KR101691496B1 - Carbon-fiber Waste Reprocessing Method - Google Patents

Abstract

The present invention relates to a method for reprocessing waste carbon fiber, comprising: a pretreatment step of packing a waste carbon fiber pile into a cutting frame according to the present invention; A cutting step of cutting the waste carbon fiber pile packed in the cutting frame into a water jet in the pretreatment step; A dehydrating step of removing water remaining in the waste carbon fiber pile cut in the cutting step; And drying the waste carbon fiber pile from which the water has been removed in the dehydrating step; The time required for reprocessing the waste carbon fiber can be shortened and the cost for the reprocessing can be greatly reduced. Also, since water is used without using chemicals, Is disclosed.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a carbon fiber recycling method,

The present invention relates to a method of reprocessing waste carbon fiber, and more particularly, to a method of reprocessing waste carbon fiber, which can cut waste carbon fiber without failure in a reprocessing process for recycling waste carbon fiber .

Composites used in the fields of aerospace, automobile, industrial structural materials, and leisure industry, which have been attracting attention as the main industry in the 21st century, are being replaced by composite materials using new materials.

Composite materials using carbon fibers are attracting attention as composite materials using these new materials. Carbon fiber has excellent physical and chemical properties, but it is used in various fields because it is light in weight. For example, carbon fiber reinforced plastic (CFRP) is one fifth thinner than iron, but its strength is ten times stronger, and it is used in various fields as heat-resistant and impact-resistant material.

Thus, there is a problem that a large amount of energy and raw materials are required to manufacture carbon fibers having high utilization values due to their excellent characteristics. Therefore, much efforts and research have been made to develop a technique for recovering and reusing carbon fibers at the disposal stage.

The carbon fiber recovery technology that has been developed so far can be classified into a chemical method using acid and organic solvents, a thermal method of pyrolyzing resin, and a supercritical method. Among such prior arts are Korean Patent No. 10-1189436 entitled "Continuous Circulation Flow Reactor for Recycling Carbon Fiber of Lung Cf Alpi and Method Thereof", hereinafter referred to as Prior Art 1).

According to the prior art 1, a method of recovering a carbon fiber-reinforced plastic containing waste carbon fibers is disclosed, and the carbon fiber can be recovered for recycling using this prior art 1. Also, after using carbon fibers, carbon fibers which are short in length and can not be used anymore can also be recovered as carbon fibers which can be recycled.

As the waste carbon fiber thus recovered for recycling, there are a variety of carbon fiber recovered by the same method as the prior art 1, and the remaining carbon fiber discarded because the length and the like do not match with each other. However, since the lengths thereof are different from each other, A reprocessing process is required to clean the length of waste carbon fiber to be recycled.

Conventionally, the length of the waste carbon fiber is cut by using a cutting machine. However, the blade of the cutting machine can not be used for a long time, and it is very difficult to replace the blade at any time.

It is an object of the present invention to solve the above-mentioned problems of the prior art, and it is an object of the present invention to solve the above-mentioned problems of the prior art, And a method for reprocessing waste carbon fibers.

According to another aspect of the present invention, there is provided a method of reprocessing waste carbon fiber, comprising the steps of: pretreating a waste carbon fiber pile in a cutting frame; A cutting step of cutting the waste carbon fiber pile packed in the cutting frame into a water jet in the pretreatment step; A dehydrating step of removing water remaining in the waste carbon fiber pile cut in the cutting step; And drying the waste carbon fiber pile from which the water has been removed in the dehydrating step; May be another feature of the present invention.

Here, the pretreatment step may include: a washing step of washing and removing foreign matter from the waste carbon fiber pile; And a packing step of packing the waste carbon fiber pile washed in the cleaning step in the cutting frame; May be another feature of the present invention.

Further, the cleaning performed in the cleaning step may further include cleaning the fine dust of the carbon fiber or the vanishing agent present in the waste carbon fiber pile.

Further, the packing made in the packing step may be characterized in that the empty space in the waste carbon fiber pile is filled with water, and the water is filled in the cutting frame while applying pressure to the waste carbon fiber pile.

Here, the method may further include rinsing the waste carbon fiber pile cut in the cutting step.

Here, the material of the cutting frame may be plastic or wood.

The cutting performed in the cutting step is a feature of cutting the cutting frame and the waste carbon fiber pile so that cutting is performed on the cutting frame and the upper plate of the cutting frame is not separated from the cutting frame You may.

In the cutting step, the cutting frame and the waste carbon fiber pile are cut together so as not to intersect the cutting line formed while cutting the water jet, which is the path on the cutting frame that has gone through the cutting, .

Here, the dehydration in the dewatering step may be characterized in that the debris of the waste carbon fiber cut in the cutting step is contained in a net made of a net, and the dehydrated waste carbon fiber pile is dehydrated.

The method for reprocessing waste carbon fiber according to the present invention can reduce the time required for reprocessing waste carbon fibers by preventing the reprocessing process from being interrupted due to breakage of the blade of the cutting machine, There is an effect to be saved.

In addition, in the reprocessing, since water is used without using chemical agents, it does not cause harm to the human body, does not cause environmental pollution, is more environmentally friendly, and does not require cost related to environmental preservation have.

1 is a flowchart schematically showing a method for reprocessing waste carbon fiber according to an embodiment of the present invention.
2 is a perspective view schematically illustrating a method of cutting waste carbon fiber according to a method for reprocessing waste carbon fiber according to an embodiment of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

First, in explaining a waste carbon fiber treatment method according to an embodiment of the present invention, 'waste carbon fiber' basically refers to a single waste carbon fiber, but a plurality of strands or piles May also be used as generic names collectively. In order to facilitate understanding, a plurality of strands of waste carbon fiber may be more accurately described as a 'waste carbon fiber pile', and a waste strand of carbon fiber may be expressed as 'a waste carbon fiber pile' .

FIG. 1 is a flow chart schematically showing a method for reprocessing spent carbon fiber according to an embodiment of the present invention. FIG. 2 is a schematic view showing a method of cutting waste carbon fiber according to a method for treating spent carbon fiber according to an embodiment of the present invention. Fig.

Referring to FIGS. 1 and 2, a method for reprocessing waste carbon fiber according to an exemplary embodiment of the present invention includes a pretreatment step, a cutting step, a dehydrating step and a drying step, more preferably, . Hereinafter, each step will be described.

First, the pretreatment step is a step of packing a waste carbon fiber pile into the cutting frame 300 to cut the waste carbon fiber into a predetermined size.

This pre-processing step may include a cleaning step (S110) and a packing step (S120).

<< S110 >>

First, in the cleaning step S110, foreign substances (not shown) are removed from the waste carbon fiber pile 210 by washing the waste carbon fiber 210 or the waste carbon fiber pile 210. [

Washing is preferably carried out with water. During the washing of the waste carbon fiber 200 with water, water is drawn in between the waste carbon fibers 200, the waste carbon fiber pile 210 can be condensed and the volume can be reduced, and the waste carbon fibers 200 are bound together .

More preferably, the cleaning of the waste carbon fiber pile 210 may include washing the dust (not shown) or the dust of the waste carbon fiber 200 existing on the surface of the waste carbon fiber 200. That is, the waste carbon fiber pile 210 is washed to remove not only impurities but also the surfactant present on the surface of the waste carbon fiber 200.

Among toxic agents used in the production of waste carbon fiber (200), toxic substances harmful to the human body may be used. Therefore, removal thereof may improve the handling safety and the recyclability of waste carbon fiber desirable.

Washing can be done in various forms, but is preferably washed in soaking or washing in running water.

<< S120 >>

The packing step S120 following the cleaning step S110 is a step of packing the waste carbon fiber 200 or the waste carbon fiber dummy 210 washed in the cleaning step S110 into the cutting frame 300.

The cutting frame 300 serves to hold the waste carbon fiber 200 so that the waste carbon fiber 200 can be cut smoothly when cutting the waste carbon fiber 200 to a predetermined size. That is, the waste carbon fibers 200 are further bound by cutting the waste carbon fibers 200 before being cut by the water jet 100 to be described later, thereby further reducing the volume of the waste carbon fiber dummy 210. In the cutting step S130, ) To prevent it from bouncing or moving.

Here, the cutting frame 300 is not limited to a specific shape or size, and may have a shape as shown in FIG. However, it is preferable that a large number of waste carbon fiber 200 dummies 210 can be well-aligned and can serve as a mold capable of holding the carbon fiber 200 to be cut to a predetermined size.

The cutting frame 300 may be made of various materials but may be made of plastic or wood such as a polymer compound so that the cutting frame 300 and the waste carbon fiber 300 can be cut together by the waterjet 100 from the outside. .

An empty space, that is, a gap 250, exists between the waste carbon fiber 200 and the waste carbon fiber in the waste carbon fiber pile 210. It is preferable that the void 250, which is an empty space, is filled with water. As mentioned briefly above, when the water is used for cleaning in the ordinary cleaning step (S110), water is naturally filled in the gap (250). When the water penetrates and fills the gap 250, the condensing force or cohesion of the waste carbon fiber pile 300 is improved.

Then, the waste carbon fiber bundle 210 is packed in the cutting frame 300 by applying pressure to the waste carbon fiber bundles 200 to be densely packed.

Here, the size of the cutting frame 300 is not limited to a specific shape or size. However, it can be determined according to the design or process needs, and it is sufficient if the waste carbon fiber pile 210 can be packed in the cutting frame 300.

<< S130 >>

Next, in the cutting step S130, cutting is performed on the cutting frame 300, and the cutting frame 300 and the waste carbon fiber pile 210 are cut so that the top plate of the cutting frame 300 is not separated from the cutting frame 300 Cut it.

A cutting line 310 is formed by cutting the cutting frame 300 and the waste carbon fiber pile 210 together while the cutting line 310 is cut along the cutting frame 300 while the waterjet 100 is cutting. It is preferable to cut it.

When the waterjet 100 is cut and passed so that the cutting line 310 is not crossed, the upper plate of the cutting frame 300 can press the waste carbon fiber pile 210 while the waterjet is cut and passed.

However, when the cutting lines 310 intersect, some of the top plates may be separated from the cutting frame. In this case, it is difficult to hold the waste carbon fiber piles so that they are not shaken during cutting by waterjet, It is because. Of course, if the waterjet is completely cut off, the top plate is not necessary.

In FIG. 2, as an example, the cutting line 310 is schematically shown as being cut in an 'e' shape.

Since the cutting step S130 is cut by waterjet, it may be performed on the water tank as schematically shown in Fig.

<< S135 >>

The cutting step S130 may be followed by the dewatering step S140, but it is also preferable that the cutting step S130 is followed by the rinsing step S135. The rinsing step S135 rinses the waste carbon fiber pile 210 cut in the cutting step S130.

Rinsing is sufficient with water. Rinsing may be repeatedly performed one or more times.

For reference, the rinsing step (S135) need not necessarily be performed before the dewatering step (S140). If the rinsing step S135 is carried out before the dewatering after the cutting, the by-products such as minute residues (not shown) may be removed in the rinsing step S135 after the cutting step S130 and the dewatering step S140, It can be said that it is desirable.

<< S140 >>

In the dehydrating step S140, which may follow the cutting step S130 or the rinsing step S135, the waste carbon fiber 200 to the waste carbon fiber pile 210 cut in the cutting step S130 may be cut into a mesh bag (Not shown) and dehydrating the waste carbon fibers 200 to the waste carbon fiber dies 210 by using a dehydrator (not shown).

The waste carbon fiber 200 to the waste carbon fiber pile 210 may be dehydrated using a dehydrator.

<< S150 >>

The drying step S150 is a step of drying the waste carbon fiber 200 or the waste carbon fiber pile 210 from which water has been removed in the dehydration step S140. That is, the drying step (S150) is performed in order to sufficiently remove water that has not been completely removed in the dehydrating step (S140).

The drying of the waste carbon fiber 200 to the waste carbon fiber pile 210 in the drying step S150 may be performed by a known method. For example, it is possible to place it in a well-ventilated place with sunlight to dry it naturally.

After the cleaning step (S110) to the drying step (S150), the reprocessing of waste carbon fiber for recycling is completed. Such recycled waste carbon fibers are of a size and length that are easy to recycle and become a valuable resource that can be recycled and applied for various purposes.

As described above, the method of reprocessing waste carbon fiber according to the present invention does not interrupt the reprocessing process due to breakage of the blade of the cutting machine, thereby shortening the time required for reprocessing the waste carbon fiber. And the cost is also greatly reduced.

Further, in the reprocessing, since water is used without using chemicals, there is no problem of environmental pollution, and there is also an advantage that it is more environmentally friendly and it does not require cost related to environmental preservation.

While the present invention has been described in connection with what is presently considered to be practical exemplary embodiments, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, It is to be understood that the scope of the present invention is to be construed as being limited only by the embodiments, and the scope of the present invention should be understood as the following claims and their equivalents.

100: Waterjet 200: Waste carbon fiber
300: cutting frame 310: cutting line

Claims (9)

A pretreatment step of packing a waste carbon fiber pile into a cutting frame;
A cutting step of cutting the waste carbon fiber pile packed in the cutting frame into a water jet in the pretreatment step;
A dehydrating step of removing water remaining in the waste carbon fiber pile cut in the cutting step; And
A drying step of drying the waste carbon fiber pile from which the water has been removed in the dewatering step; Lt; / RTI &gt;
In the cutting step,
Cutting the cutting frame and the waste carbon fiber pile so that cutting is performed on the cutting frame and the upper plate of the cutting frame is not separated from the cutting frame. The method according to claim 1,
The pre-
A cleaning step of cleaning and removing foreign matters from the waste carbon fiber pile; And
A packing step of packing the waste carbon fiber pile washed in the cleaning step into the cutting frame; Wherein the method further comprises the steps of: 3. The method of claim 2,
In the cleaning step,
And washing the dust or the carbon fiber dust present in the waste carbon fiber pile. 3. The method of claim 2,
The packing made in the packing step comprises:
Wherein water is filled in the empty space in the waste carbon fiber pile and is packed in the cutting frame while applying pressure to the waste carbon fiber pile. The method according to claim 1,
And a rinsing step of rinsing the waste carbon fiber pile cut in the cutting step. The method according to claim 1,
Wherein the material of the cutting frame is plastic or wood. delete The method according to claim 1,
The cutting frame and the waste carbon fiber pile are cut together at the cutting step,
Wherein cutting is performed so that the cutting line formed while cutting the cutting line, that is, the path on the cutting frame that has been cut while the waterjet is cutting, is not crossed. The method according to claim 1,
In the dehydration step,
Wherein the waste carbon fiber pile cut in the cutting step is embedded in a net made of a net, and the waste carbon fiber pile is dewatered.

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