JPH11241297A - Thermally insulating sheet - Google Patents

Abstract

PROBLEM TO BE SOLVED: To obtain a thermally insulating sheet that has high thermally insulating properties as well as excellent flame retardancy or incombustibility. SOLUTION: A slurry (paper stock) containing, as main materials, organic fine hollow particles with particle sizes of <=20 μm and a fibrous material is made to paper. As the hollow particles, pumicious send balloon with an average particle size of 5-15 μm is used. In a preferred embodiment, sepiolite is used as at least a part of the fibrous material. Even when an organic substance such as pulp is used in order to use ultrafine inorganic hollow particles stably dispersing in water, the proportion of the organic substance can be minimized and the slurry can give sheets containing a large amount of the inorganic hollow particles excellent in thermal insulation. In addition, since sepiolite has the agglomeration and sintering properties, flame retardancy or incombustibility of the sheet can further be increased.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a surface covering material or a backing material for a building such as a wall covering material requiring fire resistance or fire resistance.
Core material for building materials, furthermore, relates to a heat insulating material for electrical equipment, heat-resistant packing material, a heat-insulating sheet used as a heat-resistant filter, etc., more specifically, papermaking, that is, into paper or cardboard by the papermaking method. The present invention relates to a heat-insulating sheet that is manufactured and has excellent flame-retardancy or non-flammability with high heat-insulating properties.

[0002]

2. Description of the Related Art In recent years, there has been a great deal of interest in "functional paper" which is a papermaking sheet in which special functions and characteristics different from general pulp paper are highly pursued, and its development and research are being actively conducted. . A heat insulating sheet, which has a wide range of applications in fields requiring fire resistance or fire resistance, such as building materials, and is a typical example of asbestos paper (asbestos paper), is also a type.

[0003] As for the heat insulating sheet as the functional paper, an inorganic fiber sheet such as a glass fiber sheet which is already generally known is also an example. The following are known. That is, it contains asbestos in addition to sheet pulp, but is made by blending perlite or vermiculite, further forming a slurry by mixing a thermosetting resin powder, and laminating and thermoforming a plurality of the obtained sheets (insulating plate). ) [Special Publication 63
-233], a slurry (heat-absorbing sheet) made mainly of refractory inorganic fibers such as ceramic fibers and alumina trihydrate and added with an organic binder (Japanese Patent Publication No. 6-49).
55] Moreover, there is no heat resistance, but a laminate of synthetic resin foam layers for the purpose of keeping heat is available.

Further, recently, a heat-insulating sheet, which is formed by using a hollow spherical heated foam made from glassy volcanic ash produced on the Shirasu plateau together with a relatively small amount of pulp, ie, " Shirasu Balloon Paper "
Has been developed and proposed [VSI Workshop News,
etc]. As the shirasu balloon, specifically, a relatively fine average particle diameter of 50 μm and 20 μm
(Classification of 37 μm or less) is used.

[0005]

Among the heat-insulating sheets known in the art, shirasu balloon paper, which is the above-mentioned proposal, that is, shirasu balloon and pulp, which are fine hollow particles, is used as a main material, and these are used. Includes slurry (paper stock)
According to the sheet made from the above, high heat insulation can be obtained by the shirasu balloon having closed cells. Also,
Due to its heat insulating properties and the high content of the shirasu balloon, which is an inorganic particle, excellent flame retardancy or nonflammability (flame-blocking properties, heat resistance) can also be obtained.

[0006] However, it has been found that there is still some problem in practical use of such excellent shirasu balloon paper, although it is such an excellent paper. One of them is clogging of a paper net by shirasu balloon particles. And this clogging is slightly contained in the raw material.
It has been found to be caused by particles larger than μm, in particular particles of the order of 150 μm.

[0007] Further, one of such problems is particularly related to flame retardancy or nonflammability. That is, a shirasu balloon having a low specific gravity (generally, 0.6 to 0.8 g / cm ³ ) and having a spherical particle shape easily floats and separates in a slurry, and has poor bondability or fixability with pulp. There is a tendency. Therefore, in order to form a stable slurry for papermaking and to ensure good yieldability, it is necessary to use pulp at a relatively high ratio at the expense of flame retardancy or nonflammability. Was.

In view of the foregoing, an object of the present invention is to provide a heat insulating sheet having high heat insulating properties and excellent flame retardancy or nonflammability.

[0009]

While the present inventors are studying the above-mentioned shirasu balloon paper, shirasu balloons are hollow particles having bubbles inside, and the particle diameter is particularly 20 μm.
It has been found that, in the following cases, they are uniformly dispersed in water and exhibit the same behavior characteristics as colloids. And, by using such fine inorganic hollow particles, the pulp as the bonding fiber can be made the minimum ratio, thereby obtaining excellent flame retardancy or non-flammability together with high heat insulation. I confirmed that I can do it. In accordance with this, it is particularly preferable to use sepiolite, which is a hydrated magnesium silicate mineral, and / or brucite, which is a magnesium hydroxide mineral, as a fibrous material as a binding fiber of the inorganic fine hollow particles. It was confirmed that particularly excellent flame retardancy or nonflammability was obtained.

That is, the heat insulating sheet according to the present invention is characterized in that a slurry containing inorganic fine hollow particles having a particle diameter of 20 μm or less and a fibrous material as main materials is formed. Claim 1). The inorganic fine hollow particles are more preferably shirasu balloons, and the average particle diameter is more preferably 5 to 15 μm (Claim 2).

According to the heat insulating sheet, even when an organic substance such as pulp is used as the fibrous material as the binding fiber, the use ratio can be minimized. Therefore, it is possible to contain a high proportion of hollow particles that are inorganic and have a heat insulating effect, thereby obtaining excellent heat insulating properties and excellent flame retardancy and nonflammability.

In the present invention, as the fibrous material, inorganic fibrous materials can be used in addition to organic fibers such as pulp, and particularly, fine fibrous minerals, sepiolite and brucite, are used. Can be suitably used. That is, the heat insulating sheet according to the present invention,
A slurry containing the above inorganic fine hollow particles and sepiolite and / or brucite as main components is formed by papermaking (claim 3). And according to this heat insulating sheet, since sepiolite has sinterability together with solidification, the ratio of inorganic components can be made higher, and particularly excellent flame retardancy or nonflammability can be obtained. ,
Even when the sheet is baked by heat at the time of fire or the like, its shape is favorably maintained, and its excellent heat insulating property can be maintained. In addition, brucite has self-extinguishing properties due to dehydration and decomposition of hydroxyl groups, so that particularly excellent flame retardancy or nonflammability can be obtained as in the case of sepiolite. However, it is more preferable to use this brucite in combination with sepiolite in order to maintain good shape at the time of firing the sheet.

[0013]

DETAILED DESCRIPTION OF THE INVENTION As described above, the heat insulating sheet of the present invention uses inorganic fine hollow particles and an organic or inorganic fibrous material as main materials, and is produced by a usual papermaking method, Is prepared and a slurry is prepared.

Here, examples of the inorganic hollow particles include glass balloons such as shirasu balloons, silica balloons, fly ash balloons, ceramic balloons such as alumina-silica balloons, fired vermiculite, and pearlite. Among them, a heated shirasu foam, which is a vitreous volcanic eruption material containing silica as a main component, that is, a shirasu balloon made of fine closed hollow spherical particles is particularly preferable. That is, the bulk density 0.3 g / cm ^2, the true density is as small as 0.6~0.8g / cm ^2, and the thermal conductivity is as low as 0.04~0.05W / m · K, further softening Onset temperature is above 900 ° C and melting point is 12
It is 00 ° C or higher. Also, the particles that are sufficiently fine are 4
It has a breaking strength of more than 00 kgf / cm ² .

The finer inorganic fine hollow particles are more preferably finer. In particular, in the case of a shirasu balloon, it is preferably 20 μm or less, that is, it is preferable that particles exceeding 20 μm are not substantially contained. . Also,
More preferably, the average particle size is 7 to 15 μm. However, in the case of hollow body particles other than shirasu balloons having a slightly higher true density, or in the case where fine fibrous sepiolite and / or brucite is used as the fibrous material, the particle diameter may be about 50 μm or less. If
Although not preferred, it can be used practically. In addition,
On the other hand, the lower limit of the particle diameter of the inorganic fine hollow particles is not particularly limited as long as it is a hollow particle, but in the case of using a natural material such as a shirasu balloon as a raw material, a very fine particle is used. The particles may be clay-like solid particles. Therefore, in general, 1 μm
It is preferable to classify and use particles having a particle size larger than the limit.

As the fiber material which is the binding fiber or the skeleton or matrix forming fiber of the inorganic fine hollow particles, any organic or inorganic fibrous material can be used. And specifically, as the organic fiber, natural cellulose fiber pulp, that is, wood pulp such as softwood pulp, hardwood pulp, linter pulp,
Other plant fibers such as hemp and cotton, and regenerated fibers such as viscose rayon, and various synthetic fibers, for example, papermaking fibers such as polyester, acrylic or acrylic, nylon, and polyvinyl alcohol, or fibrillation. Pulp-like synthetic fibers such as aramid fibers, and the like. However, among these, softwood bleached kraft pulp (NBKP) and hardwood bleached kraft pulp (LB), which are the most widely used organic fibers as fiber materials for papermaking, are among these.
KP) and the like can be generally suitably used, and synthetic fibers can be used as reinforcing fibers.

Further, as the inorganic fibers, glass fibers such as E glass and carbon fibers which are mainly used as reinforcing fibers,
In addition to silica-alumina-based ceramic fibers or rock wool fibers, etc., fibrous minerals such as sepiolite, wollastonite, brucite, gypsum fibers, magnesium sulfate-based fibers, potassium titanate fibers or whiskers, silicon carbide, Whiskers such as silicon nitride or calcium carbonate; Since these inorganic fibers are nonflammable and have high heat resistance, they are particularly preferable as a fibrous material of a heat insulating sheet. However, these are generally high in rigidity and have a binding property other than sepiolite and brucite. Poor in binding and binding properties), so that it can be used practically with organic fibers, especially pulp.

Accordingly, a typical example of the fibrous material used as a main material together with the inorganic fine hollow particles is pulp or a combination thereof with an organic or inorganic fiber for reinforcement to enhance sheet strength. It is. However, in this case, the pulp or the organic fiber is preferably used in a proportion as small as possible in order to obtain excellent heat insulating properties by the inorganic fine hollow particles and to obtain excellent flame retardancy or non-flammability. Therefore, the pulp and the organic fiber for reinforcement can be generally used in a proportion of 5 to 30% by weight and 2 to 15% by weight, respectively, of the whole raw material, that is, the whole solid content in the slurry, but more preferably. Can be used in such a ratio that the total amount thereof becomes 35% by weight or less. In other words, in this case, the inorganic fine hollow particles can be used in a proportion of at least 50% by weight or more of the remainder, and can be used in a proportion of at least 65% by weight. Even with such a small proportion of pulp, since the inorganic fine hollow particles are sufficiently fine and have good paper-making properties, a sheet can be favorably formed.
When inorganic fibers such as glass fibers are used as reinforcing fibers, they can be used at a ratio of 2 to 15% by weight. The fiber length of the fibrous material used for reinforcement generally ranges from 3 to 15 including the case of organic fibers.
mm is appropriate.

A more preferable example of the fibrous material is the use of fibrous hydrated magnesium silicate mineral called sepiolite. That is, this sepiolite has many hydroxyl groups (silanol groups) on the surface, and thus has solidification (binding). Therefore, by using this sepiolite, a good skeleton (matrix) for binding and holding the inorganic fine hollow particles can be formed, and the pulp is used only in a smaller proportion, or the organic binder described later is used. By using this, a heat-insulating sheet having practically sufficient strength can be obtained without using pulp. Also,
Since sepiolite also has sinterability (bonding property by firing), a sheet containing it as a main material can maintain its shape well even if organic components are burned off. Thus, sepiolite can be used alone as a fibrous material, or in combination with a small amount of pulp, or in combination with organic or inorganic fibers for reinforcement. And the usage of the pulp can be about 3 to 15% by weight. Therefore, sepiolite is 15 to 85% by weight of the whole raw material, preferably 30 to 60% by weight.
And the inorganic fine hollow particles can be used in a proportion of at least 5% by weight or more.

Also preferred as sepiolite is brucite, which is a fine fibrous magnesium hydroxide mineral. That is, this brucite is not only excellent in consolidation like sepiolite, but also has a self-extinguishing property, releases water upon heating and undergoes endothermic decomposition. A non-flammable heat insulating sheet can be obtained. Since brucite, which is a natural mineral, has a sintering property due to silicates contained to some extent, it can be used alone at the same ratio as sepiolite. However, since sinterability is lower than that of sepiolite, the use of brucite is more preferably used in combination with sepiolite, and in this case, it is preferable to use brucite in a form that partially replaces sepiolite. This makes it possible to further improve the flame retardancy or nonflammability of the heat insulating sheet of the present invention using sepiolite.

In the heat insulating sheet of the present invention,
In order to ensure higher sheet strength (paper strength), an organic binder (paper strength enhancer) composed of a high molecular weight organic compound can be used in combination. Examples of such a binder include starch, polyvinyl alcohol, polyethylene oxide, carboxymethylcellulose, polyacrylamide, and urea-formaldehyde resins, melamine-formaldehyde resins which are thermosetting resins, and epoxidized polyamide resins (polyamideamine / epichlorohydrin). Resins), methylolated polyacrylamide and the like. Among them, particularly, polyacrylamide is preferably an ionic, that is, an ionic, that is, having an effect of enhancing fixing property or improving yield or cohesiveness. , Cationic or amphoteric modified products (copolymers)
Used as As the binder, an acrylic or polyester-based synthetic resin emulsion can also be used. However, from the viewpoint of ease of preparation of the slurry, the above-mentioned water-soluble organic binder is generally used. It can be more preferably used. And this organic binder is generally 0.5-5.
It can be used in a proportion of 0% by weight. However, in the case where organic fibers such as pulp are used, it is appropriate to adjust the blending of the organic material such that the total of the organic materials does not exceed 35% by weight.

Furthermore, some of the inorganic fine hollow particles can be replaced with other inorganic materials as long as their properties are not impaired. As such an inorganic material, in addition to the inorganic pigment (filler), colloidal silica, which is effective in increasing sheet strength and improving whiteness, has an effect of further improving surface smoothness and softness. Synthetic swellable mica or synthetic smectite, and aluminum hydroxide, hydrated calcium borate, etc., which are effective in improving flame retardancy or nonflammability in place of brucite, can be given. However, it is generally preferred that the usage ratio of these inorganic materials be kept within 10% by weight.

Using the inorganic fine hollow particles and the fibrous material as main materials, and further using an organic binder or the like as appropriate, the heat insulating sheet of the present invention is produced by a general ordinary papermaking method. can do. That is, the raw materials are uniformly dispersed in water, and the aggregated floc is formed, and a slurry preparation step of preparing a raw material slurry for papermaking, the prepared slurry is filtered through a paper net, And a papermaking step of forming a wet sheet by a paper machine, followed by a drying step of pressing and dewatering the wet sheet, followed by drying. As the paper machine, any machine such as a short net type, long net type, circular net type, or combination type can be used.
Those having a size of about 90 mesh can be generally used. In addition, in the slurry preparation step, an inorganic coagulant such as a sulfuric acid band, or a polymer coagulant is appropriately added separately from the binder in order to form a good coagulated floc of the main material component. Can be. Further, other filling materials such as a sizing agent can be appropriately added as needed. The sheet can be formed into a sheet having a thickness of generally about 0.15 to 1.5 mm or a sheet having a basis weight of about 80 to 200 g, depending on the specific use or the like.

The heat insulating sheet of the present invention thus produced by papermaking has a composition substantially corresponding to the solid content of the slurry, and is mainly composed of inorganic fine hollow particles and a fibrous material, particularly sepiolite. Even when pulp, which is an organic substance, is used as the fibrous material, the ratio of the inorganic material can be high because the ultrafine inorganic fine hollow particles having good formability are used. Therefore, together with excellent heat insulation by the inorganic fine hollow particles,
In particular, excellent flame retardancy or nonflammability can be obtained.

Therefore, the heat-insulating sheet can be widely used in the field where fire resistance or fire resistance is required, and is particularly suitably used as a base material for a wall material, a surface material of a building material or a backing material. be able to. Further, the non-combustible heat-resistant sheet may be further subjected to a water-repellent treatment with a silicone resin or the like, or a strengthening treatment by impregnation with an inorganic composition, whereby the use of the sheet can be further expanded. . Furthermore, a thermosetting resin is filled or impregnated in the heat insulating sheet, and a plurality of the thermosetting resins are laminated and thermoformed to form a heat insulating panel having a desired thickness. Further, the heat insulating sheet may be burned in an oxidizing atmosphere to burn off organic components, thereby obtaining a sheet made of a completely inorganic material. in this case,
The use of sepiolite is particularly preferred, so that a strong sintered sheet can be obtained.

The main use of the heat insulating sheet of the present invention is a honeycomb structural material used as a core material for building materials. That is, it is a honeycomb structure formed by using the heat insulating sheet as a base paper and using an adhesive to form a honeycomb structure including an aggregate of a large number of columnar cells. More specifically, this honeycomb structure is provided, for example, by providing an adhesive strip formed by applying a streak of an adhesive at regular intervals on the heat-insulating sheet, alternately shifting a half pitch, and laminating and bonding many sheets. Can be manufactured by a method of cutting into a desired width and then stretching (stretching method). In order to strengthen and improve non-flammability, a surface of a water glass composition solution is applied and impregnated to form an inorganic material. A coating can also be formed. Such a honeycomb structural material is not only lightweight and high-strength, but also has the advantage of having excellent heat-insulating properties and excellent flame-retardant or non-flammable properties by utilizing the features of the heat-insulating sheet of the present invention as a base paper. There is. Further, in particular, when sepiolite and / or brucite are used, there is an effect of having shape retaining properties (not collapsing) at the time of high-temperature heating such as a fire.

[0027]

EXAMPLES Example 1 Using the following materials, a heat insulating sheet of an example of the present invention was experimentally produced by a TAPPI hand-making apparatus. (Raw material composition) Shirasu balloon (average particle diameter 11 μm) 76.5 parts by weight Pulp 10 parts by weight Glass fiber 6 parts by weight Synthetic fiber 5 parts by weight Epoxidized polyamide resin 1.0 part by weight Anionic polyacrylamide 1.5 parts by weight Here The shirasu balloon is a white powder composed of fine hollow particles substantially containing no particles exceeding 20 μm, and has an average particle diameter of 11 μm. The bulk density of this shirasu balloon is 0.30 g / cm ² , the true density is 0.7 g / cm ² , and the thermal conductivity is 0.052 W
/ M · K. The pulp is made of softwood bleached kraft pulp (NBKP), the glass fiber is made of papermaking fiber having a diameter of 9 μm and a fiber length of 6 mm, and the synthetic fiber is made of 1.5%.
d, made of acrylic papermaking fiber having a fiber length of 5 mm.

Based on the above composition, the pulp, glass fiber and synthetic fiber previously beaten were defibrated by a mixer to form a slurry, and a shirasu balloon was added to the slurry to disperse the slurry. To this, the diluted anionic acrylamide was added and sufficiently stirred, and then the epoxidized polyamide resin was added and further stirred. As a result, a slurry in which the material components were flocked was formed.

[0029] This slurry was polished to a 90 mesh
× 25 cm) using a hand-making device, and then
The obtained wet sheet was dried under pressure at 100 ° C. by a heating press to obtain a heat insulating sheet having a thickness of 0.53 mm (average of five sheets, the same applies hereinafter) and a basis weight of 173 g / m ² . In addition, the yield was about 87%.

The heat insulating sheet has a tensile strength (JI
SP 8113), 2.83 kgf [break length 1.08 k
m], and the tear strength was 132 gf. Further, the heat conductivity of this heat insulating sheet was 0.10 W / m · K. Then, when a flame of a gas lighter was applied to this sheet to perform a combustion test, the portion where the flame was applied burned during that time and was carbonized to black brown, but the surrounding area did not burn and only slightly discolored Met. The carbonized portion did not collapse. That is, it exhibited excellent flame retardancy or nonflammability.

Example 2 A heat insulating sheet of another example of the present invention was produced in the same manner as in Example 1 using sepiolite. (Raw material blend) Shirasu balloon (average particle diameter 11 μm) 44.5 parts by weight Sepiolite 40 parts by weight Pulp 5 parts by weight Glass fiber 6 parts by weight Synthetic fiber 2 parts by weight Epoxidized polyamide resin 1.0 part by weight Anionic polyacrylamide 1. 5 parts by weight For the shirasu balloon and the like, the same one as in Example 1 was used.

Example 1 except that sepiolite was further used.
Similarly to the above, a slurry containing the above composition was prepared. Then, the slurry was formed into a sheet to obtain a heat insulating sheet having a thickness of 0.43 mm and a basis weight of 168 g / m ² . In addition, the yield was about 85%.

The heat-insulating sheet has a tensile strength of 2.05 kgf [break length of 0.81 km] and a thermal conductivity of 0.5 kgf.
It was 13 W / m · K. In addition, when a flame of a gas lighter was applied to this sheet to perform a combustion test, smoke was slightly emitted from the area where the flame was applied, and the sheet slightly browned, but the surrounding area showed no change. I couldn't see it. That is, it exhibited excellent nonflammability. In addition, this sheet
It was fired in an oxidizing atmosphere at 0 ° C. As a result, a porous and complete inorganic sheet which retained the original shape of the sheet was obtained.

Example 3 A heat insulating sheet of still another example of the present invention was produced in the same manner as in Example 1 using sepiolite and brucite. (Raw material composition) Shirasu balloon (average particle size 11 μm) 20 parts by weight Sepiolite 40 parts by weight Brucite 20 parts by weight Pulp 8 parts by weight Glass fiber 6 parts by weight Synthetic fiber 3.5 parts by weight Epoxidized polyamide resin 1.0 part by weight Anion 1.5 parts by weight of hydrophilic polyacrylamide The same shirasu balloon and the like as in Example 1 were used.

A slurry was prepared in the same manner as in Example 1 except that sepiolite and brucite were further used. The slurry was then sheeted to a thickness of 0.1 mm.
A heat insulating sheet having a thickness of 49 mm and a basis weight of 316 g / m ² was obtained. The yield was about 83%.

The heat-insulating sheet has a tensile strength of 3.17 kgf [break length of 1.25 km] and a thermal conductivity of 0.1 kgf.
It was 19 W / m · K. Further, when a flame of a gas lighter was applied to this sheet to perform a combustion test, smoke was slightly generated from the portion where the flame was applied, and the sheet slightly browned, but the degree was smaller than that in Example 2. Was something. No change was found in the surrounding area.
That is, it exhibited excellent nonflammability.

[0037]

As described above, the heat insulating sheet according to the present invention is obtained by forming a slurry containing inorganic fine hollow particles having a particle size of 20 μm or less and a fibrous material as main materials ( (1) More preferably, the inorganic fine hollow particles are made of a shirasu balloon having an average particle size of 5 to 15 μm (claim 2). Therefore, according to this heat insulating sheet, since extremely fine inorganic fine hollow particles, particularly shirasu balloons, are used, they are stably dispersed in water, and a small amount of fibrous material such as pulp as binding fibers is used. Even with this, it is possible to form a slurry having good papermaking properties such as yield. Therefore, since a sheet containing a high percentage of inorganic fine hollow particles and containing a small amount of organic matter such as pulp can be obtained, the high content of inorganic fine hollow particles, together with high heat insulation, excellent flame retardancy or Incombustibility (heat resistance or fire resistance) can be obtained.

Further, the heat insulating sheet according to the present invention uses sepiolite and / or brucite as at least a part of the fiber material (claim 3). Therefore, according to this heat-insulating sheet, sepiolite and brucite have caking properties (bonding properties), so that a strong sheet can be formed even when the usage ratio of pulp or the like is smaller. Excellent flame retardancy or non-flammability can be obtained. At the same time, sepiolite and brucite have sintering properties, so even if the sheet is exposed to a flame or placed under high heat, and organic matter such as pulp is burned off, the original shape of the sheet is obtained due to its sinterability. And heat insulation can be maintained.

Claims (3)

[Claims] 1. A heat-insulating sheet obtained by forming a slurry containing, as main materials, inorganic fine hollow particles having a particle size of 20 μm or less and a fibrous material. 2. The heat insulating sheet according to claim 1, wherein the inorganic fine hollow particles are made of shirasu balloons, and have an average particle diameter of 5 to 15 μm. 3. The heat insulating sheet according to claim 1, wherein at least a part of the fibrous material is made of sepiolite and / or brucite.