JP2015067467A - Method for producing carbon-coated graphite material - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a method for producing a carbon-coated graphite material capable of forming a smooth and dense carbon coating which hardly generates foaming, irregularities and cracking in the production process by a simple process in a short time.SOLUTION: There is provided a method for producing a carbon-coated graphite material, which comprises: an electrostatic coating step of spraying a charged carbon precursor to the surface of a graphite material to form a coating film; and a burning step of burning the graphite material on which the coating film is formed, wherein the coating film of the carbon precursor can be formed without using a large amount of a solvent. Therefore, the generation of air bubbles caused by the scattering of the solvent during curing or carbonization can be reduced and a carbon-coated graphite material having a smooth surface can be obtained by a simple process without causing irregularities and cracking on the surface.

Description

  The present invention relates to a method for producing a carbon-coated graphite material.

Graphite materials are used in various fields such as silicon single crystal pulling equipment, semiconductor manufacturing equipment, nuclear reactors, fusion reactors, heating furnaces, nozzles for continuous casting, jigs for heat treatment as ceramic materials with high heat resistance. ing.
However, the graphite material contains many pores inside, so depending on the application, the reaction surface area increases with the reactive gas or liquid, and thus the reaction is accelerated and consumed quickly. .
Various methods have been proposed to solve such problems.
Patent Document 1 describes a method for producing a graphite material (carbon-coated graphite material) coated with a carbonized phenol resin. Specifically, a method for producing a graphite crucible for a single crystal pulling apparatus, wherein the graphite crucible base material is immersed in a phenol resin solution at room temperature and normal pressure, and the immersed graphite crucible base material is taken out and heat treated. The gist thereof includes a curing step of curing the phenol resin, and a step of carbonizing the phenol resin by subjecting the cured phenol resin to further heat treatment.
According to the above invention, it is possible to produce a graphite crucible impregnated with phenol resin up to the inner surfaces of many open pores existing on the surface of the graphite crucible base material, and to extend the service life of the graphite crucible. It describes what you can do.

JP 2012-158503 A

However, when the above-mentioned conventional carbon-coated graphite material is coated with a liquid thermosetting resin, since the resin is in a liquid state, a foaming phenomenon occurs at the time of baking and baking, and unevenness and cracks occur on the surface. The phenomenon often occurs.
To fire and bake so that unevenness and cracks do not occur, it takes a complicated process that takes a long time, such as making the film extremely thin to suppress foaming, or increasing the temperature rise time and slowly removing volatile matter. It was. Even if a complicated process is performed, the carbonization yield decreases, and there is a problem that it is difficult to smooth and densify the surface.

If smoothing and densification cannot be performed, the surface area becomes large, the contact area with the reactive gas increases, and there is a problem that the function of the film such as corrosion resistance cannot be exhibited sufficiently.
An object of the present invention is to provide a method for producing a carbon-coated graphite material capable of forming a smooth and dense carbon coating that is less likely to cause foaming, unevenness, and cracks in the production process with a simple treatment in a short time. .

  The method for producing a carbon-coated graphite material of the present invention for solving the above problems includes an electrostatic coating step of forming a coating film by spraying a charged carbon precursor on the surface of the graphite material, And a firing step of firing the formed graphite material.

Furthermore, it is desirable that the method for producing a carbon-coated graphite material of the present invention is as follows.
The carbon precursor is a powder, a droplet, or a mixture thereof.

  The carbon precursor is a powder.

  The carbon precursor contains a thermosetting resin.

  The thermosetting resin is a B-stage thermosetting resin.

  The thermosetting resin is composed of one or more selected from a phenol resin, a furan resin, a copna resin, or a polyimide resin.

  The method for producing the carbon-coated graphite material includes a curing step of curing the coating film after the electrostatic coating step.

  According to the production method of the present invention, a film of a carbon precursor can be formed without using any solvent or with a small amount of solvent. For this reason, it is possible to reduce the emission of the solvent generated during curing or carbonization. For this reason, foaming can be reduced in the curing process, and the amount of gas generated in the carbonization process can be reduced, cracking due to volume shrinkage can be prevented, and it is simple without forming irregularities or cracks on the surface. A carbon-coated graphite material having a smooth surface can be obtained by the treatment.

Further, according to the production method of the present invention, the carbon precursor film can be formed without using any solvent or with a small amount of solvent. For this reason, the amount of the carbon precursor to be applied can be increased, and a dense carbon-coated graphite material can be obtained by a simple process.
Since the carbon-coated graphite material thus obtained has a dense and smooth carbon coating, the outer surface area can be reduced. For this reason, when used in an atmosphere containing a reactive gas, the contact area with the reactive gas can be reduced, and the function of the film such as corrosion resistance can be sufficiently exhibited. In addition, the densified film has a higher density and can reduce the thickness of the carbon coating required when reacting with a certain number of moles of reactive gas, thereby increasing the durability of the carbonaceous coating. There is.

The schematic diagram of the electrostatic coating of embodiment of this invention.

The method for producing a carbon-coated graphite material according to an embodiment of the present invention includes an electrostatic coating step of forming a coating film by spraying a charged carbon precursor on the surface of the graphite material, and graphite having the coating film formed thereon. A firing step of firing the material.
Although it does not specifically limit with the graphite material of embodiment of this invention, Isotropic graphite, extruded graphite, etc. can be utilized. Since these graphites can easily obtain a material having a large size, they can be processed into graphite parts used in various fields. However, since these graphite materials are porous bodies, by forming the carbon film of the embodiment of the present invention on the surface, it is possible to exert the effect of suppressing the contact with the reactive gas and slowing the reaction rate. . These graphite materials can be obtained, for example, by kneading using coke or pitch coke and coal tar pitch, followed by molding, firing, and graphitization.

Originally, electrostatic coating is a coating method widely used for conductive materials such as metals.
Since graphite material is a conductive substance like metal, electrostatic powder coating is possible.
Since the graphite material has conductivity necessary for electrostatic coating, the graphite material is not particularly limited as long as the surface is exposed so as to have conductivity and the graphite material is exposed.

The carbon precursor according to the embodiment of the present invention is a resin that is a resin in an unreacted state, but has a characteristic of being carbonized by firing.
The aspect of the carbon precursor is not particularly limited, and powder, droplets, a mixture thereof, and the like can be used. Among these, the carbon precursor is preferably a powder. Using a powdered carbon precursor makes it possible to reduce the amount of gas generated from the carbon precursor and to obtain a fine particle powder that is easy to disperse and easily obtain a smooth carbon coating. Can do. The size of the powder or droplet is preferably 1 to 100 μm. When the size of the powder or droplet is 1 μm or more, the specific surface area is small, so that the air resistance per weight received from the atmosphere is small and the coating can be facilitated. When the size of the powder or droplet is 100 μm or less, the powder or droplet can be easily applied because the powder or droplet is light relative to the size of the charge to be charged.

  The carbon precursor of the embodiment of the present invention is preferably a thermosetting resin. A thermosetting resin is characterized by being cured by heating and not softened even after heating, so that it is a resin with little volume fluctuation and has the effect of reducing the risk of cracking or film peeling. When using such a thermosetting resin, it is preferable to perform a hardening process after an electrostatic coating process.

The thermosetting resin according to the embodiment of the present invention is preferably an A-stage or a B-stage, and more preferably a B-stage.
Thermosetting resins are classified into A-stage, B-stage, and C-stage in order from the raw material to complete curing, and the reaction proceeds in the order of A, B, and C.
The A-stage is an initial state of the thermosetting resin production reaction, and is completely dissolved in a solvent and melts when heated.
The B-stage is an intermediate state of curing of the thermosetting resin, and dissolves in a solvent and softens when heated, but does not completely melt or dissolve. That is, it is a state in which a part is gelled.
The C-stage is the final state of curing of the thermosetting resin, is insoluble and infusible, and the completely cured thermosetting resin is in this state.

In addition, although it is a carbon precursor, the raw material stage of the thermosetting resin which is not classified into a thermosetting resin is a front | former stage of A-stage.
Such a thermosetting resin can suppress the generation of gas due to the reaction because the product of the reaction is less than that of the raw material stage, can reduce the generation of gas in the curing process and the firing process, and can prevent bubbles or cracks. There is an effect to prevent.
In addition, since the reaction of the thermosetting resin of B-Stage has progressed, the amount of low-molecular-weight by-products generated by the reaction is small, and foaming can be made difficult. Examples of the low molecular weight by-product include water, carbon dioxide gas, and ammonia.

FIG. 1 shows an electrostatic coating process of the carbon-coated graphite material of this example.
In the electrostatic coating according to the embodiment of the present invention, powder or liquid resin is used for the carbon precursor 2a that is a paint, and is used as powder or droplets at the stage of application. At this time, the droplet and the powder may be used simultaneously. In the electrostatic coating according to the embodiment of the present invention, the graphite material 1 as an object to be coated is charged to a positive charge or a negative charge, and the carbon precursor powder or droplet is charged to the opposite charge. Apply by mutual suction. By using electrostatic coating, the carbon precursor can be efficiently applied to the graphite material 1. Moreover, it can coat little by little using the gun 3 for a coating, and can form the coating film of a uniform carbon precursor, without being received to a big influence on the surface shape of the graphite material 1. FIG. Specifically, for example, it can be performed as follows.

  The coating gun 3 is directed to the grounded graphite material, and the carbon precursor 2a that is in the form of powder or droplets together with air is ejected from the coating gun 3, and the needle electrode 4 at the discharge port of the coating gun is ejected. A DC high voltage is applied to cause a corona discharge between the needle-like electrode 4 and the graphite material 1, and the carbon precursor 2a is charged by the corona discharge, and the charged carbon precursor 2b powder or droplets are The carbon precursor is attached to the surface of the graphite material 1 by the Coulomb force generated by the electric field 5 between the coating gun 3 and the graphite material 1.

The method of electrostatic coating is not particularly limited, and for example, the carbon precursor can be charged by static electricity generated by friction when passing through a pipe provided in a coating gun. As the material of the pipe used at this time, a fluorine resin or the like is used. Electrostatic coating by such a frictional force can be used similarly.
In addition, when using powder for a carbon precursor, electrostatic coating is also called electrostatic powder coating.

The graphite material coated with the carbon precursor is fired and carbonized to obtain a carbon-coated graphite material.
In the initial stage of the firing process, the generation of gases such as decomposition gas and dissolved gas generated slightly from the liquefied carbon precursor is mitigated by using a heating pattern such as heating gently or holding time. You may do it. By using such a heating pattern, a dense and smooth carbon-coated graphite material can be obtained.
When the carbon precursor is a thermosetting resin, it is preferable to divide the heating into two stages and perform the curing step and the firing step separately.

  In the curing step, gelation of the thermosetting resin is promoted. Since the thermosetting resin can be cured with or without the solvent, when the thermosetting resin containing the solvent is cured, the solvent that could not be volatilized remains taken into the thermosetting resin and swells. A thermosetting resin is obtained. When the thermosetting resin is used as it is, the solvent taken into the thermosetting resin is gradually released to the outside by diffusion, and even if it is used as it is taken into the thermosetting resin, it is applied. Since the membrane does not dissolve or dissolve, there is no real harm. However, when the cured thermosetting resin is baked, the solvent rapidly gasifies and the coating film rapidly shrinks, causing cracks. In the present invention, it is possible to apply a thermosetting resin without containing a solvent that causes cracks, and it is easy to obtain a smooth and dense carbon-coated graphite material that hardly generates cracks in the coating film during firing. it can.

  Firing in the embodiment of the present invention refers to a step of firing a graphite material in a non-oxidizing atmosphere. The firing temperature is not particularly limited, but is preferably 1000 ° C. or higher. When fired at a temperature of 1000 ° C. or higher, foreign elements other than carbon can be removed, crystal development can be promoted, and a densified film can be generated. A more desirable firing temperature is 1200 ° C. or higher. When calcined at a temperature of 1200 ° C. or higher, foreign elements can be further removed and the development of crystals can be promoted, so that a carbon-coated graphite material having few reaction active points and having corrosion resistance can be obtained. The baking step does not need to be performed in the entire temperature range in a non-oxidizing atmosphere, and it is desirable that the temperature is at least 600 ° C. or higher in a non-oxidizing atmosphere.

As described above, according to the manufacturing method of the embodiment of the present invention, it is possible to apply the carbon precursor without using a small amount of solvent or solvent, and the generation of gas during firing can be reduced, which is easy. In addition, a carbon-coated graphite material can be obtained.
Further, according to the production method of the present invention, a small amount of solvent or carbon precursor film can be formed. For this reason, the quantity of the solute to apply can be increased, and a dense carbon-coated graphite material can be obtained by a simple treatment.

A graphite material having a side of 10 mm is prepared, and electrostatic coating is performed on the graphite material. Is ET-10 manufactured by Ibiden Co., Ltd. Next, the graphite material is grounded and charged so that the graphite material side becomes the positive electrode. From the coating gun, a phenol resin, which is a powdery carbon precursor, is sprayed together with the airflow. The phenol resin used is Belpearl S899 manufactured by Air Water Co., Ltd. The average particle size of Bell Pearl S899 is 20 μm in powder form and is a B-stage phenolic resin. The painting gun is provided with a needle electrode, and a corona discharge is generated from the needle electrode toward the graphite material, and an electric field is generated.
The carbon precursor sprayed from the coating gun is charged by receiving negative and negative charges by passing through a portion where corona discharge is performed.

The carbon precursor is sprayed from the graphite material using a coating nozzle from a distance of 50 cm. In order to coat the entire surface, the graphite material is turned over and painted in two steps.
Next, the coated graphite material is fired. Firing is performed in two stages. The first stage is for the purpose of curing the carbon precursor, and the second stage is for the purpose of carbonizing the cured thermosetting resin. In the previous step, the carbon precursor is held in air at 120 ° C. for 1 hour. The temperature raising time is 20 ° C./min. After the previous step, the carbon-coated graphite material can be obtained by holding the graphite material at 2000 ° C. in a nitrogen atmosphere. The temperature is raised to 2000 ° C. at 600 ° C./hr.
In this example, since a carbon precursor not containing a solvent can be applied, foaming in the curing process can be suppressed, and the amount of gas generated in the carbonization process can be reduced. A film without unevenness and cracks can be easily formed on the surface of the graphite material.

1 Graphite Material 2a Carbon Precursor 2b Charged Carbon Precursor 3 Coating Gun 4 Needle Electrode 5 Electric Field

Claims (7)

An electrostatic coating process for forming a coating film by spraying a charged carbon precursor on the surface of the graphite material;
A firing step of firing the graphite material on which the coating film is formed;
A method for producing a carbon-coated graphite material, comprising:   2. The method for producing a carbon-coated graphite material according to claim 1, wherein the carbon precursor is powder, droplets, or a mixture thereof.   The method for producing a carbon-coated graphite material according to claim 2, wherein the carbon precursor is a powder.   The said carbon precursor contains a thermosetting resin, The manufacturing method of the carbon covering graphite material as described in any one of Claims 1-3 characterized by the above-mentioned.   The method for producing a carbon-coated graphite material according to claim 4, wherein the thermosetting resin is a B-stage thermosetting resin.   6. The method for producing a carbon-coated graphite material according to claim 5, wherein the thermosetting resin comprises one or more selected from a phenol resin, a furan resin, a copna resin, or a polyimide resin.   The method for producing the carbon-coated graphite material includes a curing step of curing the coating film after an electrostatic coating step, wherein the carbon-coated graphite material according to any one of claims 4 to 7 is used. Production method.

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