JP5164040B2 - Manufacturing method of inorganic fiber sheet - Google Patents

Description

  The present invention relates to a method for producing an inorganic fiber sheet.

The inorganic fiber sheet can be suitably used for, for example, electronic materials, battery materials, display materials, heat-resistant structural materials, catalysts, and the like.
As a method for producing an inorganic fiber sheet, Patent Document 1 discloses that “(1) a step of forming a sol solution mainly composed of inorganic components, (2) extruding the sol solution from a nozzle and applying an electric field to the extruded sol solution. Forming an inorganic gel-like fine fiber by being thinned by acting, and accumulating the inorganic gel-like fine fiber on a support; and (3) sintering the accumulated inorganic gel-like fine fiber. And the manufacturing method of an inorganic type structure characterized by including the process of forming the inorganic type structure containing an inorganic type sintered fine fiber "(Claim 2), According to this method, It is disclosed that a sheet made of silica fibers can be produced.

  Patent Document 2 discloses that “(1) a sol solution preparation step for forming a sol solution mainly composed of inorganic components, (2) extruding the sol solution from a nozzle and applying an electric field to the extruded sol solution. An accumulation step of forming an inorganic gel fiber by forming an inorganic gel fiber by forming an inorganic gel fiber and accumulating the inorganic gel fiber on a support that moves at a speed of 200 m / min. (3) Drying step of drying the inorganic gel fiber sheet to form an inorganic dry gel fiber sheet, (4) Sintering the inorganic gel fiber sheet or inorganic dry gel fiber sheet ”(Claims 6 and 7)”, “the relative humidity of the spinning chamber 4 is preferably set to 60% or less, and is set to 50% or less. More preferred "(Paragraph 0083) that," The integrated process temperature 23 ° C., carried out at set spun chamber relative humidity of 45% "(paragraph 0087) discloses that capable of producing silica filament sheet.

Patent Document 3 discloses that “(1) a sol solution preparation step for forming a sol solution mainly composed of inorganic components, (2) extruding the sol solution from a nozzle and applying an electric field to the extruded sol solution. A fiberizing step for forming an inorganic gel-like long fiber, (3) an accumulation step for accumulating the inorganic gel-like long fiber on a support that moves at a speed of 200 m / min. (4) Drying step of drying the accumulated inorganic gel-like long fibers to form inorganic dry gel-like long fibers, (5) Sintering the inorganic dry gel-like long fibers to inorganic sintering A sintering step of forming a long fiber, and (6) a cutting step of cutting the inorganic sintered long fiber to a desired length to form an inorganic sintered short fiber. A method for producing short fibers "(Claim 6) is disclosed. It is preferable to carry out in an atmosphere having a relative humidity of 60% or less (more preferably 50% or less) at around 0 ° C. Such an atmosphere is provided with, for example, a spinning chamber covering the periphery of the nozzle, It can be produced by adjusting the relative humidity ”(paragraph 0045),“ This fiberization and accumulation process is carried out in a spinning chamber set at a temperature of 23 ° C. and a relative humidity of 45% ”(paragraph 0078), silica. It is disclosed that short fibers can be produced.
As described above, in the production methods described in Patent Documents 1 to 3, silica fibers could be produced. However, when other inorganic fibers not containing a silica component were produced, the fiber contracted during spinning and formed during sheet formation. In some cases, cracks occur and an inorganic fiber sheet having a certain size cannot be obtained.

Further, Patent Document 4 states that “in a method for producing a fiber in which a spinning dope is discharged from a spinning dope supply unit in a spinning container and an electric field is applied to the discharged spinning dope to be fiberized, a desired relative humidity is obtained. And a fiber manufacturing method characterized in that only the periphery of the spinning dope supply section is maintained at a desired relative humidity ”(Claim 1),“ the spinning dope is used as a solvent and the solubility in water is 100 g. The method for producing a fiber according to claim 1 or 2, wherein a gas having a desired relative humidity is a gas having a relative humidity of 20% or less. (Claim 3), “The spinning dope is mainly composed of water as a solvent, and the gas having a desired relative humidity is a gas having a relative humidity of 40 to 70%. Item 2 The method of manufacturing fiber "(claim 5) is disclosed. Patent Document 4 states that “by supplying a gas having a desired relative humidity from the overall gas supply device 70 to the spinning container 6, the atmosphere in the spinning container 6 other than the periphery of the nozzle is changed to a desired relative humidity (of the nozzle 2. The desired relative humidity is the same as or different from the desired relative humidity in the periphery, and the relative humidity in the periphery of the nozzle 2 is easy to manage. "(Paragraph 0047)," ... (Omitted) ... Humidity-conditioned air set at a relative humidity of 15% is supplied from the supply device 7 to the rectifying vessel 5 at a rate of 50 L / min (rate of change in air flow: ± 1% or less), and the spinning dope via the air-permeable wall 5a (nonwoven fabric) Humidity control air is supplied in the same direction as the discharge direction of each nozzle so that the relative humidity of each nozzle is maintained at 15% relative humidity (humidity change ± 0.5% or less) and the relative humidity is supplied from the overall gas supply device 70. 30 Of supply air to the spinning chamber 6 at 3m ³ / min. (The air volume rate of change: ± 1% or less) to and maintaining the relative humidity of the spinning container 6 to 29.3 to 31.5% "(paragraph 0064), although it is disclosed that the humidity around the nozzle and the humidity in the spinning container are different, “the resin is not particularly limited, but, for example, polyethylene glycol, partially saponified polyvinyl Alcohol, fully saponified polyvinyl alcohol, polyvinyl pyrrolidone, polylactic acid, polyglycolic acid, polyacrylonitrile, polymethacrylic acid, polymethyl methacrylate, polycarbonate, polystyrene, polyamide, polyimide, polyethylene, or polypropylene can be used "(paragraph 0020). ) Is assumed to be organic resin, Not that assumes the system sol.

JP 2003-73964 A JP 2004-183131 A JP 2004-183132 A JP 2005-264401 A

  An object of the present invention is to provide a method for producing an inorganic fiber sheet having a certain area by preventing shrinkage during spinning and cracking during sheet formation.

The subject is a method of producing an inorganic fiber sheet by spinning a spinning stock solution comprising an inorganic sol according to the present invention by an electrostatic spinning method, and supplying the spinning stock solution to an atmosphere having a humidity of 40% or less. The inorganic fiber sheet manufacturing method is characterized in that the gel fiber is exposed to a high humidity atmosphere higher than the supply atmospheric humidity by 10% or more and then accumulated to form a fiber web and then fired. be able to.
According to the preferable aspect of the manufacturing method of this invention, the humidity of a high-humidity atmosphere is 50% or more.
In the present specification, “humidity” means relative humidity.

  According to the present invention, by setting the supply atmospheric humidity to 40% or less, the progress of the sol-gel reaction, that is, hydrolysis / condensation polymerization reaction in the supply unit is suppressed, and continuous supply property (spinnability) is ensured. In addition, when exposed to an atmosphere of high humidity, the sol-gel reaction of the gel fiber can proceed during flight, the fiber web can be prevented from shrinking, and the fiber web can be prevented from cracking. As a result, an inorganic fiber sheet having a large area can be produced.

  Examples of the inorganic sol used in the production method of the present invention include alumina sol, titania sol, zirconia sol, tin sol and the like, and silica sol can also be used. Since these inorganic sols can produce a spinning dope exhibiting spinnability, it is not necessary to mix organic polymers. Therefore, according to the production method of the present invention, there are disadvantages such as shrinkage during firing when an organic polymer is mixed, and weakness of the inorganic fiber sheet after firing when using a sol that does not exhibit spinnability. There is nothing. The inorganic sol can be used alone, or two or more inorganic sols can be mixed and used.

  An inorganic sol that exhibits spinnability can be adjusted by adjusting conditions such as reaction time and temperature after appropriately adjusting the amount of water and solvent, the type and amount of catalyst, and the type and amount of ligand. It can be produced by proceeding in a low dimension. Since the production conditions vary depending on the type of the metal element used as a raw material and the type of alkoxy group in the case of an alkoxide, the conditions are adjusted accordingly.

Examples of the catalyst that can be used include hydrochloric acid and nitric acid.
In addition, if the spinning dope contains a ligand, the progress of the sol-gel reaction can be controlled to some extent, the life of the spinnable sol solution can be extended, and the reactivity is very high. A spinnable sol can also be produced using alkoxide as a raw material. Examples of the ligand include glycols (for example, diethylene glycol), β-diketones (for example, acetylacetone), alkanolamines (for example, diethanolamine), and the like.

In the production method of the present invention, a supply unit used in a conventionally known electrostatic spinning method can be used as the supply unit for the spinning dope.
According to the electrospinning method, inorganic fibers that are continuous, thin, and have a large surface area can be produced. Therefore, it is easy to produce an inorganic fiber sheet that easily utilizes the characteristics of inorganic fibers.
As the supply unit of the electrostatic spinning method, for example, a nozzle, a wire, a cylinder, or the like can be used.

  The humidity of the supply atmosphere is 40% or less and preferably 30% or less so that the progress of the sol-gel reaction in the supply unit can be suppressed and the continuous supply property (spinnability) can be secured. Such atmospheric humidity can be achieved, for example, by supplying a gas having a humidity of 40% or less to the periphery of the supply unit in a state where the supply unit is enclosed and covered.

On the other hand, the humidity of the high humidity atmosphere to which the formed gel fiber is exposed is such that the sol-gel reaction of the gel fiber proceeds during the flight, thereby suppressing the shrinkage of the fiber web and preventing the fiber web from cracking. The humidity is 10% or more higher than the supply atmosphere humidity, and preferably 20% or more. In particular, it is preferably 50% or more, more preferably 60% or more, from the viewpoint that the sol-gel reaction of the gel fiber can sufficiently proceed.
For example, high humidity gas is supplied to the flying space of the gel fiber, or the entire flying space including the supply unit and the accumulating unit is stored in the spinning container, and the high humidity gas is supplied into the spinning container. Can be produced by doing.

A fiber web can be formed by accumulating gel fibers exposed to a high humidity atmosphere on an appropriate collector (for example, a cylinder, a conveyor, etc.).
In the case of the electrostatic spinning method, if the collector is conductive, it acts as a counter electrode. If the collector is not conductive, a counter electrode is provided separately.

Firing of the fiber web can be performed at 200 to 2000 ° C., for example.
The heating rate is 10 to 1000 ° C./hour, and the firing time is suitably 10 minutes to 10 hours (preferably 30 minutes to 2 hours).

  EXAMPLES Hereinafter, the present invention will be specifically described by way of examples, but these do not limit the scope of the present invention.

<< Example 1: Production of titanium oxide fiber sheet (1) >>
Titanium tetraisopropoxide [Ti (OC ₃ H ₇ )] was dissolved in 50 mL of 2-ethoxymethanol to a concentration of 0.1 mol / L, followed by addition of 0.01 mol / L nitric acid. This solution was heated to a temperature of 80 ° C. with stirring to advance the sol-gel reaction and to concentrate to obtain a spinning dope. This spinning dope had a viscosity of 400 mPa · s and a solid content concentration of 33 wt%.

The spinning solution is discharged from a nozzle under a spinning atmosphere at a temperature and humidity of 25 ° C./30% RH by an electrospinning method, and the gel fiber formed by discharging is formed in a high humidity atmosphere at a temperature and humidity of 25 ° C./50% RH. After passing, it accumulated on the metal plate and formed the gel fiber sheet which consists of a gel fiber with an average fiber diameter of 550 nm. The spinning atmosphere is controlled by sending air conditioned to a temperature / humidity of 25 ° C./30% RH at 50 mL / min from a cylinder installed at the rear of the nozzle, and the high humidity atmosphere has a nozzle and metal plate with a volume of 1 m ³ . It installed in the acrylic box, and it controlled by sending air adjusted to 25 degreeC / 50% RH in the box at 1 m < ³ > / min. Electrospinning was performed under the conditions of a discharge rate of 1 g / hour, a nozzle inner diameter of 0.25 mm, a distance between the nozzle tip and the metal plate of 10 cm, and an applied voltage of +8 kV. Further, the nozzle was reciprocated so that the basis weight of the gel fiber sheet was 10 g / m ² and the size was about 15 cm square.
When this gel fiber sheet was left in the room (25 ° C./40% RH) for 15 hours, the length of one side of the gel fiber sheet contracted by about 15%, but the gel fiber sheet was cracked. There wasn't.

Subsequently, the gel fiber sheet was fired at 600 ° C. in an electric furnace to obtain a titanium oxide fiber sheet (average fiber diameter: 500 nm, basis weight: 16 g / m ² , sheet size: about 9 cm square). The heating rate was 300 ° C./hour, and the firing time was 4 hours. In addition, although the length of one side in any direction of the titanium oxide fiber sheet contracted by about 30% by firing, no cracks were found in the titanium oxide fiber sheet.

<< Example 2: Production of titanium oxide fiber sheet (2) >>
A gel fiber sheet was produced in the same manner as in Example 1 except that the spinning atmosphere in the acrylic box was 25 ° C./60% RH. When the gel fiber sheet was left in the room (25 ° C./40% RH) for 15 hours, the length of one side of the gel fiber sheet contracted by about 12%, but no cracks were seen in the gel fiber sheet. It was.
Next, firing was performed in the same manner as in Example 1 to obtain a titanium oxide fiber sheet (average fiber diameter: 500 nm, basis weight: 15 g / m ² , sheet size: about 10 cm square). Although the length of one side in any direction of the titanium oxide fiber sheet contracted by firing by about 26%, no cracks were found in the titanium oxide fiber sheet.

<< Comparative Example 1 >>
A gel fiber sheet was produced in the same manner as in Example 1 except that the spinning atmosphere at the nozzle tip was 25 ° C./30% RH and the atmosphere in the acrylic box was 25 ° C./10% RH. When the gel fiber sheet was left in the room (25 ° C./40% RH) for 15 hours, the gel fiber sheet contracted and cracked, and was crushed to a size of 1 cm square or less.

<< Comparative Example 2 >>
A gel fiber sheet was produced in the same manner as in Example 1 except that the atmosphere in the acrylic box was 25 ° C./30% RH. When the gel fiber sheet was left in the room (25 ° C./40% RH) for 15 hours, the gel fiber sheet contracted and cracked, and was crushed to a size of 3 cm square or less.

<< Comparative Example 3 >>
A gel fiber sheet was prepared in the same manner as in Example 1 except that the spinning atmosphere at the nozzle tip was 25 ° C./50% RH, but the discharged spinning solution was solidified at the nozzle tip and continuously. Could not be spun.

<< Example 3: Production of tin oxide fiber sheet >>
10 g of tin chloride (SnCl ₂ ) was dissolved in 100 mL of methanol and reacted at 40 ° C. for 1 day, followed by concentration with an evaporator to obtain a spinning dope. This spinning dope had a solid content concentration of 47 wt% and a viscosity of 110 mPa · s.

The spinning solution is discharged from a nozzle under a spinning atmosphere at a temperature and humidity of 25 ° C./20% RH by an electrospinning method, and the gel fiber formed by discharging is formed in a high humidity atmosphere at a temperature and humidity of 25 ° C./50% RH. After passing, it was accumulated on a metal plate to form a gel fiber sheet made of gel fibers having an average fiber diameter of 250 nm. The spinning atmosphere is controlled by sending air adjusted to a temperature / humidity of 25 ° C./20% RH at 50 mL / min from a cylinder installed behind the nozzle, and the high-humidity atmosphere has a nozzle and metal plate with a volume of 1 m ³ . It installed in the acrylic box, and it controlled by sending air adjusted to 25 degreeC / 50% RH in the box at 1 m < ³ > / min. Electrospinning was performed under the conditions of a discharge rate of 0.5 g / hour, a nozzle inner diameter of 0.25 mm, a distance between the nozzle tip and the metal plate of 7 cm, and an applied voltage of +20 kV. Further, the nozzle was reciprocated so that the basis weight of the gel fiber sheet was 10 g / m ² and the size was about 10 cm square.
When this gel fiber sheet was allowed to stand indoors (25 ° C./40% RH) for 15 hours, the length of one side in any direction of the gel fiber sheet contracted by about 10%, but cracks were seen in the gel fiber sheet. There wasn't.

Next, the gel fiber sheet was fired at 450 ° C. in an electric furnace to obtain a tin oxide fiber sheet (average fiber diameter: 250 nm, basis weight: 8 g / m ² , sheet size: about 7.5 cm square). The heating rate was 450 ° C./hour, and the firing time was 1 hour. In addition, although the length of one side of any direction of the tin oxide fiber sheet contracted by about 17% by firing, no cracks were found in the tin oxide fiber sheet.

<< Comparative Example 4 >>
A gel fiber sheet was produced in the same manner as in Example 3 except that the spinning atmosphere at the nozzle tip was 25 ° C./20% RH and the atmosphere in the acrylic box was 25 ° C./20% RH. When the gel fiber sheet was left in the room (25 ° C./40% RH) for 15 hours, the gel fiber sheet contracted and cracked, and was crushed to a size of 1 cm square or less.

<< Comparative Example 5 >>
A gel fiber sheet was prepared in the same manner as in Example 3 except that the spinning atmosphere at the nozzle tip was 25 ° C./50% RH, but the discharged spinning solution was solidified at the nozzle tip and continuously. Could not be spun.

<< Example 4: Production of zirconium oxide fiber sheet >>
Zirconium tetra-n-butoxide [Zr (OnC ₄ H ₉ ) ₄ ]: Ethanol: Ethyl acetoacetate: Water: Nitric acid = 1: 10: 1: 2: 0.1 Was prepared. This spinning dope was prepared by the following procedure. First, a solution prepared by dissolving ethyl acetoacetate in 1/3 ethanol was added dropwise to a solution obtained by mixing Zr (OnC ₄ H ₉ ) ₄ with 1/3 of the total amount of ethanol, followed by stirring at 60 ° C. for 90 minutes. . Next, a solution obtained by mixing water and nitric acid in 1/3 ethanol was added dropwise to this solution, followed by stirring at 60 ° C. for 3 days, followed by concentration at 60 ° C. to obtain a solid content concentration of 45 wt% and a viscosity. A spinning dope of 300 mPa · s was obtained.

The spinning solution is discharged from a nozzle under a spinning atmosphere at a temperature and humidity of 25 ° C./20% RH by an electrospinning method, and the gel fiber formed by discharging is formed in a high humidity atmosphere at a temperature and humidity of 25 ° C./50% RH. After passing, the gel fiber sheet which accumulated on the metal plate and which consists of a gel fiber with an average fiber diameter of 600 nm was formed. The spinning atmosphere is controlled by sending air adjusted to a temperature / humidity of 25 ° C./20% RH at 50 mL / min from a cylinder installed behind the nozzle, and the high-humidity atmosphere has a nozzle and metal plate with a volume of 1 m ³ . It installed in the acrylic box, and it controlled by sending air adjusted to 25 degreeC / 50% RH in the box at 1 m < ³ > / min. Electrospinning was performed under the conditions of a discharge amount of 0.5 g / hour, a nozzle inner diameter of 0.25 mm, a distance between the nozzle tip and the metal plate of 10 cm, and an applied voltage of +12 kV. Further, the nozzle was reciprocated so that the basis weight of the gel fiber sheet was 10 g / m ² and the size was about 10 cm square.
When this gel fiber sheet was left in the room (25 ° C./40% RH) for 15 hours, the length of one side of the gel fiber sheet contracted by about 5%, but the gel fiber sheet was cracked. There wasn't.

Next, the gel fiber sheet was fired at 600 ° C. in an electric furnace to obtain a zirconium oxide fiber sheet (average fiber diameter: 450 nm, basis weight: 11 g / m ² , sheet size: about 6 cm square). The heating rate was 300 ° C./hour, and the firing time was 2 hours. In addition, although the length of one side in any direction of the zirconium oxide fiber sheet contracted by firing by about 22%, no cracks were found in the zirconium oxide fiber sheet.

<< Comparative Example 6 >>
A gel fiber sheet was prepared in the same manner as in Example 4 except that the spinning atmosphere at the nozzle tip was 25 ° C./50% RH, but the discharged spinning solution was solidified at the nozzle tip and continuously. Could not be spun.

  The inorganic fiber sheet obtained by the production method of the present invention can be applied to uses such as electronic materials, battery materials, display materials, heat-resistant structural materials, and catalysts.

Claims (2)

  A method for producing an inorganic fiber sheet by spinning a spinning stock solution comprising an inorganic sol by an electrostatic spinning method, wherein the spinning stock solution is supplied to an atmosphere having a humidity of 40% or less, and the formed gel fiber is supplied to the supply atmosphere. A method for producing an inorganic fiber sheet, characterized in that a fiber web is formed after being exposed to a high-humidity atmosphere higher than humidity by 10% or more, and then fired.   The manufacturing method of Claim 1 whose humidity of a high-humidity atmosphere is 50% or more.