KR20200022702A - Method for preparing graphene-activated carbon composite and graphene-activated carbon composite prepared by the same - Google Patents

Abstract

Provided is a method for preparing a graphene-activated carbon composite, comprising the steps of: preparing graphene oxide; preparing a spray solution by dispersing activated carbons and graphene oxide in a solvent; spraying the spray solution with droplets; and preparing a graphene-activated carbon composite comprising activated carbons coated with a graphene layer by applying heat to the droplets. The graphene-activated carbon composite can exhibit excellent electrical performance while showing an equivalent or higher specific surface area value compared to conventional activated carbons.

Description

FIELD OF THE INVENTION AND METHOD OF MANUFACTURING GRAPHINE-ACTIVE CARBON COMPOSITES

The present invention relates to a method for producing a new graphene-activated carbon composite and a graphene-activated carbon composite produced thereby. More particularly, the present invention relates to a method for producing a graphene-activated carbon composite having a reduced surface resistance and a graphene-activated carbon composite produced thereby.

Due to the depletion of fossil fuels, interest in renewable energy such as wind power, tidal power and solar power, which is sustainable and free of environmental pollution, is increasing. Since these renewable energy generation time and the amount of power generated is not constant, but a large amount of power generation instantaneously, research on energy storage devices for efficiently storing such energy is concentrated. Among them, supercapacitors and secondary batteries are emerging as alternatives to solve these problems.

Supercapacitors (EDLC) can store and take out large amounts of energy quickly, have higher output density than secondary batteries, can be used semi-permanently, and have stable characteristics because they do not use chemical reactions. It can be applied as a mobile phone, a hybrid car, a large-capacity power assist and storage device, and is attracting attention as a storage device such as solar, wind, and hydrogen fuel cells, which are eco-friendly and renewable energy. Such supercapacitors generally have components such as electrolyte membranes and electrodes, porous membranes and other gaskets and metal caps, which are located between the two electrodes to insulate and prevent short-circuits and allow only conduction of ions. In order to manufacture supercapacitor electrodes, porous carbon materials (activated carbon (AC), carbon fiber (CF), carbon nanofiber (CNF), carbon nanotube (CNT), graphene, etc.) capable of storing charges are mainly used as active materials. The electrode is manufactured by mixing the active material, the binder, and the conductive material. Most of the active materials currently applied to mass-produced supercapacitors use activated carbon having a low specific surface area and a high specific surface area. However, since activated carbon is manufactured on the basis of amorphous carbon, it is necessary to use a material such as a conductive material when manufacturing an electrode due to its low electrical conductivity value. There is a falling problem.

Lithium secondary batteries have been studied a lot to apply them as a power source for electric vehicles. Graphite is mostly used as a negative electrode active material of lithium secondary batteries for automobiles, and exhibits a high discharge voltage of 3.6V, which is the most widely used for ensuring high energy density of lithium secondary batteries and high life characteristics of secondary batteries with excellent reversibility. . However, graphite has a problem in that energy input / output characteristics are inferior, and in particular, low temperature output characteristics are insufficient. In addition, about 10% of the volume change of graphite occurs during charging and discharging, thereby adversely affecting the bonding strength between the current collector and the mixture layer, thereby degrading the lifespan of the battery. In order to solve this problem, non-graphitizable carbon in which micropores are developed has been proposed and used in part. Non-graphitizable carbon is a structure in which lithium ions are stored and released in a number of pores, and there is almost no volume expansion during charging and discharging of lithium ions, so the battery has excellent life characteristics. It is known to be excellent in output characteristics because it can be stored and released. However, there is a disadvantage that the initial efficiency is low, and the amount of lithium consumed irreversibly is large. This irreversible occurrence is due to the decomposition of the electrolyte at the surface of the electrode during charging to generate a solid electrolyte interphase (SEI), which is a surface coating, and the discharge of lithium stored in the carbon particles during charging. Sometimes it is due to not being able to. The more problematic of these is the former case, and the formation of the surface coating is known to be a major irreversible cause.

Accordingly, there is a demand for development of a material for a composite electrode active material that can exhibit excellent electrical conductivity and electrode capacity when used in an electrode without changing the properties of the basic active material as a material of the composite electrode active material.

Republic of Korea Patent Publication 10-1591264

Embodiments of the present invention to provide a method for producing a graphene-activated carbon composite.

Another embodiment of the present invention to provide a graphene-activated carbon composite prepared by the method for producing a graphene-activated carbon composite.

Another embodiment of the present invention to provide a supercapacitor and a lithium ion battery comprising the graphene-activated carbon composite.

In exemplary embodiments of the present invention, a graphene-activated carbon composite including an activated carbon as a core and a graphene-activated carbon composite including a graphene layer as a shell, a supercapacitor including the same, and an electrical device such as a lithium ion battery To provide.

In another exemplary embodiment of the present invention, preparing a graphene oxide; Dispersing activated carbon and the graphene oxide in a solvent to prepare a spray solution; Spraying the spray solution into droplets; And heating the droplets to produce a graphene-activated carbon composite including activated carbon coated with a graphene layer.

Graphene-activated carbon composite according to exemplary embodiments of the present invention may be prepared by a droplet spraying process, and may exhibit excellent electrical performance while showing equivalent to high specific surface area values compared to general activated carbon. Thereby, it can be used widely as an active material of various electrodes.

In addition, the graphene-activated carbon composite is prepared through a droplet spray process that is a mass-produced process. Accordingly, graphene-activated carbon composites can be easily produced.

1 is a flow chart showing a method for producing a graphene-activated carbon composite according to an embodiment of the present invention.
Figure 2a and 2b is a differential scanning microscope (SEM) of the graphene-activated carbon composite (Fig. 2a) and activated carbon (Fig. 2b) according to an embodiment of the present invention, respectively.
Figure 3 is a graph of the powder resistance of the graphene-activated carbon composite according to an embodiment of the present invention, it can be seen that exhibits a resistance reduction characteristic.
4A and 4B are graphs showing electrical characteristics of graphene-activated carbon composites and activated carbons according to an embodiment of the present invention. FIG. 4A is a graph showing characteristics of current capacity according to current density. It is a graph showing the retention change.
5 is a graph showing the charging and discharging results of the lithium secondary battery manufactured to include each of the graphene-activated carbon composite and the activated carbon according to the embodiment of the present invention.
6A and 6B are graphs illustrating 100 cycle characteristics (6a), capacity retention rate, and coulombic efficiency (6b) of a lithium secondary battery manufactured to include graphene-activated carbon composites and activated carbon, respectively, according to an embodiment of the present invention.
7 is a graph showing the discharge capacity according to the current density of the lithium secondary battery manufactured to include a graphene-activated carbon composite according to an embodiment of the present invention.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

The embodiments of the present invention disclosed in the text are illustrated for illustrative purposes only, and the embodiments of the present invention may be embodied in various forms and should not be construed as being limited to the embodiments described in the text. .

The present invention may be modified in various ways and may have various forms, and the embodiments are not intended to limit the present invention to the specific disclosed forms, and all changes, equivalents, and substitutes included in the spirit and technical scope of the present invention. It will be understood to include.

Hereinafter, the present invention will be described in more detail with reference to Examples. These examples are only for illustrating the present invention, it will be apparent to those skilled in the art that the scope of the present invention is not to be construed as limited by these examples.

Graphene -Production method of activated carbon composite

In exemplary embodiments of the present invention, a method for preparing a graphene-activated carbon composite is provided. According to the manufacturing method, it is possible to produce a graphene-activated carbon composite having reduced electric resistance value by a simpler and simpler method.

1 is a flowchart illustrating a method of preparing the graphene-activated carbon composite. Hereinafter, each step will be described in detail with reference to FIG. 1.

First, graphene oxide is prepared (S10).

In an exemplary embodiment, the graphene oxide may be prepared through a Cotter-Taylor flow reactor.

In one embodiment, the graphene oxide may be prepared through the Hummers method or the modified Hummers method.

Thereafter, activated carbon and the graphene oxide are dispersed in a solvent to prepare a spray solution (S20).

In an exemplary embodiment, biomass-based activated carbon and phenol-based activated carbon may be used as the activated carbon.

In an exemplary embodiment, the activated carbon may have a size (average diameter) in the range of 10 to 100 μm. If the size of the activated carbon is less than 10 ㎛ it is difficult to expect a high specific surface area value due to the coating of too many graphene oxide layer, it is difficult to manufacture the dispersion when it exceeds 100 ㎛ may be limited to the application of the spray drying method.

In one embodiment, the solvent may include one or more selected from the group consisting of water or an organic solvent (ethanol and acetone, etc.).

On the other hand, the graphene oxide and activated carbon in the solvent may be mixed in a weight ratio of 1: 1 to 1:10. When the mixing ratio of graphene oxide and activated carbon is less than 1: 1, the ratio of graphene and activated carbon is not compounded and is present alone, and the ratio of graphene oxide and activated carbon is too high. When the mixing ratio of 1 is greater than 1:10, the graphene may not sufficiently cover the surface of the activated carbon, and thus the electrical conductivity improvement effect may be insufficient.

On the other hand, in order to improve the dispersibility of the graphene oxide may be further used a dispersant.

Thereafter, the spray solution is sprayed into the droplets (S30).

In an exemplary embodiment, the droplet spraying process may be performed under temperature conditions ranging from 100 to 300 ° C. When the temperature of the droplet spraying process is less than 100 ℃ solvent may not be sufficiently evaporated spray drying effect is insufficient, if it exceeds 300 ℃ may be difficult to manufacture the graphene / activated carbon composite due to evaporation of solvent too fast .

In an exemplary embodiment, the droplet spray process may be carried out with a spray pressure of 49 ~ 245 kPa, the supply rate of the dispersion may be supplied at 150 ~ 1700 ml / hr. If the spray pressure of the droplet spraying process is less than 49 kPa may not form a dry powder, if it exceeds 245 kPa it may be difficult to form a graphene layer on the surface of the activated carbon.

In an exemplary embodiment, when the feed rate of the dispersion is less than 150 ml / hr, spherical complex formation may be difficult, and when it exceeds 1700 ml / hr, it may be difficult to obtain a dried powder form.

Thereafter, heat is applied to the droplets to prepare a graphene-activated carbon composite including activated carbon coated with a graphene layer (S40).

Specifically, a graphene-activated carbon composite including activated carbon coated with a graphene layer is prepared by applying heat to the droplets under a nitrogen atmosphere.

In an exemplary embodiment, the heating process may be performed in the range of 800 ~ 2000 ℃ by heating at a temperature increase rate of 5 ~ 20 ℃ per minute. If the temperature of the heating condition is less than 800 ℃ may not be enough to reduce the graphene, if the temperature exceeds 2000 ℃ activated carbon may collapse.

In an exemplary embodiment, the heating process may be performed for 50 to 640 minutes. When the execution time of the heating process is less than 50 minutes, the reduction of graphene may not be sufficient, and if the 640 minutes or more, the structure of activated carbon may be collapsed.

On the other hand, the heating process may be carried out under a nitrogen atmosphere, accordingly, the graphene oxide layer surrounding the activated carbon core can be reduced.

Alternatively, the graphene oxide layer may be reduced by using a reducing agent such as hydrazine during the heating process.

Accordingly, it is possible to produce a graphene-activated carbon composite including activated carbon as a core and a graphene layer as a shell.

Graphene Activated Carbon Complex

In another embodiment of the present invention there is provided a graphene-activated carbon composite including an activated carbon as a core as a graphene-activated carbon composite and a graphene layer as a shell. That is, in the graphene-activated carbon composite of the present invention, the graphene layer surrounds activated carbon, and may have a structure in which graphene is connected between neighboring activated carbon molecules. Accordingly, the graphene-activated carbon composite may exhibit improved electrical properties compared to activated carbon while showing excellent specific surface area characteristics of activated carbon.

In an exemplary embodiment, in the graphene-activated carbon composite, the weight ratio of the activated carbon and the graphene layer may be 2: 1 to 5: 1. If the mixing ratio of the reduced graphene and activated carbon is less than 2: 1, the electrical conductivity improvement effect of the graphene-activated carbon composite may be insignificant. If the mixing ratio of the reduced graphene and activated carbon exceeds 5: 1, the specific surface area It can be difficult to use as an electrode active material by causing a decrease of.

In an exemplary embodiment, the activated carbon may be biomass-based activated carbon or phenol-based activated carbon and may have a size ranging from 10 to 100 μm. If the size of the activated carbon is less than 10㎛ it is difficult to expect the coating effect of the graphene oxide, if it exceeds 100㎛ it is difficult to manufacture the dispersion may be limited to the application of the spray drying process.

In an exemplary embodiment, the graphene layer may be coated to have a thickness in the range of 1 nm to 200 nm. If the graphene layer is coated to less than the thickness range of 1 nm, the effect of improving electrical conductivity may be insignificant, and when the graphene layer exceeds 20 nm, the characteristics of activated carbon may be reduced. However, the present invention is not limited only to the embodiment.

Meanwhile, the specific surface area of the graphene-activated carbon composite material is in the range of 1000 to 2500 (m ² / g), and the graphene-activated carbon composite material includes a plurality of pores and the average diameter of the pores is in the range of 1.00 to 2.00 nm. There may be. As such, the graphene-activated carbon composite may exhibit an equivalent to increased specific surface area value as compared to conventional activated carbon, and thus may exhibit excellent characteristics when used as an active material of various electrodes. However, the present invention is not limited only to the embodiment.

In addition, the graphene-activated carbon composite may exhibit an electrical conductivity in the range of 1.55 to 10 S / cm, which is a significantly improved value compared to conventional activated carbon (0.67 S / cm, 1.29 MPa). However, the present invention is not limited only to the embodiment.

As described above, since the electric conductivity is excellent, it can be widely used in electronic devices such as supercapacitors and lithium ion batteries.

EXAMPLE

The embodiments of the present invention described above should not be construed as limiting the technical idea of the present invention. The protection scope of the present invention is limited only by the matters described in the claims, and those skilled in the art can change and change the technical idea of the present invention in various forms. Accordingly, such improvements and modifications will fall within the protection scope of the present invention as long as it will be apparent to those skilled in the art.

Example  One: Graphene -Activated Carbon Composite Graphene Oxide : Mixing ratio of activated carbon 1: 1)

Graphene oxide was prepared using a Couette-Taylor flow reactor, and dispersed in water with activated carbon (YP17D) to prepare a spray solution. At this time, the mixing ratio of graphene oxide and activated carbon was spray dried at a ratio of 1: 1 to 1:10. On the other hand, magnetic dispersion and sonication were performed for dispersion during preparation of the spray solution.

Thereafter, a droplet spray drying process was performed under hot air conditions of 100 to 300 ° C. to prepare droplets including activated carbon coated with graphene oxide.

Then, a graphene-activator composite including an activated carbon core coated with graphene as a shell was heated by heating to 800-2000 ° C. at a temperature increase rate of 5 ° C. per minute in a nitrogen atmosphere.

Comparative example  One

General activated carbon (YP17D) was used as a comparative example.

Experimental Example  One: Graphene -Structure and Characterization of Activated Carbon Composites

2A and 2B are differential scanning microscope (SEM) images of graphene-activated carbon composite (FIG. 2A) and activated carbon (FIG. 2B) according to one embodiment of the present invention, respectively. Looking at Figure 2a, it can be seen that in the case of graphene-activated carbon, the graphene layer is well wrapped around the activated carbon core, which is a result contrasted with that of Figure 2b.

Meanwhile, the specific surface area of the graphene-activated carbon composite was analyzed through nitrogen adsorption and desorption experiments, and total pore volume and average pore size were measured and shown in Table 1 below.

BET specific surface area
(m ² / g) Total pore volume
(cm ³ / g) Average pore diameter
(nm) Graphene-Activated Carbon Complex 1,539 0.74 1.94 Activated carbon 1,519 0.71 1.87

Looking at the Table 1, the graphene-activated carbon composite was confirmed that the surface area is similar to the activated carbon even after complexing, showing a slightly higher BET specific surface area value.

On the other hand, in order to confirm the resistance reduction characteristics of the graphene-activated carbon composite (Example 1) and activated carbon (Comparative Example 1), the powder resistance was measured and the results are shown in FIG. 3. Specifically, the powder resistance was measured at a pressure of 1 to 52 Mpa based on a 0.5 g sample. As a result, the activated carbon showed a resistance of 3.54 ~ 0.201 Ωcm, whereas the graphene-activated carbon composite produced a resistance of 0.645 ~ 0.08 Ωcm and showed a resistance of 82 ~ 60% reduced resistance.

This is because the graphene having excellent electrical conductivity is present on the surface of the activated carbon core to reduce the resistance, and also because the graphene is connected between neighboring activated carbons to decrease the resistance.

Experimental Example  3: Supercapacitor behavior analysis

Graphene-activated carbon composite according to Example 1 and activated carbon according to Comparative Example 1 were each selected as an active material, and then an electrode material was prepared in an amount of 90:10 for the active material and the binder for electrochemical characterization. The prepared electrode was prepared by evaluating two electrodes having a diameter of 1.5 cm, assembled into a 2032 coin cell type. At this time, the electrolyte solution was used TEABF ₄ in 1.5 M PC, the charge and discharge current density based on 2.5V voltage was evaluated by applying 1 ~ 30 mAcm ^{- 2} and the results are shown in Figure 4a and 4b.

4A and 4B, the supercapacitor including the graphene-activated carbon composite according to Example 1 is at 1 mAcm ⁻² . 111 Fg ^-1 , At 30 mAcm ^-2 , a weight capacitance of 46 Fg ^{- 1} was obtained, which is a supercapacitor containing activated carbon according to Comparative Example 1 (1 mAcm ^{- 2} : 99 Fg ^-1 / 30 mAcm ^{- 2} : 20 Fg ^-1 ) was increased 112 ~ 230%.

Experimental Example  4: Lithium secondary battery  Cathodic Behavior Analysis

Graphene-activated carbon composite according to Example 1 and activated carbon according to Comparative Example 1 were each selected as a negative electrode active material, and then Super-P was used as the conductive material and polyacrylic acid was used as the binder. The composition of the electrode was mixed at 80 wt% of the negative electrode active material, 10 wt% of the conductive material, and 10 wt% of the binder. A coin cell consisting of the prepared cathode and LiPF ₆ 1: 1 vol% ethylene carbonate (EC) / dimethyl carbonate (DMC) liquid electrolyte was prepared, and the charge and discharge experiments were conducted using the charge and discharge battery. The charge / discharge capacity, cycle characteristics, and rate performance of the prepared lithium secondary batteries were investigated.

Charging and discharging was performed at a voltage range of 0.005 to 2.0 V at a current of 35 mA / g (0.1 C).

Since the charge and discharge of the lithium secondary battery, cycle characteristics, capacity retention rate, coulombic efficiency and rate characteristics are shown in Figures 5, 6a, 6b and 7, respectively. As shown in FIG. 5, the lithium secondary battery manufactured using the graphene-activated carbon composite and the lithium secondary battery manufactured using the activated carbon exhibited initial cathode capacities of 434 mAh / g and 422 mAh / g, respectively. Comparing the post-coulombic efficiency, 31.8% is shown in the case of using activated carbon, 39.5% in case of using the graphene-activated carbon composite.

On the other hand, Figure 6 shows the life characteristics, capacity retention rate and coulombic efficiency of the lithium secondary battery, Figures 6a and 6b, the graphene-activated carbon composite using a higher capacity than the case of using the activated carbon even in 100 charge and discharge results It was confirmed that it shows the better cycle characteristics, capacity retention rate and coulombic efficiency.

On the other hand, Figure 7 is a discharge using a charge and discharge cycle, in order to compare the discharge characteristics according to the current density of the lithium-ion battery electrode prepared using the graphene-activated carbon composite according to Example 1 and the activated carbon according to Comparative Example 1 After five cycles of charging and discharging experiments at current densities of 0.1, 0.2, 0.5, 1, 2, and 5 C (1C = 350 mA / g), 0.2 C was again measured to confirm capacity retention. The experimental result is shown.

Referring to FIG. 7, when the lithium ion battery negative electrode was manufactured using the graphene-activated carbon composite according to Example 1, the capacity characteristics and the capacity retention rate of the lithium ion battery negative electrode were changed using the activated carbon according to Comparative Example 1 even at various discharge currents. It can be seen that it is significantly improved compared to the case of manufacture. This is because the graphene layer surrounds the activated carbon core to reduce the specific resistance of the surface of the lithium ion battery electrode, thereby inducing an effective electrochemical reaction during charging and discharging of the battery. In other words, the graphene in the electrode containing the graphene-activated carbon composite is believed to improve the electrochemical properties because it shortens the lithium diffusion path and maintains the electrical conductivity.

Claims (11)

As a graphene-activated carbon composite,
Contains activated carbon as a core,
Graphene-activated carbon composite comprising a graphene layer as a shell.
The method of claim 1,
In the graphene-activated carbon composite, the weight ratio of the activated carbon and the graphene layer is 2: 1 to 5: 1 graphene-activated carbon composite.
The method of claim 1,
The activated carbon has a size in the range of 10 to 100㎛,
The graphene layer is graphene-activated carbon composite having a thickness in the range of 1 to 200nm.
The method of claim 1,
The specific surface area of the graphene-activated carbon composite material is in the range of 1,000 to 2500 m ² / g,
The graphene-activated carbon composite includes a plurality of pores, and the average diameter of the pores is in the range of 1.00 to 2.00 nm, graphene-activated carbon composite.
The method of claim 1,
The graphene-activated carbon composite shows an electrical conductivity in the range of 0.1 to 100 S / cm, graphene-activated carbon composite.
Preparing graphene oxide;
Dispersing activated carbon and the graphene oxide in a solvent to prepare a spray solution;
Spraying the spray solution into droplets; And
A graphene-activated carbon composite manufacturing method comprising the steps of: preparing a graphene-activated carbon composite including activated carbon coated with a graphene layer by applying heat to the droplets.
The method of claim 6,
In the spray solution, the activated carbon and graphene oxide is contained in a weight ratio of 1: 1 to 1:10, the method for producing a graphene-activated carbon composite.
The method of claim 6,
The droplet spray process is carried out at a spray pressure of 49 ~ 245 kPa and a feed rate of 150 ~ 1700 ml / hr under a temperature condition in the range of 100 ~ 300 ℃, graphene-activated carbon composite.
The method of claim 6,
The process of applying heat to the droplets is heated at a temperature increase rate of 5 ~ 20 ℃ per minute is carried out for 50 to 640 minutes in the range of 800 ~ 2000 ℃, graphene-activated carbon composite manufacturing method.
Supercapacitor comprising the graphene-activated carbon composite according to any one of claims 1 to 5.
A lithium ion battery comprising the graphene-activated carbon composite according to any one of claims 1 to 5.

Images