JP2013079471A - Inorganic fiber aggregate and method for manufacturing the same - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an inorganic fiber aggregate using organic binders generating no irritating odor of formaldehyde, and a method for manufacturing the same.SOLUTION: A method for manufacturing an inorganic fiber aggregate comprises the steps of: aggregating inorganic fibers 12 and partially adhering binders 16 including a saccharide and a polyisocyanate to between filaments of the inorganic fibers 12; and heating the inorganic fibers 12 having the binders 16 adhered thereto to a cross-linking temperature at which the saccharide is cross-linked by the polyisocyanate and partially bonding between the filaments by using the cross-linked binders 16.

Description

  The present invention relates to an inorganic fiber aggregate in which inorganic fibers are bonded with a binder.

  As a sound absorbing material of a silencer (muffler) attached to an exhaust pipe of an automobile or the like, a glass fiber bonded with a binder is used.

  For example, as described in Patent Document 1, there is a glass fiber bonded with a binder such as a phenol resin. However, since the phenol resin binder uses formaldehyde as a raw material, an irritating odor such as formaldehyde is generated at the time of manufacture and use, and it is hated in the field of automobiles.

  Since there is little odor at the time of use, combining glass fiber with an inorganic binder is also considered. However, inorganic binders tend to be too hard because their bonding strength does not decrease even at high temperatures.

  In Patent Documents 2 and 3, a sugar such as starch is used as a polyisocyanate as a thermosetting binder having strong adhesiveness and excellent heat resistance, which is used for the production of automobile interior parts and adhesion of building interior materials. What is cross-linked has been proposed. However, Patent Documents 2 and 3 do not describe uses of this binder for bonding inorganic fibers such as glass fibers.

JP-A-8-177461 JP 2007-262366 A JP 2008-179736 A

  As described above, the phenol resin binder generates an irritating odor of formaldehyde during production and use, and the inorganic binder tends to be too hard.

  Then, an object of this invention is to provide the inorganic fiber assembly using the organic binder which does not generate the pungent smell of formaldehyde, and its manufacturing method.

  In order to solve the above-mentioned problems, the inorganic fiber aggregate of the present invention includes a binder in which a part of the aggregated inorganic fibers adhere between the part of the fibers and the saccharide is crosslinked with polyisocyanate by heat. Are combined.

  Further, another inorganic fiber aggregate of the present invention is a structure in which some of the aggregated inorganic fibers are bonded by a binder that adheres between the partial fibers and is cross-linked with polyisocyanate by sugar. Part or all of the binder is carbonized.

  In order to solve the above problems, the method for producing an inorganic fiber aggregate according to the present invention includes a step of assembling inorganic fibers and attaching a binder containing sugars and polyisocyanate between some of the inorganic fibers. Heating the inorganic fiber to which the binder is adhered to a crosslinking temperature at which the saccharide is crosslinked with the polyisocyanate, and partially bonding the fibers with the crosslinked binder.

  Further, another method for producing an inorganic fiber aggregate according to the present invention includes a step of assembling inorganic fibers and attaching a binder containing saccharides and polyisocyanate between some fibers of the inorganic fibers; Heating the adhering inorganic fibers to a crosslinking temperature at which the saccharide is crosslinked with the polyisocyanate, and bonding the fibers partially with the crosslinked binder; and the inorganic fibers bonded with the binder, Heating to a temperature at which the binder is carbonized to carbonize part or all of the binder.

  The aspect of each element of the manufacturing method of the inorganic fiber aggregate and inorganic fiber aggregate of the present invention is illustrated below.

1. Inorganic fiber aggregate The use of the inorganic fiber aggregate is not particularly limited, but the following can be exemplified.
-Sound absorbing material for silencer-Heat insulating material for microwave oven-Soundproofing material for automobile The place of use in the case of soundproofing material for automobile is not particularly limited, but the back of the hood can be exemplified.
-Packing for household appliances Although it does not specifically limit as a household appliance, an electric pot, a rice cooker, a hotplate, a microwave oven etc. can be illustrated.
-Gas combustion equipment packing Although it does not specifically limit as a gas combustion equipment, A water heater, a gas stove, a fan heater, a stove, etc. can be illustrated.

2. Inorganic fiber The inorganic fiber is not particularly limited, and examples thereof include glass fiber, silica fiber, rock wool fiber, ceramic fiber, alumina fiber, and basalt fiber. Glass fiber and silica fiber are preferable from the viewpoint of safety, and glass fiber is more preferable from the viewpoint of cost.

  The form of the inorganic fiber is not particularly limited, but may be a long fiber or a short fiber. When the inorganic fiber aggregate is a sound absorbing material for a silencer, it is preferable that the fiber length is long (50 mm or more) because scattering of inorganic fibers (particularly during use) can be prevented. On the other hand, when the inorganic fiber aggregate is a heat insulating material for a range, a soundproofing material for automobiles, a packing for home appliances or a packing for gas combustion equipment, the average fiber length is preferably 50 to 150 mm. If it is less than 50 mm, the fibers are unlikely to be entangled with each other, so that it is difficult to form a mat. On the other hand, if the thickness exceeds 150 mm, the manufacturing process is not stable because the fiber is easily wound around the manufacturing facility.

  Although the thickness of an inorganic fiber is not specifically limited, 3-24 micrometers is preferable. If it is less than 3 μm, the fiber is easily cut because the rigidity is low. On the other hand, if it exceeds 24 μm, the rigidity is too high, so that the fibers are hardly entangled with each other. More preferably, it is 5-12 micrometers.

3. Binder The binder may or may not contain components other than saccharides and polyisocyanate, such as a catalyst. The catalyst for shortening the crosslinking time or lowering the crosslinking temperature is not particularly limited, and examples thereof include catalysts used for polyurethanes such as amine compounds and organometallic compounds. It is preferable that the binder is thermosetting because there is little change in the binding force due to temperature (particularly at a temperature of 100 ° C. or higher).

Although the addition amount of a binder is not specifically limited, 2-30 mass parts can be illustrated with respect to 100 mass parts of inorganic fibers.
When the inorganic fiber aggregate is a sound absorbing material for a silencer, the addition amount of the binder is preferably 3 to 15 parts by mass with respect to 100 parts by mass of the inorganic fiber.
When the inorganic fiber aggregate is a microwave oven heat insulating material, the amount of the binder added is preferably 2 to 10 parts by mass with respect to 90 parts by mass of the inorganic fiber.
When the inorganic fiber aggregate is a soundproofing material for automobiles, the amount of the binder added is preferably 10 to 20 parts by mass with respect to 80 parts by mass of the inorganic fibers.
When the inorganic fiber aggregate is a packing for home appliances or a packing for gas combustion equipment, the addition amount of the binder is preferably 2 to 10 parts by mass with respect to 90 parts by mass of the inorganic fibers.
This is because, in each case, the bonding force becomes weak when the amount is less than the lower limit of the above range, and becomes too hard when the upper limit of the range is exceeded.

3-1. Examples of saccharides include, but are not limited to, monosaccharides such as glucose, disaccharides such as scrolls and maltose, oligosaccharides such as oligosaccharides, polysaccharides such as starch and cellulose, and the like. Alternatively, two or more kinds may be mixed and used (as a mixture).

3-2. Polyisocyanate Polyisocyanate is not particularly limited, but aromatic such as diphenylmethane diisocyanate (MDI), tolylene diisocyanate (TDI), xylylene diisocyanate (XDI), naphthalene diisocyanate (NDI), tetramethylene xylylene diisocyanate (TMXDI), etc. Isocyanates, isophorone diisocyanate (IPDI), hydrogenated (hydrogenated) MDI, dicyclohexylmethane diisocyanate (H12MDI), hydrogenated XDI (H6XDI), etc., hexamethylene diisocyanate (HDI), dimer acid diisocyanate (DDI) ), Aliphatic isocyanates such as norbornene diisocyanate (NBDI), etc., biuretized products thereof, isocyanurate Examples thereof include modified compounds, modified carbodiimides, etc., and these polyisocyanates may be used alone or in combination (as a mixture).

4). Crosslinking temperature Although a crosslinking temperature will not be specifically limited if it is more than the temperature at which the hydroxyl group of saccharides reacts with the isocyanate group of polyisocyanate, 160-230 degreeC can be illustrated.

5. Carbonization The temperature at which the binder is carbonized (carbonization temperature of the binder) is not particularly limited as long as it is equal to or higher than the temperature at which the organic binder is decomposed and carbonized (270 ° C. or higher). Since it can be performed, it is preferable that it is 300-350 degreeC.
Moreover, it is preferable that carbonization is partially carbonized so that the binding force by the binder remains.

ADVANTAGE OF THE INVENTION According to this invention, the inorganic fiber assembly using the organic binder which does not generate the pungent odor of formaldehyde can be provided.
Moreover, the inorganic fiber aggregate | assembly which can reduce odors other than formaldehyde at the time of use can be provided by carbonizing a part or all of a binder.

It is the perspective view of the sound-absorbing material for silencers of Example 1 of this invention, and the schematic diagram which expanded a part. It is a partial schematic diagram of the manufacturing process of the sound-absorbing material for the silencer. It is a partial schematic diagram of the manufacturing process of the heat insulating material for microwave ovens of the Example of this invention, the soundproofing material for motor vehicles, packing for household appliances, or packing for gas combustion equipment. It is a schematic diagram of the shaping | molding process of the soundproof material for motor vehicles of the Example of this invention.

  A sound absorber 10 for a silencer according to a first embodiment of the present invention will be described with reference to FIGS. 1 and 2.

  As shown in FIG. 1, the sound absorbing material 10 for a silencer adheres between some of the fibers of the glass fibers 12 gathered in a cotton-like manner, and the starch is crosslinked with polyisocyanate by heat. These are bonded by a thermosetting binder 16. The glass fiber 12 was a continuous fiber made of E-glass long fiber and having a wire diameter of about 24 μm. As a thermosetting binder, a product name “Bioprepolymer DBP2301” of Otsuchi Sangyo Co., Ltd. containing starch and polyisocyanate was used.

  Next, the manufacturing method of the sound absorbing material 10 for the silencer will be described.

  As shown in FIG. 2, the glass fiber 12 made into the roving 13 of 7000 TEX is supplied to the injection nozzle 14, and is injected in the form frame 15 from the front-end | tip of the injection nozzle 14 with about 0.5 MPa air. The glass fiber 12 is opened by being jetted together with air and accumulated in the form frame 15.

  Further, a powdery thermosetting binder 16 is sprayed from the tip of the spray nozzle 17 toward the glass fiber 12 opened by air and sprayed onto the glass fiber 12. The addition amount of a thermosetting binder is about 4 mass parts with respect to 100 mass parts of glass fiber. In order to improve the adhesion of the thermosetting binder 16, water may be supplied to the spray nozzle 14 to wet the glass fiber 12 with water.

  The opened glass fiber 12 is filled into the form frame 15 in a cotton shape. The form frame 15 is provided with a metal mesh 18 in the inner space, and the inner space is rectified by suction so that the glass mesh 12 does not come out of the form frame 15 by the metal mesh 18.

  The filled glass fiber 12 is heated together with the form frame 15 under a heating condition of a temperature of 200 ° C. and a heating time of 30 minutes, whereby the starch of the thermosetting binder 16 attached to the glass fiber 12 is crosslinked with polyisocyanate. Then, some of the glass fibers 12 are joined together to form the silencer sound absorbing material 10.

  Since the sound absorbing material 10 for the silencer of Example 1 uses a thermosetting binder that crosslinks starch with polyisocyanate, the odor of formaldehyde does not occur at the time of production and use, and it does not become too hard. Moreover, since the continuous fiber of glass is used, scattering of the glass fiber at the time of use etc. can be prevented.

  The heat insulating material for microwave ovens of Example 2 of the present invention will be described.

  The heat insulating material for the microwave oven is formed by a thermosetting binder 16 in which a part of the fibers of the glass fiber 12 assembled in a felt shape is adhered between the part of the fibers and the starch is crosslinked with polyisocyanate by heat. It has been combined. The thermosetting binder 16 is carbonized. The glass fiber 12 was made of E glass long fiber chops, having a wire diameter of about 5 μm and a fiber length of about 75 mm. As the thermosetting binder 16, a product name “Bioprepolymer DBP2301” of Taiho Sangyo Co., Ltd. containing starch and polyisocyanate was used.

  Next, the manufacturing method of the heat insulating material for microwave ovens is demonstrated using FIG.

  First, 90 parts by mass of the glass fibers 12 are arranged on the blender conveyor, and 15 parts by mass of the powder thermosetting binder 16 is sprinkled on the glass fiber 12 to adhere the thermosetting binder 16 to the glass fibers 12. Then, it opens using a cotton feeder. In addition, when opening is bad, opening with a cotton feeder is repeated.

A web is made using a card machine on the opened one. Then, it laminates | stacks so that it may become a desired fabric weight (for example, 700 g / m < ² >) using a cross layer machine. In addition, the clearance gap between the glass fibers 12 is adjusted so that what was laminated | stacked may become desired thickness (for example, 15 mm).

  The laminated product is placed on a conveyor (heater conveyor) passing through a heating furnace, heated at 200 ° C. for 5 minutes, and the starch of the thermosetting binder 16 attached to the glass fiber 12 is polyisocyanate. Are cross-linked, and some glass fibers 12 are bonded together to form a mat. Then, it winds up on a roll.

  What is wound on a roll is heated at 350 ° C. for 1 minute to carbonize at least the surface of the thermosetting binder 16, and then punched with a Thomson blade using a punching machine to form a microwave oven heat insulating material. Is done.

  Since the thermosetting binder which crosslinks starch with polyisocyanate was used for the heat insulating material for microwave oven of Example 2, the smell of formaldehyde does not generate at the time of manufacture and use, and it does not become too hard. Moreover, since it heats at least until the surface of a binder carbonizes, volatilization of the unreacted thing of a binder, a decomposition product, etc. can be reduced, and the odor at the time of use can be reduced.

  A soundproof material for automobiles according to Embodiment 3 of the present invention will be described.

  The soundproofing material for automobiles is bonded by a thermosetting binder 16 in which some fibers of the glass fibers 12 gathered in a felt shape are adhered between the some fibers and the starch is crosslinked with polyisocyanate by heat. It has been done. The glass fiber 12 was made of E glass long fiber chop, and had a wire diameter of 9 μm and a fiber length of about 75 mm. As the thermosetting binder 16, a product name “Bioprepolymer DBP2301” of Taiho Sangyo Co., Ltd. containing starch and polyisocyanate was used.

  Next, a method for manufacturing a soundproof material for automobiles will be described with reference to FIGS.

  First, 80 parts by mass of the glass fibers 12 are arranged on the blender conveyor, and 30 parts by mass of the powdered thermosetting binder 16 is sprinkled on the glass fibers 12 to adhere the thermosetting binder 16 to the glass fibers 12. Then, it opens using a cotton feeder. In addition, when opening is bad, opening with a cotton feeder is repeated.

A web is made using a card machine on the opened one. Then, it laminates | stacks so that it may become a desired fabric weight (for example, 1500 g / m < ² >) using a cross layer machine.

  The laminated product is placed on a conveyor (heater conveyor) passing through a heating furnace, heated at a temperature of 200 ° C. for 1 minute, and the starch of the thermosetting binder 16 attached to the glass fiber 12 is polyisocyanate. The glass fiber 12 is partially cross-linked and bonded to form a semi-cured mat. Then, it winds up on a roll.

  After the semi-cured mat wound on the roll is cut to a desired length, as shown in FIG. 4, using a mold attached to a hydraulic press machine at a temperature of 230 ° C. and a heating time of 1 minute. Molding is performed, and the starch of the thermosetting binder 16 attached to the glass fibers 12 is cross-linked with polyisocyanate, and a part (more than the semi-cured mat state) of glass fibers 12 is bonded and molded. Thereafter, the molded product is trimmed to form an automotive soundproofing material.

  Since the soundproofing material for automobiles of Example 3 uses a thermosetting binder that crosslinks starch with polyisocyanate, formaldehyde is not generated at the time of production and use, and it does not become too hard.

  The packing for household appliances or gas combustion equipment of Example 4 of the present invention will be described.

  Packing for home appliances or gas combustion equipment is a thermosetting in which a part of the fibers of the glass fiber 12 assembled in a felt shape is adhered between the part of the fibers and the starch is crosslinked with polyisocyanate by heat. These are bonded by the binder 16. The glass fiber 12 is made of a chop of E glass long fiber, and has a wire diameter of 5 μm and a fiber length of about 100 mm. As the thermosetting binder 16, a product name “Bioprepolymer DBP2301” of Taiho Sangyo Co., Ltd. containing starch and polyisocyanate was used.

Next, the manufacturing method of the packing for household appliances or gas combustion equipment is demonstrated using FIG.
In the packing for home appliances or gas combustion equipment, the method for producing a semi-cured mat is substantially the same as the method for producing a semi-cured mat for an automotive soundproof material (15 parts by mass of thermosetting binder 16 on 90 parts by mass of glass fiber 12). The only difference is that it is sprinkled and the basis weight is 500 g / m ² ). Then, the process of shape | molding the packing for household appliances or gas combustion equipment from a semi-cure mat is demonstrated.

After the semi-cured mat wound on the roll is cut to a desired length (1 m), it is molded using a hydraulic heating device under the conditions of a temperature of 230 ° C. and a heating time of 2 minutes, and adheres to the glass fiber 12 The cured starch of the thermosetting binder 16 is cross-linked with polyisocyanate to bind some glass fibers 12 to each other (more than the semi-cured mat state) and to form a flat plate having a thickness of 2 m (density is 250 kg / m ^3). ). Then, it punches with a Thomson blade using a punching machine, and the packing for household appliances or gas combustion equipment is formed.

  The packing for household appliances or gas combustion equipment of Example 4 uses a thermosetting binder that crosslinks starch with polyisocyanate, so that formaldehyde is not generated at the time of production and use, and it is not too hard. .

  In addition, this invention is not limited to the said Example, In the range which does not deviate from the meaning of invention, it can change suitably and can be actualized.

10 Sound absorber for silencer 12 Glass fiber 16 Thermosetting binder

Claims (4)

Assembling inorganic fibers and attaching a binder containing sugars and polyisocyanate between some of the inorganic fibers; and
Heating the inorganic fiber to which the binder is attached to a crosslinking temperature at which the saccharide is crosslinked with the polyisocyanate, and bonding a portion of the fibers with the crosslinked binder. . Assembling inorganic fibers and attaching a binder containing sugars and polyisocyanate between some of the inorganic fibers; and
Heating the inorganic fibers to which the binder is attached to a crosslinking temperature at which the saccharide is crosslinked with the polyisocyanate, and binding the fibers partially with the crosslinked binder;
Heating the inorganic fibers bound by the binder to a temperature at which the binder is carbonized, and carbonizing a part or all of the binder.   An inorganic fiber aggregate in which some of the aggregated inorganic fibers are bonded together by a binder that adheres between the partial fibers and is cross-linked with polyisocyanate by heat.   An inorganic fiber in which some or all of the binder is carbonized by bonding between the partial fibers of the aggregated inorganic fibers and bonding with a binder in which the saccharides are cross-linked with polyisocyanate by heat. Fiber assembly.

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