JPH0519057B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION Field of Industrial Application This invention relates to a ceiling of a building equipped with heating and cooling functions using radiant panels.

Conventional technology Conventionally, ceilings of buildings equipped with a cooling function using radiant panels are already known, in which a band-shaped heat sink with a required width and a water pipe on the back side is installed over almost the entire surface of the ceiling. Ta.

Problems to be Solved by the Invention However, in such conventional ceilings, after the radiant panel has been installed, the lighting fixtures are directly attached to the bottom surface of the heat sink of the radiant panel, and the installation work of such lighting fixtures is extremely difficult. Not only is it troublesome and time-consuming, but the lighting fixtures block the radiant surface, preventing uniform radiation, resulting in low radiant efficiency and poor cooling performance.

In addition, if the radiant panel is installed over the entire surface of the ceiling, maintenance of the piping etc. in the ceiling cannot be performed, so it is necessary to install the radiant panel leaving a part of the periphery of the ceiling. There was a problem that the cooling efficiency decreased accordingly.

The object of the present invention is to solve the above-mentioned problems of the prior art, to make it possible to very easily attach a lighting fixture to a ceiling equipped with a radiant panel, and to
The radiant panel can be made larger and therefore easier to install.Moreover, the lighting equipment can be placed at the same level as the radiant panel without blocking the heat dissipation part of the radiant panel, so the radiation is uniform. ,
The radiant efficiency is extremely high, and in addition to making it possible to freely maintain the pipes in the ceiling, etc., the radiant panels can be installed on almost the entire surface of the ceiling without leaving the periphery of the ceiling, increasing heating and cooling efficiency. The aim is to provide building ceilings with heating and cooling functions using radiant panels.

Means for Solving the Problems In order to achieve the above object, the invention includes a plate-shaped heat radiating section and a fluid passage provided on the back surface of the heat radiating section and through which a heating medium for cooling or heating flows. A lighting fixture in which a plurality of radiant panels are attached to a beam in parallel via hanging members, a space is left between at least two radiant panels, and a downward opening is provided between both radiant panels. A lighting fixture mounting member having a substantially inverted U-shaped cross section and having a storage groove is disposed so as to close the gap, and the lighting fixture mounting member is removably attached to the beam via a hanging member. The gist is a building ceiling equipped with heating and cooling functions using radiant panels.

Embodiments Next, embodiments of the present invention will be described based on the drawings.

In FIGS. 1 to 4, the ceiling of a building equipped with a cooling function using the radiant panel of the present invention has a heat sink 2 made of three aluminum extrusions, and a serpentine shape provided on the back side of the heat sink 2. Four radiant panels 1 equipped with water pipes 4 are attached to beams 11 in parallel via hanging members 12. A gap 5 is provided between the adjacent radiant panels 1, 1, and between both the radiant panels 1, 1,
A lighting fixture mounting member 6 having a substantially inverted U-shaped cross section and having a lighting fixture storage concave groove 7 that opens downward is located between 5
The lighting fixture mounting member 6 is attached to the beam 11 via a hanging member 12.

The heat dissipation plate 2 of the radiant panel 1 is made of three aluminum extrusions, and as shown in FIG. A fitting convex portion with a cross-sectional shape is provided at the edge, and a fitting concave portion 10 with a cross-sectional shape is provided at the other side edge. It constitutes the heat dissipation part of.

On the other hand, the water pipe 4 is made of a copper pipe and has a meandering shape when viewed from above, and cold water is flowed as a cooling heat medium inside the water pipe 4. The three straight pipe portions 4a of the water pipe 4 are fitted into the water pipe fitting recesses 8 of the heat sink 2 and caulked. One end of the meandering water pipe 4 is connected to a header pipe 13 for introducing cold water, and the other end is connected to a header pipe 14 for discharging cold water.

The hanging member 12 has a substantially square shape when viewed from the front, and the center portion of its horizontal portion is attached to the horizontal portion of the beam 11 made of angle material through the bolt/nut 2. Outer convex portions 15, 15 are provided at the lower ends of both left and right vertical portions of each hanging member 12.

The left and right edges of the radiant panel 1 are provided with outward convex portions 1 of hanging members 12, 12 that are arranged opposite to each other.
It has been stopped from passing on 5.15. Further, a required intermediate portion of each radiant panel 1 is fixed with a screw 18 to a lower horizontal portion of a reinforcing member 17 attached to the beam 11 and shaped as seen from the side.

The lighting fixture mounting member 6 is made of extruded aluminum and has a substantially inverted U-shape in cross section, and its horizontal portion 6a is attached to the hanging member 12 with screws 18. Therefore, the lighting fixture mounting member 6 can be easily removed by loosening the screw 18.

Both left and right vertical parts 6 of this lighting equipment mounting member 6
Projections 6c, 6c having a square cross section and a square cross section are provided at the lower ends of the suspension members 12.
5, 15 and the side edges of the heat sink 2 of the radiation panel 1 are covered from below.

Note that a heat insulating material 19 is laid on the back surface of each radiant panel 1.

As shown in FIG. 1, the lighting fixture 20 is mounted on the ceiling having the above-mentioned configuration by being accommodated in the groove 7 of the lighting fixture mounting member 6.

Therefore, installation of the lighting fixture 20 becomes very simple, and the large radiant panel 1 can be installed as a unit, making construction easy. Moreover, since the lighting fixture 20 is housed in the concave groove 7, the lighting fixture 20 can be positioned at the same level as the radiant panel 1 without blocking the heat sink 2 of the radiant panel 1, so that the radiation is uniform. , has extremely high radiation efficiency.

Further, by loosening the set screw 18 of the lighting fixture mounting member 6 and removing the member 6, maintenance of the piping in the attic and the like can be performed freely.

Note that the heat dissipation plate 2 of the radiation panel 1 is, for example, the fifth
As shown in the figure, a tube-on-tube system is constructed of a heat sink 2 made of an aluminum coil material and a water pipe 4 made of a copper pipe having a passage 3.
It may also be made of a sheet.

FIG. 6 shows another arrangement of the radiant panel 1. As shown in FIG. Here, the difference from the above embodiment is that the meandering water pipe 4 of each radiant panel 1 has four straight parts 4a, and this water pipe 4
The point is that four heat sinks 2 are attached to the.

Therefore, in the above embodiment, as shown in FIG.
The certification device mounting members 6 are fitted and attached to each of the spaces 5 between adjacent radiant panels 1, which are arranged in parallel with spaces 5 apart, whereas in FIG. Two radiant panels 1 are arranged in parallel, and a lighting fixture mounting member 6 is provided in a total of two spaces 5 between adjacent radiant panels 1.
is fitted and installed.

In FIGS. 3 and 6 above, since the water pipe 3 has a meandering shape, the two ends of the water pipe 3 for one radiant panel 1 are welded to the header pipes 13 and 14, respectively. It's just connected. Therefore, in the case of a unit consisting of four radiant panels 1 and three lighting fixture mounting members 6 shown in FIG. 3, there are a total of eight connection points for water pipes 3, and three radiant In the case of a unit consisting of the panel 1 and two lighting fixture mounting members 6, the number of connection points for the water pipes 3 is six in total, which is even fewer.

By the way, in a conventional ceiling equipped with a cooling function using a radiant panel, one heat sink is attached to one straight water pipe. Therefore, for one heat sink, there are two places to connect the water pipe end to the header pipe by welding, and for example, if there are 12 heat sink plates 2 in total as shown in Figure 3, the water pipe end There are 24 connection points, which not only takes a lot of effort to connect the pipes, but also
There was a problem with the risk of water leakage.

On the other hand, according to the above two embodiments, since the radiant panel 1 is large and the water pipes 3 have a meandering shape, there are very few connection points of the ends of the water pipes 3 to the header pipes. Therefore, there are advantages in that the pipe connection work is very simple and the risk of water leakage is greatly reduced.

In addition, in the above embodiment, each radiant panel 1
Although a water pipe 4 is attached to the back surface of the heat sink 2, a heat pipe may be attached instead of the water pipe 4. In this case, at the end of the heat pipe,
A suitable cooling means such as cold water is brought into contact.

Such a heat pipe may be a straight tube in which a working fluid such as fluorocarbon is sealed as a heating medium and closed at both ends, or it may be a straight tube with a working fluid such as fluorocarbon as a heating medium sealed therein, or an aluminum roll bond panel having passages in a desired pattern. The heat pipe may be a plate-shaped heat pipe in which a working fluid such as fluorocarbon is sealed.
Further, the radiant panel 1 is not limited to an aluminum roll bond panel, and may be made by joining two aluminum plates, each having a recessed portion for a fluid passage formed in advance by press working.

Note that the metal constituting the radiation panel 1 is not limited to aluminum or copper, and other metals may of course be used.

In addition, in the above embodiment, a ceiling equipped with a cooling function using the radiant panel 1 was described.
A heating function may be provided to the ceiling by flowing a heat medium such as hot water through the passage 3 of the water pipe 4 of the radiant panel 1.

Further, in the above embodiment, a space 5 is provided between all the adjacent radiant panels 1, 1, and a lighting fixture mounting member 6 is fitted, but at least two radiant panels are installed on the ceiling. Between 1 and 1 comrades
5 is opened and at least one lighting fixture mounting member 6 is attached.

Effects of the Invention As described above, the ceiling of a building equipped with a heating and cooling function using a radiant panel according to the present invention includes a plate-shaped heat radiating part and a fluid passage provided on the back surface of the heat radiating part and through which a cooling or heating heat medium flows. A plurality of radiant panels equipped with the A lighting fixture mounting member with an approximately inverted U-shaped cross section that has an open recessed groove for storing lighting fixtures.
The lighting fixture mounting member is removably attached to the beam via a hanging member, and since the lighting fixture mounting member is built into the ceiling, the lighting fixture can be attached to the ceiling. Therefore, it is very easy to install the lighting equipment.

In addition, it is possible to increase the size of the radiant panel, and since the large radiant panel can be attached as a unit, construction is easy. Moreover, since the lighting equipment is housed in the groove, the lighting equipment can be positioned at the same level as the radiant panel without blocking the heat dissipation plate of the radiant panel, resulting in uniform radiation and extremely high radiation efficiency. expensive.

Furthermore, the set screw 18 of the lighting fixture mounting member 6
By loosening and removing the member 6, maintenance of the piping in the attic, etc. can be performed freely. Furthermore, since the radiant panel can be attached to almost the entire surface of the ceiling without leaving the peripheral edges of the ceiling, it is possible to increase the efficiency of heating and cooling.

[Brief explanation of the drawing]

The drawings show an embodiment of the present invention; FIG. 1 is a cross-sectional view of a ceiling of a building according to the present invention, FIG. 2 is a vertical cross-sectional view of the same portion, and FIG. 4 is a perspective view of the radiant panel, FIG. 5 is a perspective view of a modified example of the radiant panel, and FIG. 6 is a plan view showing another arrangement of the radiant panel. 1...Radiation panel, 2...Plate heat dissipation section, 3...
Fluid passage, 4... Between, 5... Concave groove for storing lighting equipment, 6... Member for mounting lighting equipment, 11... Beam, 1
2... Hanging member.

Claims (1)

[Claims] 1 A plate-shaped heat dissipation section 2 and a fluid passage 3 provided on the back surface of the heat dissipation section 2 and through which a cooling or heating heat medium flows.
A plurality of radiant panels 1 having a hanging member 1
2 is attached to the beam 11 in parallel, and there is a gap 5 between at least two radiant panels 1 and 1.
is opened, and a lighting fixture mounting member 6 having a substantially inverted U-shaped cross section and having a downwardly opened lighting fixture storage groove 7 is placed between the two radiant panels 1, 1 so as to close the gap 5. The ceiling of a building is equipped with a heating and cooling function using a radiant panel, in which a lighting fixture mounting member 6 is removably attached to a beam 11 via a hanging member 12.