JP2000159551A - Production of silica aerogel panel - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a method for producing a silica aerogel panel by which particles of the aerogel can efficiently be filled in a space between transparent plates without unevenness. SOLUTION: A frame 3 is interposingly installed between outer peripheral parts of transparent plates 1 and 1 to form a hollow panel 4 having a space formed between the transparent plates 1 and 1 in a method for producing a silica aerogel panel comprising filling particles 2 of the silica aerogel in the space between the transparent plates 1 and 1. A charging port 5 is disposed in at least one site of the frame 3 and a suction port 6 is formed in at least another site. The particles 2 of the silica aerogel are fed from the charging port 5 while sucking air in the hollow panel 4 from the suction port 6 to fill the particles 2 of the silica aerogel in the space between the transparent plates 1 and 1.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method for producing a silica airgel panel having a layer of silica airgel particles inside.

[0002]

2. Description of the Related Art Silica airgel is a porous material having a low density, and has a characteristic that heat conductivity is very low and light transmittance is high. For this reason, silica airgel panels filled with silica airgel between transparent plates have attracted attention as architectural panels with excellent heat insulation and daylighting properties, and especially as panels used for entrance doors, windows, skylights, etc. in cold regions. Useful.

[0003] It is difficult to produce silica aerogels in a plate shape with good yield without cracks or chips. Therefore, a hollow panel is formed in which a frame is provided between the outer peripheral portions of a pair of transparent plates opposed in parallel, and a space is provided between the transparent plates, and silica is formed in a particulate form from an input port provided in the frame. It is common to produce a silica airgel panel by supplying airgel and filling the space between the transparent plates with silica airgel.

[0004]

However, the silica airgel particles are liable to be charged with static electricity, repel each other and scatter near the inlet, and it is difficult to efficiently fill the silica airgel between the transparent plates. there were. In addition, the silica airgel particles between the transparent plates also repel each other due to static electricity, causing a difference in the degree of filling between the transparent plates, causing uneven filling, resulting in a poor panel appearance,
There is a problem that the heat insulating performance is reduced in a portion where the silica airgel particles are coarsely filled.

[0005] The present invention has been made in view of the above-mentioned points, and efficiently disperses silica airgel particles between transparent plates.
Moreover, it is an object of the present invention to provide a method for producing a silica airgel panel that can be filled evenly.

[0006]

SUMMARY OF THE INVENTION A method of manufacturing a silica airgel panel according to the present invention comprises the steps of filling silica airgel particles 2 between transparent plates 1 and 1 to manufacture a silica airgel panel. A hollow panel 4 having a space between the transparent plates 1 and 1 is formed by interposing a frame 3 between the outer peripheral portions of the frame 3 and an input port 5 is provided in at least one place of the frame 3 and suction is performed in at least one other place. A mouth 6 is provided and a suction port 6 is provided.
It is characterized in that silica airgel particles 2 are supplied from an inlet 5 while being sucked from the substrate, and the silica airgel particles 2 are filled between the transparent plates 1 and 1.

Further, according to the invention of claim 2, after removing static electricity charged on the particles 2 of the silica airgel, the charging port 5 is removed.
Is characterized in that the silica airgel particles 2 are supplied from.

Further, according to a third aspect of the present invention, the silica airgel particles 2 are supplied from the inlet 5 while applying vibration to the hollow panel 4.
Is supplied.

[0009]

Embodiments of the present invention will be described below.

[0010] The silica airgel can be obtained by subjecting a gel compound made of alkoxysilane, sodium silicate, or the like to a hydrophobic treatment and supercritical drying. That is, US Patent Nos. 4,402,827 and 44,329
No. 56, No. 4,610,863, etc., a wet gel comprising a silica skeleton obtained by hydrolysis and polymerization of alkoxysilane (also referred to as silicon alkoxide or alkyl silicate). The compound can be produced by drying in a supercritical state above the critical point of the solvent in the presence of a solvent (dispersion medium) such as alcohol or carbon dioxide.
Nos. 5,137,297 and 5,124.
As provided in Japanese Patent Publication No. 364, it can be similarly produced using sodium silicate as a raw material. And
JP-A-5-279011, JP-A-7-13837
As disclosed in JP-A-5, it is preferable to use those obtained by imparting hydrophobicity to silica airgel by subjecting the above gel-like compound obtained by hydrolysis and polymerization of alkoxysilane to a hydrophobic treatment. .

In the present invention, the silica airgel is used in the form of particles, and its density is preferably in the range of 0.01 to 0.5 g / cm ³ from the viewpoint of heat insulation and light transmission. The range is more preferably from 0.1 to 0.2 g / cm ³ . Regarding the particle size and particle size distribution of the silica airgel particles 2, the thickness between the transparent plates 1 and 1 filled with the silica airgel particles 2, the required heat insulating property,
It is appropriately selected according to performance such as light transmittance, and is not particularly limited.

Next, the production of a silica airgel panel using the silica airgel particles 2 will be described.

First, as shown in FIG. 2, a frame 3 is provided as a spacer over the entire length of the outer peripheral portions of the pair of transparent plates 1, 1 and the transparent plates 1, 1 and the frame 3 are bonded to each other.
A hollow panel 4 in which a space is provided between a pair of transparent plates 1 and 1 facing in parallel is manufactured. A glass plate or a transparent plastic plate can be used as the transparent plate 1, and a frame formed of a metal material such as aluminum or a plastic material can be used as the frame 3. The frame 3 is provided with an input port 5 at at least one location and a suction port 6 at at least one other location. In the embodiment of FIG. 2, the inlet 5 is provided at one end of the upper part of the frame 3, and the suction port 6 is provided at the other end of the lower part of the frame 3. Suction port 6
A filter 10 that allows air to pass through but does not pass through the silica airgel particles 2, such as a wire mesh having a number of holes smaller than the particle size of the silica airgel particles 2,
The suction port 6 is closed.

Then, the tip of a suction hose of a suction device such as an air pump is connected to the suction port 6, and the air in the hollow panel 4 is sucked from the suction port 6 as shown by a single arrow in FIG. The silica airgel particles 2 are introduced into the space between the transparent plates 1 and 1 of the hollow panel 4 by introducing the silica airgel particles 2 from the introduction port 5 as shown by a double arrow.
The filling is performed as shown in FIG.

As described above, by sucking the air in the hollow panel 4 from the suction port 6, the air is sucked into the hollow panel 4 from the input port 5, and the silica aerogel supplied to the input port 5 is supplied. The particles 2 enter the hollow panel 4 from the inlet 5 together with the suction of the air, and the hollow panel 4 can be filled with the silica airgel particles 2. Therefore, even if the silica airgel particles 2 are charged with static electricity and repel each other, the force of sucking the silica airgel particles 2 from the input port 5 into the hollow panel 4 causes the silica airgel particles 2 to be generated near the input port 5. The silica airgel particles 2 can be efficiently filled between the transparent plates 1 and 1 without scattering. Even if the silica airgel particles 2 filled between the transparent plates 1 and 1 of the hollow panel 4 repel each other due to static electricity, the suction force from the suction port 6 causes the hollow panel 4 to move from the portion near the suction port 6. The silica airgel particles 2 can be sequentially filled, and the silica airgel particles 2 can be uniformly filled in the hollow panel 4 without causing uneven filling.

Even if the silica airgel particles 2 are charged with static electricity, suction is performed through the suction port 6 to efficiently and uniformly fill the hollow panel 4 with the silica airgel particles 2 from the charging port 5 as described above. Can be
Before supplying the silica airgel particles 2 to the inlet 5 as described above, it is preferable to remove static electricity charged on the silica airgel particles 2 in advance. The static electricity charged on the silica airgel particles 2 can be removed by using a static electricity removing air gun and blowing air generated from the static electricity removing air gun onto the silica airgel particles 2. The static electricity removing air gun blows out ionized air or an inert gas, and neutralizes and removes static electricity by blowing the ionized air. At this time, the silica airgel particles 2 from which static electricity has been removed by applying air from the static electricity removing air gun may be supplied to the inlet 5. Alternatively, the silica airgel particles 2 may be introduced while removing the static electricity by applying air from the static removing air gun. Either may be supplied to the mouth 5.

By removing the static electricity of the silica airgel particles 2 in this manner, the silica airgel particles 2 can be prevented from repelling each other, and can be charged without scattering near the input port 5. The silica airgel particles 2 can be more efficiently supplied and filled into the hollow panel 4 through the port 5.
It is possible to prevent unevenness in filling due to repulsion of the silica airgel particles 2 filled in the space therebetween, and to more uniformly fill the hollow panel 4 with the silica airgel particles 2.

Further, while the air in the hollow panel 4 is sucked from the suction port 6 as described above, the silica airgel particles 2 are charged from the charging port 5 to thereby provide a space between the transparent plates 1 and 1 of the hollow panel 4. When the silica airgel particles 2 are filled in, the filling operation can be performed while the hollow panel 4 is vibrated using a vibrator or the like. Of course, the silica airgel particles 2 at this time may be those from which static electricity has been removed in advance. By vibrating the hollow panel 4 in this manner, the silica airgel particles 2 can be filled in the hollow panel 4 so as to fill the gaps between the silica airgel particles 2. The silica airgel particles 2 can be filled at a high level. At this time, if the vibration is too strong, the silica airgel particles 2 may jump in the hollow panel 4 to lower the filling rate. Therefore, the vibration condition is set to a range where the silica airgel particles 2 do not jump and dance. Is preferred.

After the silica airgel particles 2 are filled in the hollow panel 4 as described above, the inside of the hollow panel 4 is sealed by closing the input port 5 and the suction port 6 with a lid.
It can be formed as a silica airgel panel. In this silica airgel panel, the particles 2 of the silica airgel are transparent, so that a high daylighting property can be obtained. In addition, since the particles 2 of the silica airgel have a small thermal conductivity, high heat insulating performance is obtained. Have Moreover, since the silica airgel particles 2 are uniformly filled between the transparent plates 1 and 1 of the hollow panel 4, the heat insulating performance can be obtained uniformly.

[0020]

The present invention will be described below in detail with reference to examples.

Example 1 A transparent glass plate having a thickness of 3 mm, a length of 50 cm and a width of 50 cm was used as the transparent plate 1 and had a width of 12 mm.
A hollow panel 4 was produced by sandwiching and bonding an aluminum frame 3 having a square frame shape of 2 mm between two transparent plates 1 and 1. This frame 3 has an inlet 5 having a diameter of 10 mm at one end of the upper part, and a diameter of 1 mm at the other end of the lower part.
Each of the suction ports 6 has a diameter of 0 mm, and the suction port 6 is provided with a wire mesh having an opening of 0.1 mm.

On the other hand, 47 parts by weight of an oligomer of tetramethoxysilane (“Methylsilicate 51” manufactured by Colcoat Co., Ltd., average molecular weight: about 470), 198 parts by weight of ethanol, 35 parts by weight of water, and 1.3 parts by weight of a 15N aqueous ammonia solution were added. After mixing and stirring for 1 minute, the obtained sol was allowed to stand at room temperature to obtain a gel. Immerse this gel in ethanol,
The ethanol was repeatedly exchanged while stirring, and the solvent was replaced for 24 hours. Next, this gel was immersed in an ethanol solution of hexamethyldisilazane (a reagent manufactured by Toray Dow Corning Silicone Co., Ltd.) having a concentration of 1.2 mol / liter, and subjected to a hydrophobic treatment for 24 hours while stirring at 78 ° C. Thereafter, the gel was transferred into ethanol again, and the ethanol was repeatedly exchanged with stirring, and the solvent was replaced for 24 hours. Next, this gel was placed in carbon dioxide at 18 ° C. and 55 atm, and an operation of replacing ethanol in the gel with carbon dioxide was performed for 2 to 3 hours. Thereafter, the inside of the system was brought to 80 ° C. and 160 atm, which are the supercritical conditions of carbon dioxide, and supercritical drying was performed for about 5 hours to obtain a hydrophobic silica airgel. The density of the obtained silica airgel is 0.1
g / cm ³ , which was ground to obtain silica airgel particles 2 having a particle size of 1 to 3 mm.

The silica airgel particles 2 were supplied into the hollow panel 4 from the input port 5 by using a conical hopper. At this time, the silica airgel particles 2 were charged while sucking from the suction port 6 using an air pump at a suction speed of 30 liter / min. Thus, the silica airgel particles 2 are contained in the hollow panel 4.
After filling, the inlet port 5 and the suction port 6 were plugged with a lid made of the same material as the frame 3 to obtain a silica airgel panel.

(Example 2) The static electricity of the silica airgel particles 2 was removed in advance by using a static electricity removing air gun ("HBA type" manufactured by Simco Japan Co., Ltd.). At this time, the static electricity was removed by the static electricity removing air gun by blowing air at a flow rate of 30 L / min for about 20 seconds to the 3 L silica airgel particles 2. A silica airgel panel was obtained in the same manner as in Example 1, except that the silica airgel particles 2 from which the static electricity had been removed were used.

(Embodiment 3) Hollow panel 4 using a vibrator
Was obtained in the same manner as in Example 1 except that the hollow panel 4 was filled with the silica airgel particles 2 while vibrating in the horizontal direction under the conditions of 5 Hz and an amplitude of 1 cm.

(Embodiment 4) Using a vibrator, the hollow panel 4
Was obtained in the same manner as in Example 2, except that the hollow panel 4 was filled with the silica airgel particles 2 while vibrating horizontally under the conditions of 5 Hz and an amplitude of 1 cm.

(Comparative Example 1) Example 2 was repeated except that the silica airgel particles 2 were charged into the hollow panel 4 from the input port 5 without suction through the suction port 6.
A silica airgel panel was obtained in the same manner as described above.

(Comparative Example 2) The hollow panel 4 in which the inlet 5 and the inlet 6 were covered without using the silica airgel particles 2 was used.

With respect to the silica airgel panels obtained in Examples 1 to 4 and Comparative Example 1 and the hollow panel of Comparative Example 2, the packing ratio of silica airgel particles, the presence or absence of uneven packing of silica airgel particles, the light transmittance, The heat transfer coefficient was measured for each. Table 1 shows the results.

Here, the presence or absence of uneven packing of the silica airgel particles was evaluated by visual observation from the side of the panel.

The light transmittance is measured by irradiating one side of the panel with light from a fluorescent lamp as a light source in an acrylic box, and measuring the illuminance before and after the panel is installed with an illuminometer (illuminometer “Model No. 510” manufactured by Yokogawa Instruments Inc.). -02 "), which was determined as follows. At this time, the distance between the fluorescent lamp and the illuminometer is constant.

Light transmittance = (illuminance when panel is installed) / (illuminance when panel is not installed) × 100 The heat transmission coefficient is as follows: indoor temperature 20 ° C., indoor humidity 80%, outdoor temperature A panel is horizontally installed between the room and the outside of the test room adjusted to -15 ° C and the outdoor humidity is 0%, and the temperature difference between the room and the outside and the heat flow value passing through the panel are measured with a heat flow meter (manufactured by Eiko Seiki Co., Ltd.) "MF-140D"). The heat transmission coefficient was measured at three points on the panel, and the maximum value, minimum value, and average value were obtained.

[0033]

[Table 1]

As can be seen from Table 1, the silica airgel particles of each embodiment in which the hollow panel was filled with silica airgel particles while sucking were compared with the silica airgel particles of Comparative Example 1 in which suction was not performed. The filling rate was high, there was no filling unevenness, and the variation of the heat transmission rate was small. Further, in addition to the suction, the method of Examples 2 to 3 in which the method of removing static electricity of the silica airgel particles and the method of vibrating the hollow panel are combined, the example 1 in which only suction is performed
It is confirmed that the packing ratio of the silica airgel particles is further increased as compared with that of Example 1.

[0035]

As described above, according to the present invention, a hollow panel having a space provided between the transparent plates with a frame interposed between the outer peripheral portions of the transparent plates is formed, and an input port is provided in at least one place of the frame. At the same time, a suction port is provided at at least one other location, and the silica airgel particles are supplied from the input port while sucking from the suction port to fill the silica airgel particles between the transparent plates, so that the silica airgel particles are charged with static electricity. Even if they are repelled by each other, the silica airgel particles are efficiently sucked between the transparent plates without the silica airgel particles being scattered near the input port by the force to suck the silica airgel particles into the hollow panel from the input port. The hollow panel can be sequentially filled with silica airgel particles from a portion near the suction port by a suction force from the suction port. Without filling unevenness occurs, in which can be filled uniformly silica airgel particles within the hollow panel.

According to the second aspect of the present invention, since the silica airgel particles are supplied from the inlet after removing the static electricity charged on the silica airgel particles, the silica airgel particles repel each other due to the static electricity. It is possible to more efficiently supply and fill the silica airgel particles into the hollow panel from the input port, and the silica airgel particles filled between the transparent plates are mutually charged by static electricity. The unevenness of filling due to repulsion can be prevented, and the silica airgel particles can be more uniformly filled in the hollow panel.

According to the third aspect of the present invention, since the silica airgel particles are supplied from the inlet while applying vibration to the hollow panel, the gap between the silica airgel particles is filled so that the silica airgel is filled in the hollow panel. Particles can be filled, and the silica airgel particles can be filled into the hollow panel at a high filling rate.

[Brief description of the drawings]

FIG. 1 shows an example of an embodiment of the present invention,
(A) is a front sectional view, and (b) is a side sectional view.

FIG. 2 is an exploded perspective view of the hollow panel.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Transparent plate 2 Silica aerogel particle 3 Frame 4 Hollow panel 5 Input port 6 Suction port

 ──────────────────────────────────────────────────続 き Continued on the front page (72) Inventor Mikio Kiyo 1048 Kadoma Kadoma, Osaka Prefecture Matsushita Electric Works, Ltd. (72) Inventor Hiroshi Yokokawa 1048 Okadoma Kadoma, Kadoma City, Osaka Matsushita Electric Works ( 72) Inventor Kenji Tsubaki 1048 Kazuma Kadoma, Kadoma City, Osaka Prefecture Inside the Matsushita Electric Works Co., Ltd. AA26 BA01 CA02 CB12 CB13 CD02 CD14 CD23 CD24 CD25 4G072 AA26 AA28 BB05 CC08 DD01 EE10 GG04 HH30 JJ23 JJ39 JJ44 LL04 LL11 LL15 MM01 MM26 MM34 MM35 MM40 PP03 QQ07 UU30

Claims (3)

[Claims] In producing a silica airgel panel by filling silica airgel particles between transparent plates,
Forming a hollow panel having a space between the transparent plates by providing a frame between the outer peripheral portions of the transparent plate, providing an input port in at least one place of the frame and providing a suction port in at least one other place,
A method for producing a silica airgel panel, characterized in that silica airgel particles are supplied from an input port while being sucked from a suction port, and the silica airgel particles are filled between transparent plates. 2. The method for producing a silica airgel panel according to claim 1, wherein the silica airgel particles are supplied from an inlet after removing static electricity charged on the silica airgel particles. 3. The method for producing a silica airgel panel according to claim 1, wherein particles of the silica airgel are supplied from an inlet while applying vibration to the hollow panel.