JP3492630B2 - Method for transporting vapor-grown carbon fiber and method for heat treatment - Google Patents

Description

Detailed Description of the Invention

[0001]

TECHNICAL FIELD The present invention relates to a method for transporting vapor-grown carbon fibers and a method for heat treatment, and more specifically,
Vapor grown carbon fibers with low bulk density can be efficiently and easily transported, and the method for transporting vapor grown carbon fibers does not require compression molding before heat treatment, and heat treatment can be performed by a simple process. Regarding the method.

[0002]

2. Description of the Related Art A vapor-grown carbon fiber is prepared by introducing a catalyst, a carrier gas and an organic compound into a reaction furnace to form an organic compound.
It is generated by thermal decomposition at about 00 ° C to 1300 ° C. As a general method for producing vapor grown carbon fiber,
A method in which a transition metal compound such as ferrocene is vaporized and introduced into a reaction furnace (pyrolysis furnace) and fine particles of the transition metal are generated and used as a seed (Japanese Patent Application Laid-Open No. 60-54998) or a transition metal such as iron is used. A method for producing seeds by vaporizing them directly in a pyrolysis furnace (JP-A-61-291497).
Or a transition metal compound such as ferrocene is dispersed or melted in a liquid organic compound and sprayed in a reaction furnace to produce a seed (JP-A-58-18061).
No. 5).

The vapor-grown carbon fibers obtained by these methods include, for example, the residue of unused catalyst in addition to the vapor-grown carbon fibers,
It is a crude fiber containing unreacted organic matter, non-fiber carbide, and tar content.

4 to remove non-fibrous material from crude fibers
Heat treatment is performed at 00 ° C to 1200 ° C, and then,
2000 to graphitize vapor grown carbon fiber
Heat treatment is performed at 3000 ° C.

As one of the heat treatment methods, there is a batch type method in which the crude fiber taken out from the reaction furnace is put in a graphite crucible and heat-treated in the two-stage heat treatment furnaces having different temperatures. In this case, the work of introducing the crude fiber into the crucible and the work of putting the crucible in the heat treatment furnace depend on one operator, and it is not possible to work continuously, which is not suitable for mass production.

Another heat treatment method is disclosed in Japanese Patent Application Laid-Open No. 8-60.
As described in Japanese Patent Application Laid-Open No. 444/844 and Japanese Patent Application Laid-Open No. 8-60446, the crude fiber taken out from the reaction furnace is mechanically compressed to form a molded body, and the molded body is conveyed on a conveyor in two stages having different temperatures. There is a continuous method in which the material is transferred to the heat treatment furnace and heat treated. However, in the case of this continuous method, there is a drawback that the pressure molding treatment of the fiber and the crushing and classification treatment of the fiber after the heat treatment are required, the process becomes complicated and the equipment cost is increased. Further, there is a drawback that the fibers are broken during the crushing process and the uniformity of the fibers is impaired.

Further, since the crude fiber is thin and has a low bulk density, when it is conveyed by a conveyor or the like without being compressed, problems such as mixing of impurities, adhesion of the crude fiber and clogging occur. Further, as the bulk of the crude fiber becomes large, a large heat treatment furnace is required. Furthermore, since heat energy is consumed for heating the gas portion between the crude fibers, the heating efficiency at the time of heat treatment is poor, and energy loss is large.

[0008]

SUMMARY OF THE INVENTION It is therefore an object of the present invention to provide a vapor growth carbon fiber conveying method capable of efficiently and easily conveying vapor growth carbon fibers having a low bulk density. .

Further, the present invention provides a heat treatment method for vapor-grown carbon fibers, which does not require pressure molding treatment before heat treatment, crushing and classification treatment after heat treatment, and has a simple process, and has low equipment cost and operation cost. The purpose is to provide.

[0010]

Means for Solving the Problems The means of the present invention to solve the above problem is generated in the reactor, the vapor-grown carbon fibers discharged from the discharge port of the reactor, the vapor
A method of transporting vapor-grown carbon fibers, characterized in that it is collected by a striation that moves obliquely with respect to the discharge direction of carbon fibers, and another means of the present invention is produced in a reaction furnace, The vapor growth carbon fiber discharged from the outlet of the reaction furnace,
A heat treatment method for vapor grown carbon fibers, characterized in that the vapor-grown carbon fibers are collected by a strip that moves obliquely with respect to the discharge direction and conveyed to a heat treatment furnace. The heat treatment method for vapor-grown carbon fiber according to claim 2, characterized in that the strips are made of a substance that does not contain oxygen atoms in its composition and has heat resistance to a heat treatment temperature. Another means of the present invention is the heat treatment method for vapor-grown carbon fiber according to claim 2 or 3, wherein the strip is a carbon fiber. The heat treatment of the vapor grown carbon fiber according to any one of claims 2 to 4, wherein a moving bed for recovering the vapor grown carbon fiber desorbed from the strip is provided in the heat treatment furnace. Is the way.

[0011]

DESCRIPTION OF THE PREFERRED EMBODIMENTS FIG. 1 shows a schematic view of a heat treatment apparatus for vapor-grown carbon fibers which is an embodiment of the present invention. The heat treatment apparatus includes a conveyance unit 20 that conveys the crude fibers of the vapor-grown carbon fibers produced in the reactor 1 to the heat treatment unit, a heat treatment unit 30 that heat treats the crude fibers, and a vaporized carbon fiber graphitized by the heat treatment. And a recovery unit 40.

The reaction furnace 1 is a suction port which is a discharge port for discharging the raw material and carrier gas supply ports 5, 6 and a reaction region 2 heated to a predetermined temperature and the generated crude fiber to the outside of the reaction furnace 1. With tube 3.

The carrying section 20 is provided with a carrying thread 21 which is a filament.
And a reel 22 around which the transport yarn 21 is wound, and the transport yarn 2
It has a driving roller 23 which is a feeding device for moving 1 and non-driving rollers 24 to 27. Carbon fiber, for example, is used as the material of the conveying yarn 21. The non-driving rollers 24 to 27 are arranged so that the conveying yarn 21 sent out from the reel 22 passes through the vapor growth carbon fiber collecting region 4 located near the outlet of the suction pipe 3. In the collection area 4, the conveying yarn 21 is arranged so as to move obliquely so that the conveying yarn 21 comes into contact with the crude fiber discharged from the suction pipe 3 at a constant angle. The conveying yarn 21 that has passed through the collecting region 4 is further sent into the heat treatment furnace by the drive roller 44, and finally wound up by a winding device (not shown).

The heat treatment section 30 is provided with a heat treatment furnace 31 for removing organic compounds which are unburned components and a graphite molding heat treatment furnace 32. The heat treatment furnaces 31 and 32 are provided with heaters 33, 34, 35, 36 which are heating means in such a manner that the conveying yarn 21 passing through the furnaces is vertically sandwiched. The heat treatment furnace 31 is, for example, 400 ° C. to 120 ° C.
The heat treatment furnace 32 is heated to 0 ° C.
Heat to 3000 ° C.

The collecting section 40 has a nozzle 41 for separating the vapor-grown carbon fibers adhering to the carrying yarn 21 from the carrying yarn 21, and a collecting container 42 for containing the separated vapor-grown carbon fibers. It has a moving tray 43 which is a moving bed provided in the heat treatment furnaces 31 and 32. In the nozzle 41,
An opening having a diameter similar to that of the carrying yarn 21 is provided, and when the carrying yarn 21 passes through this opening, the vapor-grown carbon fibers attached to the surface of the carrying yarn 21 are separated from the carrying yarn 21. It The moving tray 43 collects the vapor-grown carbon fibers detached from the transport yarn 21 while passing through the heat treatment furnaces 31 and 32. The moving tray 43 is composed of a ring-shaped belt connecting plate-like pieces, and is circulated in the heat treatment furnace by a driving roller 44. The moving tray 43 is made of a material having excellent heat resistance and containing no oxygen, for example, graphite.

The heat treatment of the vapor grown carbon fiber using the above heat treatment apparatus is performed as follows.

Raw material supply port 5 provided in the upper part of the reactor 1.
The raw material and the carrier gas are introduced from the carrier gas supply port 6, and the crude fiber 7 of vapor grown carbon fiber is generated in the reaction region 2. Here, for example, benzene is used as the raw material, and as the carrier gas, for example,
Non-oxidizing argon gas is used. As a catalyst,
For example, ferrocene is used. The crude fiber 7 vapor-grown in the reaction region 2 is discharged to the outside of the reaction furnace 1 through the suction pipe 3.

The crude fiber 7 discharged from the suction pipe 3 is
It is collected by the transporting yarn 21 provided in the collecting area 4. Since the crude fiber 7 discharged from the suction pipe 3 contains unburned hydrocarbon components, the crude fiber 7 adheres to the transport yarn 21 without scattering in the collection area 4,
It can be easily collected.

In the collection area 4, the crude fibers 7 discharged from the suction pipe 3 are discharged while being distributed in the range of the central diameter a depending on the size of the suction pipe 3 as shown in FIG. The conveying yarn 21 moves obliquely across the flow of the discharged crude fiber 7 and collects the crude fiber 7. In order to efficiently collect the crude fiber 7, as shown in FIG.
It is preferable to arrange a plurality of conveying yarns 21 in a band shape so as to have a width equal to or larger than the central diameter a. In this case, the band-shaped carrier yarn 29 is wider than the distribution region 28 of the coarse fiber 7 having the center diameter a, and therefore, it can be collected without leakage.

Further, it is desirable that the angle θ ₁ formed by the carrying yarn 21 and the horizontal plane be the angle of repose of the coarse fiber 7. The angle of repose, but is that the angle theta _r between the free surface and the horizontal plane of the powder in case of depositing the powder as shown in FIG. 3, the transport thread and the angle theta ₁ is angle of repose 21
In addition, there is an advantage that more crude fibers 7 can be collected. On the other hand, when the angle θ _{1 is set} to an angle of repose or more, the coarse fiber 7 slips off from the transport yarn 21, and the coarse fiber 7 is unevenly attached to the transport yarn 21 located in the lower part of the collection area 4. Therefore, it is not preferable. Further, when the conveying yarn 21 is moved horizontally across the flow of the crude fiber 7 without making an angle to the conveying yarn 21, the conveying yarn 21 is dispersed by the reaction force due to the flow of the crude fiber 7. It is not desirable because it will end up.

In the collecting area 4, the transporting yarn 21 to which the crude fiber 7 is attached is then sent to the heat treatment furnace 31 and the unburned components in the crude fiber 7 are removed. Then, the yarn for transport 2
1 is sent to the heat treatment furnace 32, and a graphite phase is formed. At this time, the catalyst particles remaining in the crude fiber 7 are also evaporated and removed, and the crude fiber 7 becomes a vapor growth carbon fiber composed of only carbon.

The vapor grown carbon fiber 7 is dissociated from the conveying yarn 21 by the nozzle 41 of the recovery section 40 provided near the outlet of the heat treatment furnace 32 and recovered in the recovery container 42.
In the present invention, unlike the conventional compression-type heat treatment method, since the crushing treatment of the vapor-grown carbon fiber after the heat treatment is not required, the uniformity of the vapor-grown carbon fiber can be improved by breaking the fiber during crushing. It is not damaged.

The coarse fibers 7 separated from the conveying yarn 21 while passing through the heat treating furnace 31 or 32 are accumulated on the moving tray 43 and move in the heat treating furnace in the same manner as the conveying yarn 21. The crude fibers 7 on the moving tray 43 are also graphitized by removing unburned components by heat treatment. Moving saucer 4
The vapor-grown carbon fibers 7 graphitized on 3 are also collected in the collection container 42 located at the end of the moving tray 43. A scraping member for scraping off the vapor-grown carbon fiber 7, for example, a scrubber may be provided at the end of the moving tray. By providing such a moving tray, vapor-grown carbon fibers can be efficiently collected without waste.

In the present invention, the strip for carrying the crude fiber is a heat-resistant material that is neither deformed nor melted at the heat treatment temperature. Furthermore, in the heat treatment furnace, Any material can be used as long as it is a noncombustible substance that does not cause an oxidation reaction with the vapor grown carbon fiber. To be the above non-combustible substance,
Specifically, it is required that no oxygen atom is contained. Examples of the material suitable for the strip include carbon fiber.

The thickness of the strip can be appropriately selected according to the strength and elasticity of the material. Preferably 0.1-5.
It is 0 mm. Further, the filament may be a single filament or a twisted yarn in which filaments are twisted together.

The effect of the present invention can be achieved with only one filament, but it is preferable to use a plurality of filaments in order to efficiently convey the crude fiber. For example, as shown in FIG. 4, the strips may be arranged in a strip shape with a certain space therebetween, or the strips may be arranged closely without providing a space. The width of the band of strips is determined by the center diameter a of the distribution of the crude fibers discharged from the suction tube 3 of the reaction furnace 1, and the size of the heat treatment furnace can be determined based on the width. Therefore, the internal space of the heat treatment furnace for passing the bundle of strips may be about the same as the center diameter a of the distribution of the crude fibers discharged from the suction pipe 3, and the heat treatment furnace itself can be downsized. it can.

The heat treatment furnace may be made of a heat resistant material, and for example, a carbon material such as graphite can be used. The heating means of the heat treatment furnace may be one that is usually used for heating an object, and may be, for example, an external heating type heating means using electricity or high temperature gas or a direct heating type means using high temperature gas. Although the heating temperature varies depending on the purpose, for example, when the purpose is to remove unburned components, 400
C. to 1200.degree. C., and 2000 to 3000.degree. C. for the purpose of graphitizing the vapor grown carbon fiber.

When oxygen gas is present in the heat treatment furnace, the reaction between the crude fiber and oxygen gas occurs at a heating temperature of 500 ° C. or higher, particularly 1000 ° C. or higher. Is filled with a non-oxidizing gas to remove oxygen gas. Examples of the non-oxidizing gas include nitrogen, helium, argon, xenon, and krypton. Therefore, the heat treatment furnace is provided with a mechanism for introducing and discharging the non-oxidizing gas. Further, a discharge mechanism for discharging non-combustible components generated when the crude fiber is heated is provided.

The moving bed provided in the heat treatment furnace is heat-resistant to the heat treatment temperature and can receive vapor-grown carbon fibers desorbed from the filaments thereon and convey it outside the heat treatment furnace to collect it. Any shape and material may be used. Ceramics are particularly preferable as the material.

Further, the heat treatment method of the present invention can be carried out under any reaction condition as long as it is a reaction furnace for carrying out a vapor phase growth reaction.
It can be applied to any reactor.

[0031]

According to the present invention, it is possible to provide a method for transporting vapor-grown carbon fibers which can efficiently and easily transport vapor-grown carbon fibers having a low bulk density.

Further, according to the present invention, the pressure forming treatment before the heat treatment and the crushing and the classification treatment after the heat treatment are not necessary, and the process is simple, and the equipment cost and the operation cost are low. A heat treatment method can be provided.

Further, according to the present invention, it is possible to avoid contact between the vapor-grown carbon fiber and other than the strip, and it is possible to prevent impurities from being mixed into the vapor-grown carbon fiber.

Further, according to the present invention, since there is no crushing treatment after the heat treatment, the heat treatment does not impair the uniformity of the vapor grown carbon fiber.

[Brief description of drawings]

FIG. 1 is a schematic view of a heat treatment apparatus for vapor-grown carbon fibers, which is an embodiment of the present invention.

FIG. 2 is an enlarged view of a collection area in the heat treatment apparatus of FIG.

FIG. 3 is an explanatory diagram of an angle of repose.

FIG. 4 is a perspective view of a collection region in a heat treatment apparatus which is another embodiment of the present invention.

[Explanation of symbols]

1 Reactor 2 reaction area 3 Suction tube 4 Collection area 5 Raw material supply port 6 Carrier gas supply port 7 crude fiber 20 Transport section 21 Transport yarn 22 reels 23 Drive roller 24, 25, 26, 27 rollers 28 Distribution area 29 Band-shaped transport yarn 30 heat treatment department 31 heat treatment furnace 32 heat treatment furnace 33, 34, 35, 36 heaters 40 Collection Department 41 nozzles 42 Collection container 43 Moving saucer 44 drive roller

Continuation of front page (58) Fields surveyed (Int.Cl. ⁷ , DB name) D01F 9/08-9/32 C01B 31/00-31/36

Claims (5)

(57) [Claims] 1. A generated in the reactor, the vapor-grown carbon fibers discharged from the discharge port of the reactor, the vapor-grown carbon
A method for transporting vapor-grown carbon fibers, characterized in that the fibers are collected by striations that move obliquely with respect to the discharge direction of the fibers. 2. A generated in the reactor, the vapor-grown carbon fibers discharged from the discharge port of the reactor, the vapor-grown carbon
It is collected by the striations that move diagonally with respect to the fiber discharge direction ,
A heat treatment method for vapor-grown carbon fibers, characterized by transporting to a heat treatment furnace. 3. The composition does not contain oxygen atoms in the composition,
The heat treatment method for vapor grown carbon fiber according to claim 2, wherein the heat treatment method comprises a substance having heat resistance to a heat treatment temperature. 4. The heat treatment method for vapor grown carbon fiber according to claim 2, wherein the filament is carbon fiber. 5. The vapor phase growth according to claim 2, further comprising a moving bed for recovering the vapor growth carbon fibers desorbed from the strip in the heat treatment furnace. Carbon fiber heat treatment method.