JP2015031060A - Ceiling unit, ceiling structure, and ceiling repair method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To meet a local temperature request while enabling even air conditioning of the whole room.SOLUTION: In a ceiling unit, a porous panel 6, which comprises a large number of air communication holes passing through front and back sides and which can be freely arranged along a ceiling surface C, is provided, and an air supply chamber 7 opened downward is provided in such a manner as to be capable of being freely loaded on a top surface of the porous panel 6. A part of the porous panel 6 is fitted with a fan F for blowing air within the air supply chamber 7 in a downward direction of a ceiling.

Description

  The present invention is provided with a porous panel which has a large number of air circulation holes penetrating the front and back and can be arranged along the ceiling surface, and an air supply chamber which is open at the bottom is provided on the upper surface of the porous panel. The present invention relates to a ceiling unit, a ceiling structure in which the ceiling unit is attached along the ceiling surface, and a ceiling repair method for repairing the ceiling unit. For convenience, these ceiling units, ceiling structures, and ceiling repair methods are referred to as ceiling air conditioning technology.

Conventionally, as one of this type of ceiling air conditioning technology, a slit-like air outlet that opens to the ceiling surface is provided, and an air supply duct from an air conditioner is installed so that air-conditioned air is blown out from the air outlet downward from the ceiling. There is a ceiling structure that is connected to the air outlet in the ceiling space and is configured to perform so-called “convection air conditioning” air conditioning.
According to this ceiling structure, air-conditioned air is blown out from the air outlet directly downward to the ceiling, so there is a problem that draft feeling cannot be denied and unevenness in the air-conditioning effect in the entire room is likely to occur. .
A so-called “radiant air-conditioning system” is an example of an air-conditioning system that solves this problem.
As an example of a ceiling structure that employs this "radiation air conditioning system", a perforated panel that has a large number of air flow holes penetrating the front and back and that can be placed along the ceiling surface is suspended from the ceiling slab at a horizontal interval. There is a structure in which an air supply chamber having a lower opening is placed on a perforated panel provided over a supported support (see, for example, Patent Document 1).
According to this ceiling structure, the air conditioning effect by the thermal radiation from the perforated panel to the lower part of the ceiling and the air conditioning effect by the conditioned air descending at a slow speed through the numerous pores provided in the perforated panel, It becomes possible to suppress the draft feeling and to air-condition in a state with less temperature unevenness.
In addition, one perforated panel has a structure in which one air supply chamber is placed.

Japanese Patent Laying-Open No. 2009-249897 (FIGS. 2 and 4)

  According to the conventional ceiling air conditioning technology described above, it is possible to perform air conditioning with little variation by using heat radiation from the perforated panel, and conversely, it is difficult to control air conditioning in response to local temperature requirements. For example, when there is a heat source (for example, a computer, a copy, another IT device, etc.) in a local area in the room, an increase in temperature is observed in the vicinity of the heat source, and it feels hotter than other parts. Even if there is no heat source, for example, a person who enters the room from a hot outside environment may feel that the effectiveness of air conditioning is low and temporarily require a strong air conditioning effect. Therefore, there is a problem that it is not possible to cope with such a local temperature requirement.

  Accordingly, an object of the present invention is to provide a ceiling air-conditioning technology that can solve the above-mentioned problems and can uniformly air-condition the entire room, but can also cope with local temperature requirements.

  A first characteristic configuration of the present invention includes a multi-hole panel that is provided with a large number of air circulation holes penetrating on the front and back sides and that can be arranged along the ceiling surface, and an air supply chamber that opens downward is provided on the top surface of the multi-hole panel. The ceiling unit is provided so as to be freely mounted, and a fan for blowing the air in the air supply chamber toward the lower part of the ceiling is attached to a part of the perforated panel.

According to the first characteristic configuration of the present invention, in addition to the radiant air-conditioning through the perforated panel and the air-conditioning effect for a wide range of the room due to the conditioned air oozing out from a large number of air circulation holes, Personal air conditioning for indoor areas can be realized.
Therefore, the entire room can be air-conditioned evenly, and local temperature requirements can be met.
In addition, as equipment, even if it is not equipped with large-scale equipment, it can be configured as a simple source by providing a fan on a part of the perforated panel and placing an air supply chamber on them. As described above, it is possible to economically implement advanced air conditioning with fine texture.

  According to a second characteristic configuration of the present invention, there is provided a fan arrangement changing means capable of changing a planar arrangement of the fan in the air supply chamber.

According to the second characteristic configuration of the present invention, since the fan arrangement changing means is provided, the plane arrangement of the fans in the air supply chamber can be changed, and the fan arrangement can be changed arbitrarily according to needs. become able to.
Therefore, for example, the fan arrangement is changed according to the position where a person sits, the position where the heat source is installed, and the like, and personal air conditioning for that portion can be easily performed.

Incidentally, as a specific example of the fan arrangement changing means, the following configuration example can be given.
For example, by changing the arrangement of the perforated panel to which the fan is attached to the air supply chamber (for example, changing the installation direction or changing the installation position), the fan can be automatically changed to the air supply chamber. Example configuration.
For example, a configuration example in which the mounting position of the fan with respect to the perforated panel can be changed.
For example, a configuration example in which a plurality of divided perforated panels are provided so that the plane position can be freely changed, and the position of the fan relative to the supply chamber is changed by changing the plane position of the divided perforated panel with a fan among them. .

  According to a third characteristic configuration of the present invention, the fan arrangement changing unit includes a plurality of divided porous panels in which the porous panel is divided and formed in a state in which a planar arrangement can be changed. There is a fan installed.

According to the third characteristic configuration of the present invention, as the fan arrangement changing means, the fan is attached to a part of the divided porous panel divided into a plurality of parts so that the plane arrangement can be freely changed. Then, the plane arrangement of the fans in the air supply chamber can be easily changed by simply changing the arrangement with the fanless divided perforated panel.
Moreover, by dividing the perforated panel into a plurality of parts, each of the divided perforated panels can be made compact and easy to handle, and the work efficiency of installation work and maintenance work can be improved. it can.
And even when clogging or breakage occurs in the local part of the perforated panel, it is not necessary to replace the whole, and it is only necessary to replace the divided perforated panel of the corresponding part, so that the maintenance cost can be reduced. it can.
Also, when replacing or maintaining the fan, the divided porous panel adjacent to the divided porous panel with the fan is shifted to the side and the opening is used as a temporary inspection port, or the divided porous panel with the fan is removed from the ceiling. It is also possible to work by removing the fan, and it is possible to easily perform fan replacement and maintenance work even from the lower side of the ceiling.

  According to a fourth characteristic configuration of the present invention, the perforated panel including the fan is formed to be replaceable with a panel not including the fan.

According to the fourth characteristic configuration of the present invention, it becomes possible to replace the perforated panel provided with the fan with a panel at another position in the ceiling surface, and accordingly, the position of the fan is changed within the ceiling surface. It is possible to change the position to another position.
As a result, even if the area that requires personal air conditioning is changed by, for example, rearranging indoors, the layout of the perforated panel with a fan is changed in accordance with the changed area, and the area is targeted. Personal air conditioning can be implemented easily.
In addition, a panel other than the porous panel with a fan (a panel without a fan) can include a porous panel without a fan, a ceiling panel without a hole, and the like.

  A fifth characteristic configuration of the present invention is a ceiling structure in which the ceiling unit according to any one of claims 1 to 4 is attached along the ceiling surface, and the ceiling slab has a lateral interval. The perforated panel is supported across a support supported by suspension, and an air supply duct from an air conditioner is connected to the air supply chamber.

  According to the fifth characteristic configuration of the present invention, each of the advantages such as radiant air conditioning by the perforated panel, air conditioning by the conditioned air exuding from the perforated panel, and personal air conditioning by the fan, etc., is a simple ceiling structure. It is possible to realize air conditioning that demonstrates both.

  A sixth characteristic configuration of the present invention is a convection air-conditioning ceiling in which a slit-like air outlet opening in the ceiling surface is provided and the air supply duct from the air conditioner is connected to the air outlet. A ceiling repair method for repairing the structure to the ceiling structure according to claim 5, wherein a ceiling plate adjacent to the blowout port is replaced with the porous panel, and a lower portion is opened on an upper surface of the porous panel. The air supply duct is placed and the air supply duct connected to the air outlet is connected to the air supply chamber.

According to the sixth characteristic configuration of the present invention, the support structure that supports the ceiling board adjacent to the air outlet, the air supply duct that is connected to the air outlet, and the like are used. The ceiling unit can be installed, and the ceiling repair work can be carried out economically and efficiently in a short period of time compared with removing all the convection air-conditioning ceiling structures and newly installing them.
Therefore, it is possible to quickly and economically switch the convection air-conditioning ceiling structure to an air-conditioning ceiling structure that can uniformly air-condition the entire room and meet local temperature requirements while minimizing complicated work. it can.

Sectional view showing the ceiling structure after renovation Plan view showing the ceiling structure after renovation Sectional view showing the edge of the ceiling unit The top view which shows the perforated panel of another embodiment Sectional view showing the ceiling structure before renovation

  Embodiments of the present invention will be described below with reference to the drawings.

FIG. 1 is an explanatory diagram showing a ceiling structure that has been repaired using the ceiling air conditioning technology of the present invention.
Incidentally, the ceiling structure before renovation is as shown in FIG.

  In the ceiling structure before refurbishment, a long support metal (an example of a support) 1 is arranged in parallel on the ceiling surface C with a lateral interval. By this support metal 1, the lighting fixture 2 and the ceiling board are arranged. (Equivalent to the panel) 3, slit-shaped air-conditioning outlet (hereinafter simply referred to as outlet) 4, sprinkler head, fire detector, ceiling-mounted speaker, emergency lighting, etc. not shown in the figure ing.

  The support hardware 1 is composed of a long metal (so-called “T-bar”) whose cross-sectional shape is, for example, an inverted “T” shape, and is suspended from a ceiling slab (not shown) through a suspension rod or another member. Suspended and supported. In addition, each supported object is mounted (or fixed) on the lower edge flange portion 1a located at the lower edge portion of the inverted T-shaped cross section, thereby supporting each.

  The luminaire 2 is composed of, for example, a fluorescent lamp, an LED, and the like, and is disposed between a pair of adjacent support metal fittings 1 arranged in parallel with a space therebetween, and both side portions are respectively connected to the lower edge flanges. It is provided in a state of being placed on the part 1a.

  The ceiling board 3 is composed of, for example, a rectangular rock wool sound absorbing board or the like, and is provided in a state in which the side edge portion is placed on each lower edge flange portion 1 a of the pair of support hardware 1. .

The blower outlet 4 is comprised by the cylinder member connected in communication with the air supply duct 5 from the air conditioner K. As shown in FIG. The outlet opening of the cylindrical member is formed in a flat shape, and the blowout port 4 is housed in a gap between the pair of support hardware 1 so that the flat longitudinal direction is along the longitudinal direction of the support hardware 1. .
Therefore, the conditioned air from the air conditioner K is directly blown out from the air outlet 4 in the gap between the support hardware 1 to the lower part of the ceiling, and this air conditioning system corresponds to a so-called “convection air conditioning system”. .

Next, the ceiling structure after renovation will be described.
As shown in FIG. 1, most of the supporting hardware 1 and the members that suspend and support the supporting hardware 1 from the ceiling slab are reused without modification.
In addition, the air conditioner K, the air supply duct 5, the lighting fixture 2, and the sprinkler head, the fire detector, the ceiling-mounted speaker, the emergency lighting, and the like which are not shown in the figure are reused as they are before the repair.

The ceiling plate 3 has been replaced with a new ceiling unit T with respect to the object to be repaired.
The air outlet 4 is removed, and the air supply duct 5 that is connected to the air outlet 4 is reconnected to the ceiling unit T.

  As shown in FIGS. 1 and 2, the ceiling unit T includes a porous panel 6 whose outer dimensions are set in the same manner as the ceiling plate 3, and an air supply chamber 7 that can be placed on the upper surface of the porous panel 6. It is configured.

The perforated panel 6 is made of a corrugated plate material (for example, a square wave lightweight steel plate or the like), and includes a large number of air circulation holes 6a penetrating the front and back.
Moreover, it is preferable that the perforated panel 6 is comprised with the material with high heat conductivity. With this configuration, heat exchange between the conditioned air sent into the air supply chamber 7 and the perforated panel 6 is efficiently performed, and an air conditioning system that uses heat radiation from the perforated panel 6 downward to the ceiling (so-called “radiant air conditioning”). System ") can be effectively performed.

  Further, in this embodiment, a corrugated plate material is used (see FIG. 3). With this configuration, it is possible to increase the cross-sectional secondary moment as compared with the flat plate, and to suppress the bending due to the load of the air supply chamber 7 to be placed. And about the installation of the perforated panel 6, it arrange | positions as a support span between both the support hardware 1 so that a waveform peak part ridgeline may follow the space | interval direction of the support hardware 1 of mounting object. For convenience, the direction along the ridge line of the perforated panel 6 is referred to as “perforated panel span direction X”, and the direction along the longitudinal direction of the mounting hardware 1 to be placed is referred to as “perforated panel width direction Y” (see FIG. 2). .

The air circulation hole 6a is configured by a fine hole, and passes through the air-conditioned air so that it oozes out, thereby suppressing the draft feeling below the ceiling.
Further, as shown in FIG. 3, the air circulation hole 6a is formed only on the peak surface portion of the corrugated panel 6, and is formed on the lower side cross section of the neutral shaft that effectively acts when an overload is applied. We try not to make a defect and suppress the strength reduction.
Furthermore, since the perforated panel 6 is made of a corrugated plate material, even if condensed water or dust is generated on the upper surface of the perforated panel 6, they are easily moved to the valley surface portion and formed on the mountain surface portion. It is easy to prevent adverse effects such as clogging on the air circulation holes 6a. Therefore, the conditioned air sent from the air conditioner K into the air supply chamber 7 can always be oozed out through the air circulation hole 6a to the lower part of the ceiling.

Further, as shown in FIG. 2, the perforated panel 6 is constituted by a divided perforated panel 6 </ b> A divided into a plurality of parts in the perforated panel width direction Y. Each divided porous panel 6A is configured so that the relative positional relationship in the porous panel width direction Y can be arbitrarily changed.
Moreover, in the said embodiment, the thing which divided the perforated panel 6 into four parts is mentioned as an example, The air in the air supply chamber 7 is made into the division | segmentation perforated panel 6A of the one sheet among the four sheets below a ceiling. A fan F that blows out toward is attached. The one provided with the fan F is referred to as a divided porous panel 6Aa with a fan, and the one not provided with the fan F is referred to as a fanless divided porous panel 6Ab.
The drive operation of the fan F can be remotely operated with a remote controller or the like from the lower side of the ceiling, for example, and can be turned on and off as necessary.
Therefore, in the lower space where the divided porous panel 6Aa with the fan is installed, the direct air of the conditioned air from the fan F can be received, and personal air conditioning can be realized.

Each of the divided porous panels 6A has the same divided width dimension, and is configured such that the planar arrangement in the porous panel width direction Y in the ceiling unit T can be freely changed.
Therefore, for example, by simply changing the arrangement of the divided porous panel 6Aa with a fan according to the position where a person sits in the room, the position where the heat source is installed, etc., personal air conditioning for that part can be easily performed. It becomes like this.
A fan arrangement changing means H is configured by a divided perforated panel 6 </ b> A that is provided with a fan F in a part thereof and that can be arranged and changed.

The air supply chamber 7 is formed of a reinforced non-combustible corrugated cardboard with an aluminum foil attached, and is configured in a box shape with an open bottom surface as shown in FIG. An opening 8 is formed in a part of the upper surface portion 7 a of the air supply chamber 7, and a cylindrical connecting portion 9 is attached to the periphery of the opening 8 so as to extend upward.
An air supply duct 5 is connected to the connection portion 9 in communication.
Moreover, the cushion material 10 is attached to the lower edge of the side part 7b of the air supply chamber 7 over the entire circumference (see FIG. 3). Therefore, in the installed state where the air supply chamber 7 is placed on the porous panel 6, the cushion material 10 is elastically deformed so as to follow the corrugated shape of the porous panel 6. The gap can be sealed.

Next, a method for modifying the ceiling structure shown in FIG. 5 to the ceiling structure shown in FIG. 1 will be described.
[1] Remove the air outlet 4 from the air supply duct 5 and remove it.
[2] Remove the ceiling plate 3 at the place where the ceiling unit T is to be installed, and install it on the perforated panel 6 again. At that time, the divided porous panel 6Aa with a fan is arranged in accordance with a position where personal air conditioning is performed.
[3] The air supply chamber 7 is placed on the perforated panel 6 and the air supply duct 5 is connected to the connection portion 9 in communication.
By the above simple procedure, the ceiling structure with a different air conditioning system can be modified.

According to the ceiling air-conditioning technology described here, the convection air-conditioning ceiling structure can be easily and economically converted into a ceiling structure that allows fine and sophisticated air-conditioning that combines radiant air-conditioning and personal air-conditioning. It becomes possible to change to.
In addition, even after the repair, the work for changing the target position of the personal air conditioning and the maintenance work for the fan F can be easily performed.

[Another embodiment]
Other embodiments will be described below.

<1> The perforated panel 6 is not limited to the angular wave lightweight steel plate described in the previous embodiment, and may be a round wave panel. Moreover, it is not restricted to a corrugated panel, A flat plate may be sufficient.
Further, the material is not limited to the steel plate, and may be made of, for example, an aluminum alloy or another metal having high thermal conductivity. Moreover, it may be a material other than metal or a combination of these and metal.

<2> The relationship between the porous panel 6 and the fan F is such that the fan F is attached to a part of the divided porous panel 6Aa among the divided porous panels 6A divided into a plurality of parts as described in the previous embodiment. For example, as shown in FIG. 4, a fan F may be attached to an eccentric position of a single porous panel 6 that is not divided. According to the porous panel 6 of this embodiment, the arrangement of the fans F on the ceiling surface C can be changed by changing the installation orientation of the porous panel 6.
In addition, by replacing the perforated panel 6 in a place where the ceiling plate 3 before renovation is installed as it is or a place where a perforated panel not equipped with the fan F is installed, the ceiling surface C The arrangement of the fan F can be changed.
In addition, a single perforated panel 6 or a divided perforated panel 6Aa is provided with a plurality of detachable portions to which the fan F can be detachably attached, and the fan F to be replaced is selected from the plurality of detachable portions. The arrangement of the fans F on the ceiling surface C can be changed by selecting and changing the attachment / detachment portion.
These means are collectively referred to as fan arrangement changing means H.

<3> The divided perforated panel 6A is not limited to one obtained by dividing the perforated panel 6 into four equal to the perforated panel width direction Y as described in the previous embodiment. For example, the divided perforated panel 6A is divided into two equal parts, three equal parts, It may be divided into five or more equal parts. Further, the division is not limited to the perforated panel width direction Y, and the division width may be division that is not equal.

<4> The air supply chamber 7 is not limited to the material and structure described in the previous embodiment, and can be changed.

<5> The support 1 is not limited to the support hardware (T-bar) described in the previous embodiment. For example, I-type, H-type, and mountain-type can be selected. A light-weight angle may be attached to the lower end of the plate. In short, any material that can support the ceiling unit T, the ceiling plate 3 and the like may be used.

  In addition, as mentioned above, although the code | symbol was written in order to make contrast with drawing convenient, this invention is not limited to the structure of an accompanying drawing by this entry. In addition, it goes without saying that the present invention can be carried out in various modes without departing from the gist of the present invention.

1 Support hardware (an example of support)
3 Ceiling panel (equivalent to panel)
4 Air outlets for air conditioning (hereinafter simply referred to as air outlets)
5 Air supply duct 6 Porous panel 6a Air circulation hole 6A Divided perforated panel 6Aa Divided perforated panel with fan 7 Air supply chamber C Ceiling surface F Fan H Fan arrangement changing means K Air conditioner

Claims (6)

Provided with a large number of air circulation holes penetrating the front and back and a perforated panel that can be arranged along the ceiling surface.
A ceiling unit in which an air supply chamber having a lower opening is provided so as to be freely placed on the upper surface of the porous panel,
A ceiling unit in which a fan that blows out air in the air supply chamber toward a lower part of the ceiling is attached to a part of the perforated panel.   The ceiling unit according to claim 1, further comprising fan arrangement changing means capable of changing a planar arrangement of the fan in the air supply chamber. The fan arrangement changing means includes a plurality of divided porous panels formed by dividing the porous panel into a state in which the planar arrangement can be changed,
The ceiling unit according to claim 2, wherein the fan is attached to some of the divided porous panels.   The ceiling unit according to claim 1, wherein the perforated panel including the fan is formed to be replaceable with a panel not including the fan. A ceiling structure in which the ceiling unit according to any one of claims 1 to 4 is attached along the ceiling surface,
The perforated panel is supported across a support supported to be suspended from a ceiling slab with a lateral interval,
A ceiling structure in which an air supply duct from an air conditioner is connected to the air supply chamber. The ceiling according to claim 5, wherein a ceiling structure of a convection air-conditioning system in which a slit-like air outlet opening in a ceiling surface is provided, and the air supply duct from the air conditioner is connected to the air outlet. A ceiling repair method for repairing to a structure,
While replacing the ceiling panel adjacent to the air outlet with the perforated panel,
On the upper surface of the perforated panel, an air supply chamber having a lower opening is placed,
A ceiling repair method for changing the air supply duct connected to the air outlet to the air supply chamber.

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