JPH07133937A - Floor heater - Google Patents

Abstract

PURPOSE:To integrally build a floor heater with a floor structure by embedding a surface heater and a heat storage material in concrete without increasing a thickness of a floor itself. CONSTITUTION:A floor surface 13 having recesses 13a is formed by laying deck plates 10 in parallel, a heat storage material 4 having large latent heat and heater 3 for heating to melt the material 4 are contained to be disposed in the recesses 13a, and the heater 3 and the material 4 are integrally embedded in slab concrete 20 placed on the surface.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a floor heating system which employs a radiant heating system in which the heat from the floor makes the person feel warmth directly.

[0002]

2. Description of the Related Art As a floor heating device, a special composition having a large latent heat is used as a heat storage material, and this heat storage material is heated by a heater and melted, and then the solidification heat released when the heat storage material solidifies. It is known to use (latent heat) for heating, and examples of the heat storage material include sodium sulfate decahydrate (Na ₂ SO ₄ · 10H ₂ 0), calcium chloride, or sodium acetate-based materials. A heat storage material having a predetermined melting point (for example, 25 ° C. to 60 ° C.) is used.

Conventionally, a floor heating device of this type, for example, a floor heating device using a sheet heater as a heater and a pipe-shaped heat storage material has been constructed as shown in FIG. 4, for example.

That is, a heat insulating material 2 made of a hard urethane board or the like is laid all over the upper surface of the floor slab 1 having a predetermined wall thickness T and erected between the beams. Thin sheet heaters 3 having a width are arranged in parallel at a predetermined pitch. The upper surface of each sheet heater 3 is filled with a composition having a large latent heat, such as the above-mentioned sodium sulfate decahydrate or sodium acetate composition, in a regular plastic case (for example, a polypropylene package). The pipe-shaped heat storage material 4 is arranged in a plurality of rows, whereby each heat storage material 4 is heated and melted by each planar heater 3.

A plurality of heat storage materials 4 (five in the figure)
Each of them is put together in parallel and covered with a strip-shaped metal lid body 5, and a wire mesh 6 is arranged in a lattice pattern above the lid body 5. Further, a mortar 7 having a predetermined wall thickness t is cast on the upper surface of the heat insulating material 2 so that the wire mesh 6 is buried, and a desired finishing material 8 is laid on the upper surface of the mortar 7, and floor heating is performed. The device is built integrally with the floor structure.

Here, the heater such as the planar heater 3 and the heat storage material 4 are integrally embedded together with the wire mesh 6 inside the mortar 7 cast on the upper surface of the heat insulating material 2. Therefore, the thickness t of the mortar 7 is set to a thickness sufficient to bury them, for example, 80 mm or more.

[0007] The thickness T of the floor slab 1 is
According to the C standard, for example, for a reinforced lightweight concrete floor slab, it is determined that the length is 100 mm or more, and in practice, it is often 120 mm or more.

[0008]

However, in the above-mentioned conventional example, when the floor heating device is constructed integrally with the floor structure, the floor for burying the heater such as the planar heater 3 and the heat storage material 4 therein. Since a mortar 7 different from the slab 1 is required, and the floor slab 1 needs to have a predetermined wall thickness in relation to the standard, strength, etc. There was a problem that the thickness of itself increased.

Moreover, since the heat insulating material 2 is interposed between the floor slab 1 and the heater such as the planar heater 3 and the heat storage material 4, the floor slab 1 cannot be used as a sensible heat material under the present circumstances. Met.

The wall thickness t of the mortar 7 is considerably large as described above. Therefore, when a floor structure equipped with a floor heating device is constructed, not only the weight of the floor structure itself increases but also the ceiling. Was lower by that amount.

In view of the above, the present invention makes it possible to construct a floor heating device integrally with a floor structure by embedding the heater and the heat storage material inside concrete without increasing the thickness of the floor itself. The purpose is to provide what has been done.

[0012]

In order to achieve the above object, the floor heating apparatus according to the present invention has deck plates laid in parallel to form a floor surface having a recess, and a large latent heat is generated in the recess. A heat storage material and a heater for heating and melting the heat storage material are housed and arranged, and the heater and the heat storage material are integrally embedded inside slab concrete cast above the floor surface. It is what

[0013]

According to the present invention constructed as described above, the slab cast on the floor surface formed by laying the deck plate having a predetermined wall thickness which meets the standard such as the standard and the strength. Inside the concrete, by embedding a large heat storage material and a heat storage material and a planar heater for heating the heat storage material, eliminating the need to use another mortar for embedding these,
As a result, the floor heating device can be constructed integrally with the floor structure and the slab concrete can be used as a sensible heat material without increasing the thickness of the floor itself.

Moreover, by accommodating and disposing the heat storage material and the planar heater in the recess formed in the floor surface,
The influence on the strength of slab concrete can be eliminated.

[0015]

Embodiments of the present invention in which a sheet heater is used as a heater and a pipe-shaped heat storage material is used will be described below with reference to FIGS. 1 to 3.

1 and 2 show a so-called steel frame structure (S
Showing the example applied to the floor structure of the building of
In the figure, the reference numeral 10 is formed by bending a central portion in the length direction except both ends into a continuous cross-section dish shape, and projecting an I-shaped reinforcing rib portion 10a on the back surface side along the length direction. This is a long flat plate-shaped deck plate, and this deck plate 10 is laid in parallel by being bridged between beams 12 which are joined at both ends to vertically standing columns 11 and arranged horizontally. As a result, the recess 1 which is lowered one step on the upper surface is formed.
A floor surface 13 having 3a is formed.

The deck plate 10 is joined at both ends in the lengthwise direction to the deck receivers 15 at the beam 12 and the joint plate 14 by welding or the like, and side ends thereof are fitted to each other in the widthwise direction. Alternatively, the deck plates 10 that are connected by being overlapped and located on both sides are joined to the beam 12 and the deck bridge 15 by welding or the like as described above.

On the floor surface 13, a thin-walled sheet-like heater 3 having a predetermined width and located in the recess 13a formed therein is provided along the lengthwise direction of the deck plate 10 and almost the same. A composition having a large latent heat, such as the above sodium sulfate decahydrate or sodium acetate composition, is formed on the upper surface of the planar heater 3 while extending over the entire length, and the composition is shaped into a plastic case (for example, a polypropylene package). ) Etc., the pipe-shaped heat storage material 4 is arranged in a plurality of rows. Further, the heat storage material 4 is grouped in parallel by a plurality (five in the figure),
A strip-shaped metal lid 5 is covered.

As a result, by each sheet heater 3,
For example, each heat storage material 4 is heated at night and melts. Here, the depth of the recess 13a is d.
Is set to be larger than the total thickness h of the planar heater 3 and the heat storage material 4 (d> h), and the planar heater 3 and the heat storage material 4 have the floor surface 13 in the recess 13a. It is configured to be completely stored without protruding upward.

In this embodiment, the planar heater 3 is used as a heater for heating the heat storage material 4. However, in addition to the planar heater, a linear heater, a cord heater, a cable heater, and As a matter of course, any heater such as a hot water pipe may be used, and the sensible heat material may be any shape such as a flat plate shape or a spherical shape, other than the pipe shape.

The latent heat of the sodium sulfate decahydrate is, for example, 40 to 45 kcal / kg, and once melted, a large amount of heat is gradually released for a long time at a substantially constant temperature when solidifying. .

Further, a reinforcing bar 16 for slab concrete is arranged above the floor surface 13 while being held at a predetermined height via a spacer 17 standing on the floor surface 13.
Then, the slab concrete 18 is cast on the floor surface 13 so that the bar arrangement 17, by extension, the planar heater 3 and the heat storage material 4 are buried and have a predetermined wall thickness T that meets requirements such as standards and strengths. It is installed and the floor slab 1 is formed.

That is, as described above, the wall thickness T of the slab concrete 18 (floor slab 1) is regulated by strength, standards, etc., but is set to a thickness satisfying these requirements, for example, 150 mm. The planar heater 3 and the heat storage material 4 are embedded inside the slab concrete 18,
These are not exposed to the outside, and the planar heater 3 and the heat storage material 4
Are completely stored in the recess 13a so that the strength of the slab concrete 18 is not affected.

Incidentally, when the slab concrete 18 is poured, the deck plate 10 is used as a form. Then, a desired finishing material 8 is laid all over the upper surface of the slab concrete 18, and a spray heat insulating material layer 19 such as rock wool spraying material or closed cell urethane is provided on the lower surface of the deck plate 10 by , The floor heating system is constructed integrally with the floor structure.

As described above, by embedding the planar heater 3 and the heat storage material 4 inside the slab concrete 18 having a predetermined wall thickness T that meets the requirements of standards, strength, etc. There is no need to use another mortar, and it is possible to prevent the thickness of the floor itself from increasing due to the provision of the floor heating device, and to completely dispose the planar heater 3 and the heat storage material 4 in the recess 13a. The presence of these prevents the strength of the slab concrete 18 from being affected.

Furthermore, the slab concrete 18 can be used as a sensible heat material that retains and dissipates heat, thereby increasing the heat storage effect of the floor structure as a whole.

In the case of a reinforced concrete structure (RC structure) or a steel frame reinforced concrete structure (SRC structure), as shown in FIG. 3, decks located at both lengthwise ends and both widthwise sides of the deck plate 10 are used. The side end of the plate 10 is positioned so as to abut on the upper surface of a frame 20 having a U-shaped cross section that surrounds the beam 12 and opens upward, and slightly protrudes into this opening. This can be laid by striking nails, screw nails 22 or the like on the upper surface of the coral 21 arranged on the side of.

[0028]

Since the present invention has the above-mentioned structure,
By embedding the heat storage material and the heater inside the slab concrete with a predetermined wall thickness that conforms to the standards such as standards and strength, the need for separate mortar to bury these and the thickness of the floor itself By storing the planar heater and the heat storage material in the recess provided on the floor surface without increasing the temperature, it is possible to prevent the existence of these from affecting the strength of the floor structure itself, and The heating device can be integrated into the floor structure.

[0029] With this, it is possible to prevent the weight of the floor structure itself from increasing due to the provision of the floor heating device, and to use the steel frame structure without the floor heating device as it is. At the same time, it is possible to prevent the ceiling height from being lowered.

Furthermore, there is an effect that the heat storage effect of the entire floor structure can be increased by using the entire slab as the sensible heat material.

[Brief description of drawings]

FIG. 1 is a sectional view showing a first embodiment of the present invention.

FIG. 2 is a perspective view showing an example of laying a deck plate.

FIG. 3 is a perspective view showing another example of laying a deck plate.

FIG. 4 is a sectional view showing a conventional example.

[Explanation of symbols]

 1 Floor slab 3 Planar heater (heater) 4 Heat storage material 10 Deck plate 12 Beam 13 Floor surface 16 Slab concrete reinforcement 18 Slab concrete 20 Formwork

Claims (1)

[Claims] 1. A deck plate is laid in parallel to form a floor surface having a recess, and a heat storage material having a large latent heat and a heater for heating and melting the heat storage material are housed and arranged in the recess. At the same time, the heater and the heat storage material are integrally embedded in a slab concrete cast above the floor surface.