KR100371402B1 - Activated carbon fiber with modified porous characteristic and modifying method thereof - Google Patents

Abstract

The present invention relates to a method of modifying the pore characteristics of activated carbon fibers by changing the micropores of activated carbon fibers into mesopores through a catalytic gasification using a catalyst. In the present invention, a) adsorbing a catalyst to the activated carbon fiber; b) pretreatment of the activated carbon fibers to which the catalyst is adsorbed in a furnace; And c) oxidizing the pre-treated activated carbon fibers to change the fine pores of less than 20 microns in diameter into mesopores having a diameter of 20 microns or more by modifying the pore characteristics of the activated carbon fibers. This improves the mechanical strength and electrical conductivity of the activated carbon fibers, and in particular, can be used as an electrode material for ultra-high capacity capacitors with improved storage efficiency.

Description

Activated carbon fiber with modified pore properties and its modification method {ACTIVATED CARBON FIBER WITH MODIFIED POROUS CHARACTERISTIC AND MODIFYING METHOD THEREOF}

The present invention relates to an activated carbon fiber having a modified pore property and a method for modifying the same, and more particularly to mesopores of micropore of activated carbon fibers through catalytic gasification using a catalyst. To change the pore properties of activated carbon fibers.

Activated carbon fibers are spun from a polymer raw material such as a polyacrylonitrile (PAN) or phenolic resin, and the fibers are burned in an inert gas atmosphere such as nitrogen or argon to form carbon fibers, which are then heated at high temperature. It is prepared by activating with an oxidizing agent such as carbon dioxide. Activated carbon fiber prepared as described above is a porous material composed of fine pores of less than 20Å, characterized by a large specific surface area, using a large specific surface area of the electrode material of the ultra-high capacity capacitor (supercapacitor), adsorbent for removing odor or contaminants, Or as a carrier for a catalyst.

Such activated carbon fibers were produced in 1976 and are currently produced by Kuraray, Toyobo and Osaka Gas in Japan. The activated carbon fibers produced by these companies have different pore size distribution and pore characteristics depending on the activation conditions, but most of the pores are composed of fine pores with a radius of 10 mm or less.

Fig. 1 shows the pore size distribution of activated carbon fibers under the trade name CH700-20 manufactured by Curaray Co., and the specific surface area of CH700-20 occupies the total area, the area occupied by micropores and mesopores, and the mesopores occupy the total area. Table 1 shows the ratio of area. At this time, the pore size distribution shown in Figure 1 is expressed as the area ratio (dS / dR) to the radius (R) of the pore.

Table 1. Specific surface area of CH700-20 and the ratio between micropores and mesopores

Specific surface area (m ² / g) Total area Fine pores Heavy hole Medium hole / total area CH700-20 1614 1460 154 0.095

In this case, generally, the boundary separating the micropores and the mesopores is 20 mm in diameter. As shown in Table 1 and Figure 1, CH700-20 is composed of more than 90% of the fine pores. However, the micropores that occupy most of the activated carbon fibers have a problem that their application is limited when used as an electrode material, an adsorbent, a catalyst carrier, etc. of an ultra high capacity capacitor. This will be described taking the electrode material of the electric double layer capacitor as an example.

Supercapacitors are auxiliary energy storage devices that have emerged to compensate for the shortcomings of secondary cells, of which there is an electronic double-layer capacitor. An electric double layer capacitor consists of a current collector, an electrode, an electrolyte, and a separator, and an electrolyte is filled between two electrodes electrically separated from each other by the separator, and the current collector effectively stores or discharges charge on the electrode. Play a role. When (+) is applied to the activated carbon fiber electrode using the activated carbon fiber as the electrode material of the electric double layer capacitor, the (+) ions released from the electrolyte enter the pores of the activated carbon fiber to form a (+) layer. This is a principle in which charge is stored by forming a double layer together with the (-) layer formed at the interface of the activated carbon fibers.

At this time, if the pore size of the activated carbon fiber is less than 10 Å as shown in Fig. 1 or less than the size of the electrolyte ions, the electrolyte ions cannot enter the pores, there is a problem that the amount of storage capacity decreases.

Since the activated carbon fibers having mesopores larger than the micropores can be widely applied not only to electrode materials of ultra high capacity capacitors, but also to carriers of adsorbents or catalysts, a method of developing activated carbon fibers having mesopores is described. Recently, a lot of research has been conducted and the method has been proposed, but there is no technically established method so far.

The prior art, which is typically used, is a method of adding a catalyst or additive to a raw material before producing activated carbon fibers. This method is a method in which combustion occurs more actively around a catalyst, and a hollow hole is formed around the portion, or an additive which burns better than carbon is added to form the hollow hole in the portion.

However, in this prior art, since the catalyst or additive is added to the raw material, that is, before spinning and drawing the fiber, it is difficult to spin and pull the fiber, and the mechanical strength and electrical conductivity of the produced activated carbon fiber are lowered. There was a problem.

In addition, the electrical conductivity is poor, and in particular, the electrode material of the ultra-high capacity capacitor cannot be used, and even if used, there is a problem in that the efficiency as an electrode is very low.

The present invention has been made to solve the problems as described above, the object is to change the pores of the activated carbon fiber consisting mostly of fine pores to medium pores through the gasification reaction using a catalyst activated carbon fiber modified pore characteristics And a method for modifying the same.

FIG. 1 is a graph showing the size distribution versus the radius of pores present in activated carbon fibers under the trade name CH700-20 manufactured by Curaray.

2A to 2B are graphs showing temperature changes with time during the pretreatment and oxidation reactions.

3 is a graph showing the pore size distribution of activated carbon fibers with modified pore properties in accordance with the present invention along with a pore size distribution of CH700-20.

4 is a graph showing the pore size distribution of activated carbon fibers after the experiments 1 and 2, together with the pore size distribution of CH700-20.

5 is a graph showing the pore size distribution of activated carbon fibers after the experiments 1 and 3, together with the pore size distribution of CH700-20.

6 is a graph showing the pore size distribution of activated carbon fibers after the experiments 4 and 5, together with the pore size distribution of CH700-20.

FIG. 7 is a graph showing the pore size distribution of activated carbon fibers after experiments 6 and 7. FIG.

FIG. 8 is a graph showing pore size distribution of activated carbon fibers after experiments 8 to 10. FIG.

9 is a graph showing pore size distribution of activated carbon fibers after experiments 11 to 13. FIG.

FIG. 10 is a graph showing pore size distribution of activated carbon fibers after experiments 20 to 22. FIG.

FIG. 11 is a graph showing the pore size distribution of activated carbon fibers after experiments 24 to 26. FIG.

In order to achieve the object as described above, the method for modifying the pore properties of the activated carbon fiber according to the present invention comprises the steps of: a) adsorbing a catalyst to the activated carbon fiber; b) pretreatment of the activated carbon fibers to which the catalyst is adsorbed in a furnace; And c) oxidizing the pretreated activated carbon fiber, by which the fine pores of less than 20 mm in diameter of the activated carbon fibers are changed into mesopores having a diameter of 20 mm or more.

At this time, the precursor of the catalyst is preferably selected from the group consisting of cobalt chloride (CoCl ₂ ), cobalt acetate (Co (CH ₃ COO) ₂ ), cobalt nitrate (Co (NO ₃ ) ₂ ).

In addition, the step a) of adsorbing the catalyst to the activated carbon fibers, preferably impregnated the activated carbon fibers into the catalyst precursor solution, and then drying the activated carbon fibers impregnated with the catalyst.

The catalyst precursor solution is preferably an aqueous solution in which the precursor of the catalyst is dissolved in distilled water at a concentration of 0.001 to 1.0 M.

In addition, the impregnation temperature in the step of impregnating the activated carbon fiber into the catalyst precursor solution is preferably 80 ° C., and the impregnation time is within 24 hours.

In addition, in the step of drying the activated carbon fibers impregnated with the catalyst, the drying temperature is preferably 110 ° C. or higher and the drying time is 1 hour or more.

In the step b) of pretreating the activated carbon fibers adsorbed in the furnace in the furnace, it is preferable to inject gas containing carbon dioxide into the furnace, but inert gas, inert gas, and a mixture thereof.

In the step b) of pretreating the activated carbon fibers in the furnace, the furnace temperature is preferably 300 to 900 ° C., and the temperature is maintained within 100 minutes.

Moreover, it is preferable that the speed | rate which raises the temperature of the said furnace is 10 degree-C / min.

In the step c) of oxidizing the activated carbon fibers, it is preferable to inject air or oxygen mixed gas into the furnace and oxidize the activated carbon fibers while lowering the temperature raised in the pretreatment step.

In addition, in step c) of oxidizing the activated carbon fibers, air or oxygen mixed gas is injected into the furnace and the temperature raised in the pretreatment step is maintained within a range of 60 minutes to oxidize the activated carbon fibers and then inert. It is desirable to lower the temperature by injecting gas.

In addition, the oxygen mixed gas is preferably a mixed gas of oxygen and nitrogen.

In other words, the present invention uses the already prepared activated carbon fiber as a base material, below, an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

First, CH700-20 manufactured by Curaray Co., Ltd. is prepared as activated carbon fiber. Next, cobalt chloride (CoCl ₂ ) is dissolved in distilled water as a precursor of the cobalt catalyst to make 100 ml of 0.1M aqueous solution of CoCl ₂ , and 0.5 g of CH700-20 is added thereto and impregnated at 80 ° C. for 24 hours. The activated carbon fiber impregnated with the cobalt catalyst is dried at 130 ° C. for 2 hours.

Next, about 0.1 g of the dried activated carbon fiber was placed in a tube furnace, and the temperature was raised to 700 ° C. at a temperature rising rate of 10 ° C./min while flowing carbon dioxide into the tube furnace at a flow rate of about 0.5 L / min. The temperature is maintained for a minute to pretreat the activated carbon fiber with carbon dioxide. At this time, CoCl ₂ used as a precursor of the cobalt catalyst is thermally decomposed, and as a result, Cl ₂ is blown off and cobalt is combined with oxygen provided from carbon dioxide to form CoO having a valence of +2.

Next, the activated carbon fiber is oxidized while lowering the temperature by flowing air into the tube furnace at 1 L / min, and carbon dioxide reacts with oxygen to change carbon dioxide into a gaseous reaction where it blows heavy pores having a diameter of 20 mm or more in its place. Form. At this time there is variation in the above CoO Co ⁺² and Co ⁺³ is a spinel (spinel) structure coexisting Co ₃ O _4, Co ₃ O ₄ of spinel structure, such a gas-forming reaction described above with excellent efficiency of the catalyst This is going to be active.

At this time, the oxidation reaction may be carried out by maintaining the elevated temperature while flowing air for a certain time to oxidize, and then lowering the temperature by flowing an inert gas such as argon.

2A to 2B are graphs showing temperature changes with time during the pretreatment and oxidation reactions. Figure 2a shows a case where the oxidation reaction is carried out for d ₂ hours, which is higher than T _o , which is a constant temperature at which a temperature can be lowered by flowing air immediately after pretreating the temperature raised to T _p for d ₁ hour. Figure 2b is a case of pretreating the temperature raised to T _p for d ₁ hour, and then performing the oxidation reaction by maintaining the temperature at T _p temperature for d ₂ hours, and then lowering the temperature by flowing an inert gas such as argon .

Activated carbon fiber subjected to the oxidation reaction as described above measures the surface area and pore size distribution using nitrogen adsorption, and as a result of the measurement, the shape of the activated carbon fiber is first maintained as it is, CH700-20 shown in FIG. Unlike the pore size distribution of, the mesopores having a size of 40 ~ 80Å is formed, the area ratio by the mesopores to the total area is modified to 50% or more. In addition, the pore size distribution changed after the gasification reaction is shown in FIG. 3 along with the pore size distribution of CH700-20, and the specific surface area changed as a result of the gasification reaction is shown in Table 2 together with the case of CH700-20.

Table 2. Specific Surface Area of Activated Carbon Fiber and CH700-20 after Gasification

Specific surface area (m ² / g) Total area Fine pores Heavy hole Medium hole / total area After gasification reaction 1243 562 681 0.55 CH700-20 1614 1460 154 0.095

On the other hand, in order to determine the effect of the experimental conditions of the gasification reaction as described above on the modification of the pore characteristics, Experiment 1 to Experiment 26 were described as follows.

In Experiment 1, after impregnating a catalyst in the activated carbon fiber in the same manner as in the embodiment of the present invention described above, pretreatment was performed at 600 ° C. for 30 minutes, and a mixed gas composed of 5% oxygen and 95% nitrogen was prepared. While flowing, the temperature was maintained at 550 ° C. for 6 minutes, oxidized, and the temperature was lowered.

On the other hand, Experiment 2 performed pretreatment and oxidation reactions in the same manner as in Experiment 1 on the activated carbon fibers not impregnated with the catalyst. The experimental variable differences and the experimental results of the above Experiment 1 and Experiment 2 are shown in Table 3 below.

Table 3. Experimental Variable Differences and Results of Experiment 1 and Experiment 2

Use of catalyst Specific surface area (m ² / g) Total area Fine pores Heavy hole Medium hole / total area Experiment 1 Used 1560 822 738 0.47 Experiment 2 not used 1945 1757 188 0.097

4 shows the pore size distribution of activated carbon fibers after the experiments 1 and 2, together with the case of CH700-20. As shown in FIG. 4 and Table 3, when cobalt catalyst is present, 20 to 50 kV of mesopores were generated, and the proportion of mesopores in the total area of the activated carbon fibers was increased compared to the case without cobalt catalyst. Therefore, it can be seen from the experiments 1 and 2 that the gasification reaction using the cobalt catalyst modifies the pore characteristics of the activated carbon fibers.

Next, Experiment 3 is a case in which only the pretreatment is performed and the oxidation reaction is not performed in the same manner as in Experiment 1, and the difference between the experiment variables and the results of Experiment 1 and Experiment 3 are shown in Table 4 below.

Table 4. Experimental Variable Differences and Results of Experiment 1 and Experiment 3

Oxidation reaction Specific surface area (m ² / g) Total area Fine pores Heavy hole Medium hole / total area Experiment 1 box 1560 822 738 0.47 Experiment 3 Never 1587 1403 184 0.116

5 shows the pore size distribution of the activated carbon fibers after the experiment 3 is performed with the experiment 1 and the CH700-20. Comparing the results of Experiment 3 with Experiment 1, as shown in Fig. 5 and Table 4, the increase of the mesopores during the pretreatment hardly occurs, but after the pretreatment, the mesopores develop and the mesopores develop in the total area of the activated carbon fiber. The proportion of occupancy was greatly increased.

Next, in Experiment 4 and Experiment 5, the catalyst was impregnated in the same manner as in Experiment 1 using 0.15M aqueous solution of CoCl _2, and then pretreated for 30 minutes at 700 ° C. using carbon dioxide and argon gas, respectively. The temperature was lowered after oxidizing with air while maintaining C for 1 minute. The experimental variable differences and the experimental results of the experiments 4 and 5 are shown in Table 5 below.

Table 5. Experimental Variable Differences and Results of Experiment 4 and Experiment 5

Pretreatment gas Specific surface area (m ² / g) Total area Fine pores Heavy hole Medium hole / total area Experiment 4 carbon dioxide 1580 1058 522 0.33 Experiment 5 argon 1616 1208 408 0.25

6 shows the pore size distribution of activated carbon fibers after the experiments 4 and 5, together with the case of CH700-20. As shown in FIG. 6 and Table 5, in the case of Experiment 4 and Experiment 5, the mesopores developed. When the oxidation reaction is performed after pretreatment using a gas or inert gas with low reactivity, such as carbon dioxide, it can be seen that the formation of mesopores.

However, in the case of experiment 4 in which oxidation reaction by oxygen mixed gas was performed after pretreatment with a gas that can provide oxygen like carbon dioxide, the ratio of mesopores was large, whereas in pretreatment with inert gas without carbon dioxide as in experiment 5, oxidation In the case of the reaction, the area ratio of the mesopores was smaller than that of Experiment 4. From this, it can be seen that the use of a gas that can provide oxygen while having low reactivity, such as carbon dioxide, can effectively increase the area ratio of the mesopores.

Next, in Experiment 6, impregnated the catalyst in the same manner as in Experiment 1 using 0.15M aqueous solution of CoCl ₂ , and then pretreated by raising the temperature to 700 ℃ while flowing carbon dioxide at 0.5L / min, and maintained at that temperature for 30 minutes, Air was injected at a flow rate of 1 L / min to oxidize while lowering the temperature. On the other hand, in Experiment 7, the gasification reaction was performed while raising the temperature to 700 ° C. during the pretreatment with carbon dioxide and immediately lowering the temperature by injecting air without maintaining the temperature for 30 minutes. That is, Experiments 6 to 7 are experiments to determine the pore distribution change according to the change in pretreatment time, and the experimental variables and experimental results of Experiments 6 and 7 are shown in Table 6 below.

Table 6. Experimental Variable Differences and Results of Experiment 6 and Experiment 7

Pretreatment time Specific surface area (m ² / g) Total area Fine pores Heavy hole Medium hole / total area Experiment 6 0 min 2382 1551 831 0.35 Experiment 7 30 minutes 1741 1085 656 0.37

7 shows the results of experiments 6 and 7. As shown in FIG. 7 and Table 6, although the ratio of the area of the mesopores does not differ significantly even if the pretreatment time is changed, the small mesopores of 40 μs or less are generated when there is no pretreatment time. Large mesopores were formed.

Next, in Experiment 8 to Experiment 10, impregnated the catalyst in the same manner as in Experiment 1 using 0.15M aqueous solution of CoCl _2, and then pretreatment was performed for 30 minutes at 550, 600, 700 ℃ by changing the pretreatment temperature, respectively, Air was injected and oxidized while the temperature was lowered.

Table 7. Experimental Variable Difference and Experimental Results from Experiment 8 to Experiment 10

Pretreatment temperature Specific surface area (m ² / g) Total area Fine pores Heavy hole Medium hole / total area Experiment 8 550 ℃ 1679 1263 416 0.24 Experiment 9 600 ℃ 1503 1156 347 0.23 Experiment 10 700 ℃ 1812 1290 522 0.29

The results of the experiments 8 to 10 are shown in FIG. 8, and as shown in FIG. 8, the pore size distribution was different as the oxidation reaction temperature by air was changed with the change of pretreatment temperature. Using these results, it is possible to produce activated carbon fibers having mesopores of a desired size.

Next, in Experiments 11 to 13, the catalyst was impregnated in the same manner as in Experiment 1 using 0.1 M CoCl ₂ aqueous solution, followed by pretreatment at 500, 600, and 700 ° C. for 30 minutes, respectively. Was oxidized while flowing at 500 ° C. for 6 minutes and then cooled by argon to lower the temperature. The experimental variable differences and the experimental results of Experiments 11 to 13 are shown in Table 8 below.

Table 8. Experimental Variable Difference and Experimental Results from Experiment 11 to Experiment 13

Pretreatment temperature Specific surface area (m ² / g) Total area Fine pores Heavy hole Medium hole / total area Experiment 11 500 ℃ 1776 1110 666 0.37 Experiment 12 600 ℃ 1761 1201 560 0.32 Experiment 13 700 ℃ 1616 1050 566 0.35

As a result of experiments 11 to 13, as shown in FIG. 9, it can be seen that even if the pretreatment temperature is changed, if the oxidation reaction by the oxygen mixed gas occurs under the same conditions, similar pore size distributions are shown.

Next, in Experiments 14 to 18, impregnating the catalyst and pretreatment using 0.1 M aqueous solution of CoCl _{2 in the} same manner as in Experiment 1, and then flowing 500%, 550, 600, 650, 700 with 10% oxygen mixed gas. The mixture was kept at 占 폚 for 4 minutes to oxidize, and then cooled down while flowing Ar. The experimental variable differences and experimental results of the experiments 14 to 18 are shown in Table 9 below.

Table 9. Experimental Variable Difference and Experimental Results from Experiment 14 to Experiment 18

Pretreatment temperature Specific surface area (m ² / g) Total area Fine pores Heavy hole Medium hole / total area Experiment 14 550 ℃ 1844 1227 617 0.33 Experiment 15 550 ℃ 1918 1172 746 0.39 Experiment 16 600 ℃ 1989 1165 824 0.41 Experiment 17 650 ℃ 1904 1364 540 0.28 Experiment 18 700 ℃ 1751 1327 424 0.24

In Experiments 19 to 23, the catalyst was impregnated and subjected to pretreatment under the same conditions as in Experiment 1, and then oxidized by maintaining at 475, 500, 525, 550, and 575 ° C. for 6 minutes while flowing 5% oxygen gas. The temperature was lowered while flowing argon. The experimental variable differences and experimental results of the experiments 19 to 23 are shown in Table 10 below.

Table 10. Experimental Variable Difference and Experimental Results from Experiment 19 to Experiment 23

Oxidation temperature Specific surface area (m ² / g) Total area Fine pores Heavy hole Medium hole / total area Experiment 19 475 ℃ 1675 1017 658 0.39 Experiment 20 500 ℃ 1761 1201 560 0.32 Experiment 21 525 ℃ 1776 1055 721 0.40 Experiment 22 550 ℃ 1671 1238 433 0.26 Experiment 23 575 ℃ 1620 1210 410 0.25

The results of experiments 20 to 22 are shown in FIG. 10, and the pore size distribution is different depending on the temperature change during oxidation by oxygen mixed gas. Using these results, an activated carbon fiber having a medium pore of a desired size is manufactured. can do.

Next, in Experiments 24 to 26, the catalyst was impregnated and pretreated under the same conditions as in Experiment 1, and then oxidized by maintaining the temperature at 550 ° C. for 4, 6, and 10 minutes while flowing 5% oxygen gas. The temperature was lowered while shedding. The experimental variable differences and the experimental results of Experiments 24 to 26 are shown in Table 11 below.

Table 11. Experimental Variable Differences and Experimental Results

Oxidation time Specific surface area (m ² / g) Total area Fine pores Heavy hole Medium hole / total area Experiment 24 4 minutes 1587 1210 386 0.24 Experiment 25 6 minutes 1671 1238 433 0.26 Experiment 26 10 minutes 1761 1226 535 0.30

The results of Experiments 24 to 26 are shown in Fig. 11, and it can be seen that the longer the oxidation time, the more the ratio of the mesopores of the activated carbon fibers increases. Using these results, it is possible to produce activated carbon fibers having a desired area ratio of mesopores.

As described above, the experiments 1 to 26 which were conducted to examine the effect of the experimental conditions of the gasification reaction on the modification of the pore characteristics were described. Including experiments 1 to 26, the following experimental conditions were established by varying the impregnation concentration of the catalyst, the type of gas injected into the furnace during pretreatment, the pretreatment temperature and time, or the oxidation temperature and time. .

First, the cobalt precursor is water-soluble, and may use cobalt acetate (Co (CH ₃ COO) ₂ ) or cobalt nitrate (Co (NO ₃ ) ₂ ), etc., as well as CoCl ₂ mentioned above, and cobalt as described above. The concentration of the aqueous solution in which the precursor is dissolved in distilled water is appropriate if it is 0.001 to 1.0M.

The time for impregnating the activated carbon fiber into the cobalt precursor solution is within 24 hours, and the activated carbon fiber impregnated with the catalyst may be dried at 110 ° C or higher for 1 hour or more.

In the pretreatment, a gas or an inert gas capable of providing oxygen, including carbon dioxide, may be injected into the furnace, and the pretreatment may be performed by maintaining the temperature within a range of 100 minutes at 300 to 900 ° C.

After the pretreatment, the air or oxygen mixed gas may be oxidized while lowering the pretreatment temperature, or the argon may be oxidized by maintaining 300 to 900 ° C within 60 minutes while flowing the air or oxygen mixed gas. You can also lower the temperature while flowing.

And, by modifying the pore properties of the activated carbon fiber under the experimental conditions as described above, it is possible to obtain an activated carbon fiber having a medium pore of the desired size. For example, when activated carbon fiber is used as an electrode material for an ultra high capacity capacitor, the activated carbon fiber containing mesopores is preferable to micropores because the discharge time is faster than that containing micropores. According to the present invention it is possible to manufacture a capacitor having a desired discharge time by modifying the pore characteristics to a medium pore of the desired size.

As described above, in the method for modifying the pore properties of the activated carbon fiber according to the present invention, since the catalyst or the additive is not added to the polymer raw material in advance, the activated carbon fiber having the modified pore properties according to the present invention is modified according to the prior art. Compared with activated carbon fibers, the mechanical strength and the electrical conductivity are excellent.

In addition, due to the excellent electrical conductivity can be used as the electrode material of the particularly high-capacitance capacitor, there is an effect that the efficiency of the electrode material compared to the activated carbon fiber modified according to the prior art.

Claims (16)

In the method of modifying the activated carbon fiber, a) adsorbing a catalyst to activated carbon fibers; b) pretreatment of the activated carbon fibers to which the catalyst is adsorbed in a furnace; And c) oxidizing the pretreated activated carbon fibers Method for modifying the pore characteristics of activated carbon fiber to change the fine pores of less than 20Å diameter of the activated carbon fiber to the mesopores more than 20Å diameter by the method comprising a. The method of claim 1, wherein the precursor of the catalyst is a water soluble cobalt precursor. The activated carbon of claim 2, wherein the water-soluble cobalt precursor is selected from the group consisting of cobalt chloride (CoCl ₂ ), cobalt acetate (Co (CH ₃ COO) ₂ ), and cobalt nitrate (Co (NO ₃ ) ₂ ). Method of modifying the pore properties of fibers. The activated carbon fiber of claim 1, wherein in the step b) of pretreating the activated carbon fiber adsorbed by the catalyst in the furnace, gas, an inert gas, and a mixture thereof, including carbon dioxide, are injected into the furnace. Method of modifying the pore characteristics. The activity of claim 1, wherein the step a) of adsorbing the catalyst to the activated carbon fibers comprises the step of impregnating the activated carbon fibers into a catalyst precursor solution and then drying the activated carbon fibers impregnated with the catalyst. Method of modifying the pore properties of carbon fiber. The method of claim 5, wherein the catalyst precursor solution is an aqueous solution in which the precursor of the catalyst is dissolved in distilled water at a concentration of 0.001 to 1.0 M. 7. The method of modifying pore properties of activated carbon fibers according to claim 5, wherein the impregnation temperature in the step of impregnating the activated carbon fibers in the catalyst precursor solution is 80 ° C and the impregnation time is within 24 hours. The method of modifying pore characteristics of activated carbon fibers according to claim 5, wherein the drying temperature of the activated carbon fibers impregnated with the catalyst is at least 110 ° C. and the drying time is at least 1 hour. The method of modifying pore characteristics of activated carbon fibers according to claim 1, wherein the temperature of the furnace in the step b) of pretreating the activated carbon fibers in the furnace is 300 to 900 ° C., and the temperature is maintained within a range of 100 minutes. 10. The method of claim 9, wherein the rate of raising the temperature of the furnace is 10 ° C / min. The method of claim 1, wherein in the step c) of oxidizing the activated carbon fibers, injecting air or oxygen mixture gas into the furnace and lowering the temperature raised in the pretreatment step to oxidize the activated carbon fibers. Method of modifying pore properties. The method of claim 1, wherein in step c) of oxidizing the activated carbon fibers, air or oxygen mixed gas is injected into the furnace and the temperature raised in the pretreatment step is maintained within a range of 60 minutes to maintain the activated carbon fibers. A method of modifying the pore properties of activated carbon fibers by lowering the temperature by injecting an inert gas after oxidation. The method according to claim 11 or 12, wherein the oxygen mixed gas is a mixed gas of oxygen and nitrogen. In a method of modifying activated carbon fibers for electrode materials of ultra high capacity capacitors, Adsorbing a catalyst to activated carbon fibers; Pretreatment of the activated carbon fibers adsorbed by the catalyst in a furnace; And A method of modifying the pore characteristics of activated carbon fibers for electrode materials of an ultra-high capacity capacitor by changing the fine pores of less than 20Å diameter of the activated carbon fibers to 20 or more medium diameter by the method comprising the step of oxidizing the pre-treated activated carbon fibers. Adsorbing a catalyst to activated carbon fibers; Pretreatment of the activated carbon fibers adsorbed by the catalyst in a furnace; And Oxidizing the pretreated activated carbon fibers Activated carbon fiber modified pore properties are produced by a method comprising a. Adsorbing a catalyst to activated carbon fibers; Pretreatment of the activated carbon fibers adsorbed by the catalyst in a furnace; And Oxidizing the pretreated activated carbon fibers Activated carbon fiber for the electrode material of the ultra-high capacity capacitor is modified by the pore properties produced by a method comprising a.