, and a typical example thereof is specified in each claim. Of these, the invention of claim 1 is applied to the ceiling of a building.
"It has a ceiling material with a rectangular shape in a plan view and a hanging tool that extends long along one side edge of the ceiling material.
The lower surface of the ceiling material has an uneven shape when viewed from the horizontal direction orthogonal to the longitudinal direction of the hanging tool. Therefore, the lower surface of the ceiling material has a concave-convex shape in the direction orthogonal to the longitudinal direction of the hanging tool. While a large number of downward grooves extending over the entire length are formed in parallel,
The hanger has a horizontal flange on which one side edge of the ceiling material rests, and a vertical portion rising from the flange, and the ends of a large number of downward grooves in the ceiling material are the flanges. Located on "
In the configuration
" A light emitting element that horizontally irradiates light from the space above the flange toward each downward groove of the ceiling material is arranged in the vertical portion or the flange of the hanging tool."
It has the configuration.

The invention of claim 2 is applied to a hanging tool for a ceiling material. That is,
" A ceiling material having a rectangular shape in a plan view and a lower surface having a concavo-convex surface in which a group of linear downward grooves are arranged side by side is suspended at a position on one side edge where the end of each downward groove is located. "
It ’s about hanging tools,
" It has a flange on which one side edge of the ceiling material is placed and a vertical portion rising from the flange, and the ceiling material is supported on the vertical portion or the flange from the space above the flange. A light emitting element that horizontally irradiates light toward each downward groove of the ceiling material is arranged. "
It is configured as.

The invention of claim 3 relates to an air conditioner for a ceiling portion. This ceiling air conditioner
"It is equipped with a rectangular radial panel as a ceiling material and a hanging tool that extends long along one side edge of the radial panel.
The radiating panel has a radiating plate in which downward ridges and downward grooves are alternately present on the lower surface, and a fluid passage provided in the radiating plate . While extending over the entire length in the direction orthogonal to the longitudinal direction of the hanger ,
The hanger has a flange on which one side edge of the radiation panel rests, and a vertical portion that rises from the flange , with the ends of a number of downward grooves in the ceiling material located above the flange. I'm doing it . "
In the basic configuration
" A light emitting element that horizontally irradiates light from the space above the flange toward each downward groove of the radiation panel is arranged in the vertical portion or the flange of the hanging tool."
The configuration is added.

In the inventions of claims 4 to 6 , the light emitting element is an LED or an organic EL, and is provided on the side surface of the vertical portion of the hanger or the upper surface of the flange . In claims 7 and 8, the light emitting element is provided at a position corresponding to each downward groove of the ceiling material .

In the present invention, since the downward groove is illuminated by the light of the light emitting element, even if a shadow is generated in the downward groove, it is difficult to confirm (visually recognize) it, or the shadow in the downward groove is formed. Can be prevented or suppressed from occurring in.

Therefore, it is possible to prevent shadows from getting into the eyes when a person looks up at the ceiling and to have a sense of discomfort, and to improve the aesthetic appearance. Further, in the present invention, since the light emitting element can also play the role of indoor lighting, it can also contribute to the adjustment of indoor brightness.

If the light of the light emitting element is too strong, the light of the light emitting element may cause a sense of discomfort. However, by setting the light of the light emitting element to an illuminance that is inconspicuous under the main lighting in the room. , You can create a comfortable state. The illuminance of the light emitting element may be adjustable.

In the present invention, since the light is emitted from the space above the flange, the downward groove is illuminated from the back, and the generation of shadows can be reliably prevented . Further, since the light of the light emitting element does not directly hit the human eye and becomes indirect lighting, it can be said that it is particularly suitable as an auxiliary for indoor lighting. For example, when the illuminance in the room is reduced due to the use of a projector, the illuminance in the room can be evenly reduced by turning on only the light emitting element of the present invention.

If a light emitting element is provided corresponding to each downward groove as in claims 7 and 8, the certainty of preventing the generation of shadows can be significantly improved. In addition, the indirect lighting function can be improved.

In the present invention, the ceiling material may be a simple ceiling plate, but when applied to an air-conditioning facility for a ceiling portion as in claim 3, a radiant panel having an uneven lower surface is used to improve the air-conditioning efficiency and improve the aesthetic appearance. It can be improved and is suitable. The group of light emitting elements may be configured to be turned ON / OFF as a whole, or may be turned ON / OFF for each location of the ceiling material.

It is a perspective view of the interior of the building which concerns on embodiment. (A) is a plan view of the radiation panel, and (B) is a view of BB of (A). It is a partial plan view of the ceiling part of 1st Embodiment. (A) is an enlarged plan view of a main part of the ceiling portion, (B) is a sectional view taken along the line BB of FIG. 3, and (C) is a sectional view taken along the line CC of FIG. (A) is a separated perspective view seen from above, and (B) is a perspective view seen from below. (A) is a perspective view of the first reference example , (B) is a bottom view of the second reference example , (C) is a side view of the third reference example , and (D) is a side view of the fourth reference example . (A) is a vertical sectional side view of the second embodiment, (B) is a vertical sectional side view of the third embodiment, (C) is a side view of the fifth reference example , and (D) is a side view of the fourth embodiment. be. In the perspective view which shows the conventional structure, (A) shows the T bar by the alternate long and short dash line, and (B) shows the T bar by a solid line.

(1). First Embodiment Next, an embodiment (and a reference example) of the present invention will be described with reference to the drawings. This embodiment is applied to a ceiling air conditioner having a radiating panel. That is, a radiant panel is used as a ceiling material. First, the first embodiment shown in FIGS. 1 to 5 will be described.

Figures 1 and 2 show the outline of the building and the air conditioning equipment. As shown in these figures, the ceiling of the room has a large number of radiant panels 1 arranged side by side (vertically and horizontally). I have. The structure of the radiation panel 1 is the same as the conventional one, but it will be described just in case.

As is clearly shown in FIG. 2, the radiating panel 1 has a rectangular shape in a plan view, and a large number of the radiating panels 1 are arranged side by side in a state where the long sides are in contact with each other to form a radiating panel row. There is a certain amount of space (gap, space) between the rows of radiating panels adjacent to each other. In FIG. 2, a slight gap is drawn between the long sides of the adjacent radiation panels 1 in the front-rear direction, but in reality, the long sides of the adjacent radiation panels 1 are in contact with each other.

In the present embodiment, as described above, the front-back and left-right words are used to specify the direction, but the direction along the short side of the radiation panel 1 is the front-back direction, and the direction is left and right along the long side of the radiation panel 1. Defined as directions (these directions are for convenience of explanation). The front view is a state viewed from the front-rear direction, and the side view is a state viewed from the left-right direction. To be on the safe side, the directions are specified in Figures 1 and 2.

As shown in FIGS. 2 and 3, the radiation panel 1 is composed of six radiation plates 2 arranged in parallel in the front-rear direction and a pipe 3 mounted on the upper surface thereof. Therefore, in the present embodiment, the fluid passage is formed by the pipe 3.

The radiating plate 2 has a long and narrow shape extending left and right, and the radiating panel 1 is also formed in a rectangular shape extending left and right as described above. On each radiation plate 2, semicircular downward ridges 4 are formed in three rows side by side. Therefore, the lower surface of each radiation plate 2 has an uneven shape in the side view in which the downward protrusions 4 and the downward groove 20 in the left-right longitudinal direction are arranged alternately in the front-rear direction , and the radiation panel 1 also has an uneven shape in the side view. It has a shape.

As shown in FIG. 4C, in each radiation plate 2, one of the front and rear longitudinal side edges has a step-up portion 2a, and the other longitudinal side edge has a step-down portion 2b. By superimposing the step-up portion 2a and the step-down portion 2b that are adjacent to each other in the front-rear direction, the radiation panel 1 has an appearance like a single plate as a whole.

On the other hand, as shown in FIG. 2, the pipe 3 is bent in a zigzag manner in a plan view, and the straight portion of the pipe 3 is fitted into the downward ridge 4 in the central portion of each radiation plate 2. The downward ridge 4 at the center of each radiation plate 2 is formed with an upward rib 5 that holds the pipe 3. Therefore, the pipe 3 elastically deforms the upward rib 5 and is fitted into the downward ridge 4 (forced fitting).

The U-shaped portion of the pipe 3 is exposed above the downward ridge 4. Further, as shown in FIG. 2, one end 3a and the other end 3b of the pipe 3 are bent so as to extend in parallel with one short side of the radiation plate 2, and the one end 3a and the other end 3b are different from each other. It faces in the opposite direction. Then, one end 3a of the pipe 3 in one of the radiation panels 1 adjacent to the front and back and the other end 3b of the pipe 3 in the other radiation panel 1 are connected by a joint pipe 6 shown by a dotted line in FIG. ing.

The front and rear longitudinal holding frames 7 are overlapped with the pipe 3 from above. The holding frame 7 has a U-shaped shape that opens downward (see FIG. 2), and a plurality of open engagement grooves 8 are formed in the front and rear side plates thereof in a scattered manner, while the front and rear longitudinal side edges of the radiation plate 2 are formed. The engaging rib 9 that fits into the cut-open engagement groove 8 is integrally formed, and the claw formed on the tip edge of the engagement rib 9 is engaged with the step portion of the cut-open engagement groove 8 to engage the holding frame. The pipe 3 is pressed and held by the radiation plate 2 by 7, and six radiation plates 2 are connected in a single plate shape.

As shown in FIG. 4C, the portion of the holding frame 7 that corresponds to the pipe 3 is notched in a trapezoidal shape with a downward opening. Three holding frames 7 are arranged at the left and right ends near the left and right ends of the radiation panel 1 and at the left and right middle parts, and nuts 10 are welded to the lower surface of the front and rear ends near the top plate of the holding frame 7 located at the middle part. It is fixed by. The number of pressing frames 7 can be arbitrarily set. Although not shown, the holding frame 7 is suspended and supported by screwing a hanging bolt (not shown) hanging directly from the ceiling slab (not shown) or via an intermediate member into the nut 10. ing.

The radiation plate 2 uses an extruded product made of a metal such as aluminum or a resin, but an injection molded product made of a resin, a metal die-cast product, a metal sintered product, or a sheet metal processed product. Various materials and modes can be used. It is also possible to configure the radiation panel 1 with one radiation plate 2.

(2). Suspension tool A radiation panel row is composed of a large number of radiation panels 1 arranged in front and behind, and a plurality of rows of radiation panel rows are arranged side by side. For example, it is shown in FIGS. 4 (A) and 4 (B). As described above, there is a space between the rows of radiating panels adjacent to the left and right, and the hanger (T bar) 12 is arranged at this location. The hanger 12 is also arranged on the outside of the radiation panel 1 located at the left and right right ends.

As is clearly shown in FIG. 4B, the hanger 12 has a horizontal left and right flange 13 and a vertical portion 14 integrally rising from a portion of the longitudinal center line thereof, and the flange 13 radiates a panel. One side edge (short end) of 1 is supported from below. Therefore, the flange 13 has a function of suspending and supporting the radiating panel 1 and a function of a joint for closing the gap between the short ends of the adjacent radiating panels 1. As the hanger 12, an extruded product made of a metal such as aluminum or a synthetic resin is used, but a sheet metal processed product or the like can also be used.

A thick portion 15 is formed at the upper end of the vertical portion 14 of the hanger 12, and the thick portion 15 is held by the holding portion 17 formed at the lower end of the intermediate suspension plate 16 formed in the front-rear and longitudinal directions, and the intermediate suspension plate is held. 16 is suspended and supported by a hanging bolt 18 and a nut 19.

There is a gap (for example, several mm to ten and several mm) between one side edge (short side edge) of the radiation panel 1 and the vertical portion 14 of the hanger 12. Further, since the lower surface of the radiation plate 2 is uneven in a side view, only the lower end of the downward ridge 4 rests on the flange 13 of the suspension tool 12, and therefore, the short side portion of the radiation plate 2 and the suspension tool 2 are placed. A large number of downward groove strips 20 sandwiched between the downward protrusions 4 arranged in the front-rear direction are formed between the flange 13 and the flange 13. The downward groove 20 has a flat surface on the upper surface and curved inclined surfaces on both front and rear sides, and has a shape close to a trapezoid.

Therefore, as shown in FIGS. 4 and 5, the LEDs 22 are arranged on both front and rear surfaces of the vertical portion 14 of the hanger 12 via the circuit board 21. The circuit board 21 is adhered to the vertical portion 14 with an adhesive or double-sided adhesive tape, but may be fixed by other means such as screwing. A large number of LEDs 22 are mounted on the circuit board 21 in a scattered manner so as to be located at each downward groove 20 of the radiation panel 1, and the light irradiation direction faces the downward groove 20.

Therefore, as schematically shown in FIG. 5B, each downward groove 20 of the radiation panel 1 is illuminated from the back by the light radiated horizontally from the LED 22. As a result, no shadow is formed on the downward groove 20 due to the indoor lighting, and even if a person looks up at the ceiling, he / she does not feel uncomfortable.

In this embodiment, the LED 22 also functions as indirect lighting for indoor use. Therefore, when it is desired to reduce the illuminance of the entire room, for example, when a projector is used indoors, a desired atmosphere can be created by turning on only the LED 22 of the present invention. Further, since the LED 22 is generally driven by a direct current of 12 volts, it is possible to function as an emergency light in the event of a power failure by preparing a battery as a backup power source. It is also possible to variably configure the illuminance of the LED 22.

The illuminance of the LED 22 is set so that people do not feel uncomfortable, but even if a person looks up at the ceiling, the light of the LED 22 does not come into direct contact with the eyes. Even if the illuminance is secured, people do not feel uncomfortable.

The LED 22 can be directly attached to the vertical portion 14 of the hanger 12, but if the circuit board 21 is used as in the embodiment, the mounting is easy and the LED 22 can be easily applied to the existing hanger 12. There is. When the circuit board 21 is used, those having an appropriate length may be arranged in series.

(3). Reference example in Fig. 6
Next, a reference example shown in FIG. 6 will be described. In the first reference example shown in FIG. 6A and the second reference example shown in FIG. 6B, the LED 22 is arranged on the lower surface of the flange 13 via the circuit board 21. In this case, in the first reference example of (A), the LEDs 22 are arranged in only one row along the longitudinal center line of the flange 13, and in the second reference example of (B), they are moved closer to the left and right longitudinal edges of the flange 13. Two rows are formed. The LED 22 preferably has a light irradiation angle as large as possible (for example, about 180 degrees).

In this reference example , since the group of LEDs 22 forms a band of light protruding outside the lower surface of the flange 13, even if a shadow is generated at the position of the downward groove 20, the shadow is a band of light. It is hidden in the shadow, and even if a person looks up, it cannot recognize the shadow. Therefore, even in this reference example , it is possible to prevent a person from feeling uncomfortable due to shadows.

Further, since a part of the light of the LED 22 goes toward the downward groove 20, it is possible to prevent or suppress the formation of a shadow at the portion of the downward groove 20. In particular, when the LED 22 is arranged close to the longitudinal edge of the flange 13 as in the second reference example of (B), the irradiation light is directed to the downward groove 20 by diffraction, so that it can be said that the function of preventing the generation of shadows is high. ..

In FIGS. 6C and 6D, the LED 22 is arranged on the lower surface portion of the flange 13 in a state where the light is irradiated laterally. Of these, in the third reference example shown in (C), a holder member 24 made of synthetic resin or the like having left and right lateral grooves 23 is fixed to the lower surface of the flange 13 by adhesive or the like, and the LED 22 is attached to the lateral groove 23 of the holder member 24. It is arranged.

On the other hand, in the fourth reference example shown in (D), the lateral groove 23 is integrally formed on the lower surface portion of the flange 13 by utilizing the fact that the hanger 12 is extruded, and the LED 22 is formed in the lateral groove 23. Is placed. In either case, the LED 22 is mounted on the circuit board 21, but the LED 22 may be mounted alone. In these reference examples of (C) and (D), since the light is irradiated laterally, the irradiation of the downward groove 20 can be promoted and the generation of shadows can be prevented more accurately. In addition, the indirect lighting function can be improved.

(4). Embodiment / reference example of FIG.
In the second embodiment shown in FIG. 7A, the upper and lower holder members 24 that hold the circuit board 21 from above and below are integrally formed on the vertical portion 14. This embodiment has the advantages that the circuit board 21 can be easily attached and the front-rear position of the LED 22 can be easily changed.

In the third embodiment shown in FIG. 7B, the lateral lip 25 is integrally provided at a portion of the vertical portion 14 higher than the radiation panel 1, and the LED 22 is provided on the lower surface of the lateral lip 25 via the circuit board 21. It is arranged. The light of the LED 22 is emitted downward and reflected by the vertical portion 14 and the flange 13 toward the downward groove 20. Therefore, the function of preventing shadows is perfect.

In this embodiment, since the LED 22 is arranged at a position higher than the radiation panel 1, even if there is only a slight gap between the radiation panel 1 and the vertical portion 14, it is possible to firmly prevent the generation of shadows. In this case, as shown by the alternate long and short dash line, if the reflective tape 26 is attached to one or both of the side surface of the vertical portion 14 and the upper surface of the flange 13, the reflection / scattering of light is promoted. , The occurrence of shadows can be prevented more accurately.

If the light can be strongly reflected and scattered at the flange 13 by the reflective tape 26 or the like, the LED 22 does not necessarily have to be provided corresponding to each downward groove 20. Therefore, positioning of the LED 22 is not required, which facilitates construction. Also in the first embodiment, if the reflective tape 26 is attached to the upper surface of the flange 13 as in the present embodiment, one LED 22 can illuminate a plurality of downward grooves 20, so that the LED 22 can be accurately positioned. do not have to.

In the fifth reference example shown in FIG. 7 (C) and the fourth embodiment shown in (D), the resin bracket material 27 holding the flange 13 is attached to the hanger 12 so as not to fall off. The LED 22 is attached to the bracket material 27. That is, the bracket material 27 has a cross-section C shape that holds the flange 13 from below, and in the fifth reference example of (C), a laterally overhanging portion 27a is formed at the lower end of the longitudinal side edge of the bracket material 27. The LED 22 is mounted on this. Although the LED 22 is directly mounted on the lateral overhanging portion 27a, it may be mounted via the circuit board 21.

In this fifth reference example , since the light of the LED 22 is emitted upward, the generation of shadows can be reliably prevented. The LED 22 does not necessarily have to correspond to each downward groove 20, and it is also possible to illuminate a plurality of downward grooves 20 with one LED 22 (again, a reflective tape is attached to the upper surface of the lateral overhanging portion 27a or metal. It is beneficial to apply color paint.)

In the fourth embodiment shown in (D), the dovetail-shaped holding portion 27c overlapping the vertical portion 14 is integrally provided on the upper piece 27b of the bracket material 27, and the circuit board 21 is provided on the dovetail groove-shaped holding portion 27c. Is attached. Therefore, as in the first embodiment and the second embodiment of FIG. 7A, the LED 22 is arranged on the side surface portion of the vertical portion 14.

The reference examples and embodiments of (C) and (D) have an advantage that they can be easily applied to the existing hanger 12. In the reference examples and embodiments of (C) and (D), the radiation panel 1 is supported by the flange 13 via the upper piece 27b of the bracket material 27. Therefore, even if the bracket material 27 disappears due to a fire, the radiation panel 1 will not fall.

The invention of the present application can be embodied in various ways in addition to the above embodiments. For example, it is possible to arrange the LED on the upper surface of the flange (in this case, by using the bracket material 27 as shown in FIG. 7C, the position of the LED can be easily adjusted. Is preferable.). Further, although the above embodiment is applied to the air-conditioning equipment for the ceiling portion, it can also be applied to the ceiling portion having no air-conditioning function and the hanging tool (T bar) for the ceiling portion.

As the light emitting element, it is possible to use an organic EL such as a sheet, or it is also possible to use an LED and an organic EL in combination. When an organic EL is used, for example, it can be attached to the side surface of a vertical portion to cause surface emission, so that it is excellent in the certainty of preventing shadows and also in the workability.

In the embodiment, the fluid passage of the radiation panel is composed of a pipe, but it is also possible to integrally form the fluid passage with the plate. Further, the target ceiling material may have at least a concave-convex shape on the lower surface, and even if the upper surface is flat, it is the subject of the present invention.

The invention of the present application can be embodied in an air conditioner for a ceiling or the like. Therefore, it can be used industrially.

1 Radiant panel that constitutes the ceiling material 2 Radiant plate 3 Pipe that constitutes the fluid passage 4 Downward protrusion 12 Suspension tool (T bar)
13 Horizontal flange 14 Vertical part 20 Downward groove of radiant panel 21 Circuit board 22 LED

Claims (8)

It has a ceiling material with a rectangular shape in a plan view and a hanging tool that extends long along one side edge of the ceiling material.
The lower surface of the ceiling material has an uneven shape when viewed from the horizontal direction orthogonal to the longitudinal direction of the hanging tool. Therefore, the lower surface of the ceiling material has a concave-convex shape in the direction orthogonal to the longitudinal direction of the hanging tool. While a large number of downward grooves extending over the entire length are formed in parallel,
The hanger has a horizontal flange on which one side edge of the ceiling material rests, and a vertical portion rising from the flange, and the ends of a large number of downward grooves in the ceiling material are the flanges. It is a configuration located on the top ,
A ceiling portion of a building in which a light emitting element that horizontally irradiates light from a space above the flange toward each downward groove of the ceiling material is arranged in a vertical portion or a flange of the hanging tool. Suspension of a ceiling material that is rectangular in plan view and whose lower surface is an uneven surface in which a group of linear downward grooves are arranged side by side, at a position on one side edge where the end of each downward groove is located. It ’s an ingredient,
It has a flange on which one side edge of the ceiling material is placed, and a vertical portion rising from the flange, and the ceiling material is supported on the vertical portion or the flange from the space above the flange. A light emitting element that irradiates light horizontally toward each downward groove of the ceiling material is arranged.
Hanging tool for ceiling materials. It is equipped with a rectangular radial panel as a ceiling material and a hanging tool that extends long along one side edge of the radial panel.
The radiating panel has a radiating plate in which downward ridges and downward grooves are alternately present on the lower surface, and a fluid passage provided in the radiating plate . While extending over the entire length in the direction orthogonal to the longitudinal direction of the hanger ,
The hanger has a flange on which one side edge of the radiation panel rests, and a vertical portion that rises from the flange , with the ends of a number of downward grooves in the ceiling material located above the flange. It is a configuration that is
An air-conditioning facility for a ceiling portion in which a light emitting element that horizontally irradiates light from a space above the flange toward each downward groove of the radiation panel is arranged in a vertical portion or a flange of the hanging tool. The light emitting element is an LED or an organic EL, and is provided on the side surface of a vertical portion of the hanger or the upper surface of a flange.
The ceiling portion according to claim 1. The light emitting element is an LED or an organic EL, and is provided on the side surface of the vertical portion or the upper surface of the flange.
The hanging tool for the ceiling material according to claim 2. The light emitting element is an LED or an organic EL, and is provided on the side surface of a vertical portion of the hanger or the upper surface of a flange.
The ceiling air-conditioning equipment according to claim 3. The light emitting element is provided at a position corresponding to each downward groove of the ceiling material.
The ceiling portion according to claim 1 or 4. The light emitting element is provided at a position corresponding to each downward groove of the ceiling material.
The hanging tool for the ceiling material according to claim 2 or 5.

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