JPH10131330A - Execution method of ceiling thermal insulating material - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an execution method of a ceiling thermal insulating material capable of being simply executed without lowering heat insulation efficiency. SOLUTION: In this execution method, a ceiling thermal insulating material 1 formed of a fibrous thermal insulating material 2 coated with a resin film in a ventilable and enclosed state is set in a ceiling plenum. The rising of the ceiling thermal insulating material 1 is reduced by deaeration in the resin film to a sheet-like state, and after the sheet-like ceiling thermal insulating material 1 is set in a ceiling beam 4 of the ceiling plenum and a gap D between a brace 41 and ceiling grounds 5, air is supplied in the resin film again to restore the ceiling thermal insulating material 1 to the original rising, and the ceiling thermal insulating material 1 is compactly set in the gap D.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method for constructing a ceiling heat insulating material laid behind a ceiling.

[0002]

2. Description of the Related Art Generally, as shown in FIG. 4, a ceiling heat insulating material a to be laid below a ceiling is formed in a mat shape with heat insulating fiber b such as glass wool sandwiched between upper and lower moisture-proof papers c. It has been known.

Conventionally, when this ceiling heat insulating material a is constructed, as shown in FIG. 4 (a), a ceiling heat insulating material a cut to an appropriate size is replaced with a ceiling beam d and a ceiling beam d. And was laid so as to be inserted between the ceiling base e attached to the ceiling. Also, when the thickness of the ceiling insulation material a is large,
As shown in FIG. 4B, the ceiling heat insulating material a was laid on the ceiling base e so as to cover the brace f hung over the ceiling beam d.

[0004]

However, in the case of the above-mentioned conventional method of applying the ceiling heat insulating material a, the ceiling heat insulating material a is provided between the ceiling beam d and the ceiling base e attached to the ceiling beam d.
In a place where the gap between the ceiling beam d and the ceiling base e is narrow, the ceiling heat insulating material a cannot be inserted to the corner, and a gap g is generated and heat insulation occurs. This causes inconvenience such as lower efficiency.

In addition, when the ceiling heat insulating material a is inserted into such a place where the gap is narrow, the operation becomes troublesome, and at the time of insertion, the moisture-proof paper c provided above and below the heat insulating fiber b is broken, resulting in poor construction. Or the heat insulating fiber b is scattered to deteriorate the working environment.

[0006] Further, the ceiling heat insulating material a is placed on the brace f hung over the ceiling beam d so as to cover the ceiling base e.
When laid on the ceiling, the ceiling insulation material a rises and the gap g
And the inconvenience that the heat insulation efficiency is deteriorated occurs.

The present invention has been made in view of the above circumstances, and an object of the present invention is to provide a method of installing a ceiling heat insulating material that can be easily installed without lowering the heat insulation efficiency.

[0008]

SUMMARY OF THE INVENTION In order to solve the above-mentioned problems, a method of installing a ceiling heat insulating material according to the present invention is directed to a ceiling heat insulating material in which a fibrous heat insulating material is covered by a resin film in a sealed state capable of supplying and exhausting air. Is laid in the ceiling,
By degassing the air in the resin film, the bulk of the ceiling heat insulating material is reduced to a sheet shape, and the sheet-shaped ceiling heat insulating material is laid in the gap between the ceiling beams and braces above the ceiling and the ceiling base. Thereafter, air is sent again into the resin film to restore the ceiling heat insulating material to its original volume, and the ceiling heat insulating material is laid without gaps in the gap.

[0009]

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

FIG. 1 shows an outline of the entire structure of the ceiling heat insulating material 1, and FIG.

That is, in the method of applying the ceiling heat insulating material 1, the ceiling heat insulating material 1 in which the fibrous heat insulating material 2 is hermetically covered with the resin film 3 is used.
Ceiling beam 4 and brace 41 while supplying and exhausting air inside
And the ceiling base 5 is laid in the gap D.

As the fibrous heat insulating material 2, a material obtained by forming heat insulating fibers such as glass wool in a mat shape is used.

The resin film 3 is formed in a bag shape which can cover the above-mentioned mat-shaped fibrous heat insulating material 2 in a sealed state. The material of the resin film 3 is not particularly limited as long as it is airtight and can keep the fibrous heat insulating material 2 in a closed state. In addition, fibers may be mixed into the resin film 3 in order to impart durability, and aluminum vapor deposition or the like may be applied in order to enhance heat insulation. The fibrous heat insulating material 2 is formed by the resin film 3.
As a method of covering the resin film in a sealed state, the opening portion of the resin film 3 is heat-sealed or adhered with an adhesive tape while the fibrous heat insulating material 2 is inserted into the resin film 3 formed in a bag shape. It can be closed or closed with a slide fastener or the like that fits in a closed state. Further, in such a sealed state, a supply / exhaust port 30 which can be opened and closed by a detachable sealing tape 31 is formed on the upper surface of the resin film 3.

The ceiling heat insulating material 1 thus formed
In the normal state shown in FIG. 1A, the inside of the resin film 3 is evacuated from the air supply / exhaust port 30. This deaeration operation can be performed by compressing the ceiling heat insulating material 1 with the air supply / exhaust port 30 opened, or by sucking the air from the air supply / exhaust port 30.

As a result, as shown in FIG.
Since the bulk of the ceiling heat insulating material 1 is reduced, in this state, the air supply / exhaust port 3
The sealing tape 31 is stuck on 0 to maintain this reduced state. In this state, the bulk of the ceiling insulation material 1 is reduced by about 1 /
If the ceiling insulation material 1 is transported or stored in this state, it can be handled three times or more at a time, and the distribution cost and storage cost can be reduced. be able to.

In use, as shown in FIG. 1C, when the sealing tape 31 stuck to the air supply / exhaust port 30 is peeled off, air is naturally taken into the resin film 3 from the air supply / exhaust port 30, The ceiling insulation 1 returns to its original bulk.

Therefore, when the ceiling heat insulating material 1 is actually constructed, as shown in FIG.
The ceiling heat insulating material 1 is laid in a gap D between the brace 41 hung over the ceiling beam 4 and the ceiling base 5 suspended from the ceiling beam 4 in a state where the bulk of the ceiling beam is reduced. In this state, as shown in FIG. 2B, the thickness W1 of the ceiling heat insulating material 1 is larger than the gap D between the ceiling beam 4 and the brace 41 and the ceiling base 5.
Is smaller, the ceiling heat insulating material 1 can be easily laid in the gap D.

Then, as shown in FIG. 2 (c), after the ceiling heat insulating material 1 has been laid in this way, the sealing tape 31 stuck to the air supply / exhaust port 30 is peeled off. Since it returns to bulk and has a thickness W2 larger than the gap D, the ceiling heat insulating material 1 is laid without gaps in the gap D between the ceiling beam 4 and the ceiling base 5. Therefore, even in the gap D between the ceiling beam 4 and the ceiling base 5 which has been conventionally difficult to work, the ceiling heat insulating material 1 can be easily laid without any gap. A thermal bridge is prevented from being formed in a portion of the gap D between the first and second portions, and excellent heat insulating efficiency can be obtained.

Further, since the fibrous heat insulating material 2 is covered with the resin film 3 in the ceiling heat insulating material 1, the fiber heat insulating material 2 is covered from transportation and storage to construction work.
It is safe without the work environment deteriorating due to the scattering of fibers.

Further, if it is desired to re-install the ceiling heat insulating material 1 after a lapse of time due to a change in electric wiring or the like, the air supply / exhaust port 30 is again evacuated to reduce the bulk of the ceiling heat insulating material 1. Since the state can be returned to the state of 2 (b), it is possible to easily perform the construction work again.

In this embodiment, the resin film 3 is provided with two supply / exhaust ports 30. However, the number and position of the supply / exhaust ports 30 are not particularly limited. Further, a pipe or the like which is convenient for air supply and exhaust may be extended from the air supply and exhaust port 30.

Further, in the present embodiment, the supply / exhaust port 30 is provided in the resin film 3 and the sealing tape 31 provided in the supply / exhaust port 30 is attached / detached to supply / exhaust the air. The invention is not particularly limited to the air supply / exhaust method using the air supply / exhaust port 30. For example, a case where the opening of the resin film 3 formed in a bag shape is closed with a slide fastener or an adhesive tape is used. Alternatively, air may be supplied and exhausted simply by opening the opening. In addition, deaerate the ceiling insulation material 1 in advance.
2B, the ceiling heat insulating material 1 is applied to the gap D between the ceiling beam 4 and the ceiling base 5 as shown in FIG. By perforating the resin film 3, air may be taken into the resin film 3 to return to the original bulk. However, in this case, if the resin film 3 is perforated at random, it becomes difficult to deaerate the inside of the resin film 3 again and reduce the bulk of the ceiling heat insulating material 1, so that the construction work must be repeated. Is not preferred.

Further, in the present embodiment, the fibrous heat insulating material 2 formed in a mat shape is used. However, as shown in FIG. The used mat-shaped heat insulating material 20 may be used as it is. However, in the case of the heat insulating material 20, since both surfaces of the fibrous heat insulating material 2 formed in a mat shape are sandwiched by the moisture-proof paper 21, the portion of the moisture-proof paper 21 can be removed without air ventilation. You will not care. Therefore, when this heat insulating material 20 is used, the moisture-proof paper 2
It is preferable to use one provided with a vent hole 22 penetrating therethrough.

Further, the heat insulating fiber used for the fibrous heat insulating material 2 is not particularly limited. However, when the specific gravity (about 30 to 40 kg / m ³ ) increases like rock wool, the heat insulating fiber is made of resin. Even if the inside of the film 3 is degassed, it becomes difficult to reduce the bulk of the ceiling heat insulating material 1. Therefore, as the heat insulating fiber, specific gravity of 10 to 16k such as glass wool is used.
It is preferable to use one having a g / m ^{3 value} .

[0025]

As described above, according to the present invention, the air in the resin film is degassed to reduce the bulk of the ceiling heat insulating material to form a sheet. Can be laid. Then, in this state, the air is sent again into the resin film to restore the bulk of the ceiling insulating material to the original bulk, so that even in a place where the gap between the ceiling beam and the ceiling base is narrow, the gap is extended to the corner. The ceiling insulation can be laid without it. Therefore, excellent heat insulation efficiency can be obtained without forming a gap. In addition, even in the event that a gap is created, the inside of the resin film is degassed again to form a sheet in which the volume of the ceiling heat insulating material is reduced, and then the gap is corrected and air is sent again into the resin film. In this way, the gap can be reliably eliminated. Since this work does not damage the ceiling heat insulating material and does not involve the scattering of the heat insulating fibers, the work can be performed safely without causing a construction failure.

[Brief description of the drawings]

1 (a) to 1 (c) are perspective views showing a state before ceiling air-insulating material is degassed, a state where a bulk is reduced by degassing, and a state where the ceiling heat-insulating material is restored to its original bulkiness by air supply. .

FIGS. 2A to 2C are process diagrams showing a state in which a ceiling heat insulating material is applied to a gap between a ceiling beam and a ceiling base.

FIG. 3 is a partially cutaway perspective view showing another embodiment of a ceiling heat insulating material.

4 (a) and 4 (b) are perspective views showing a state of construction of a conventional ceiling heat insulating material.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Ceiling heat insulating material 2 Fibrous heat insulating material 3 Resin film 4 Ceiling beam 41 Brace 5 Ceiling base D gap

Claims (1)

[Claims] 1. A ceiling heat insulating material in which a fibrous heat insulating material is covered with a resin film so as to be able to supply and exhaust air,
A method of laying under the ceiling, in which the air in the resin film is degassed to reduce the volume of the ceiling heat insulating material to form a sheet. After laying in the gap between the brace and the ceiling base, air is again sent into the resin film to restore the ceiling insulation to the original bulk, and the ceiling insulation is laid without gaps in the gap. Method of ceiling insulation to be used.