KR20230111168A - Eco-friendly mass manufacturing method of high purity graphene flakes - Google Patents

Abstract

The present invention relates to a method for mass-producing high-purity graphene flakes, and more particularly, to a method for mass-producing high-purity and high-quality graphene, which can significantly reduce production costs by mass-producing high-purity and high-quality graphene, minimizes environmental pollution caused by discharge of strong acids or bases generated during mass production, and can mass-produce graphene functionalized with hydrogen to facilitate development of new materials using high-purity graphene flakes. Accordingly, the method for mass-producing high-purity graphene flakes according to the present invention includes a material preparation step of preparing an aqueous solution containing a carbon-based material having a layered structure and at least one ion of a group 1 or group 2 element; After introducing the prepared carbon-based material and the aqueous solution into a homogenizer, the homogenizer is operated at a predetermined temperature and a predetermined rotation speed for a predetermined period of time to generate at least one ion of a group 1 or group 2 element contained in the aqueous solution between layers of the carbon-based material; After adding hydrogen peroxide to the mixture generated through the mixture generating step, operating the homogenizer again for a predetermined time at a predetermined temperature and a predetermined rotation speed to oxidize and discharge group 1 or group 2 element ions inserted between the layers of the carbon-based material, and a hydrogen peroxide mixing step of widening the interlayer spacing of the carbon-based material through oxidative discharge of ions; an electrolytic peeling step of exfoliating the carbon-based material in the hydrogen peroxide mixture having an increased interlayer gap by passing a current having a predetermined current value for a predetermined time to the hydrogen peroxide mixture generated through the hydrogen peroxide mixing step; And, the hydrogen peroxide mixture subjected to the electrolytic separation step is subjected to vacuum filtering to separate solid powder and liquid, and the separated solid powder is washed with ultrapure water until the pH of the separated solid powder reaches 7. A solid powder-liquid separation and washing step of removing impurities remaining in the separated solid powder; The liquid and washing water separated through the solid powder liquid separation and washing step are characterized in that a predetermined amount of water is removed through fractional distillation, and then an aqueous solution containing one or more ions of Group 1 or Group 2 elements is mixed with a predetermined amount and reused as the aqueous solution in the material preparation step.

Description

Eco-friendly mass manufacturing method of high purity graphene flakes}

The present invention relates to an eco-friendly mass production method for high-purity graphene flakes, and more particularly, to a method for mass-producing high-purity and high-quality graphene, which can significantly reduce production costs, minimizes environmental pollution caused by discharge of strong acids or strong bases generated during mass production, and can mass-produce hydrogen-functionalized graphene to facilitate the development of new materials using high-purity graphene flakes. it will

In general, for materials such as aircraft and automobiles, there is a growing demand for lighter weight and higher strength materials with the aim of improving fuel efficiency and reducing energy consumption. In particular, graphene-metal composites are widely used as structural members for aircraft and automobiles due to their advantages such as light weight, high strength, and excellent formability.

Conventional graphene-metal composites are manufactured through a powder metallurgy process in which metal powder and graphene powder are mixed, subjected to a dry exfoliation process, and then sintered. In the case of the powder metallurgy process, the graphene powder has a property of strong aggregation between graphenes due to the van der Waals force between the graphenes, making it difficult to uniformly distribute in the metal matrix, and due to the difference in density between graphene and the metal matrix, it is difficult for graphene to disperse in the metal matrix and degrades uniform distribution in the metal matrix. , The agglomerated graphene interferes with sintering of the composite powder, reducing the density, degrading the properties of the composite material, and when graphene is mixed with metal powder such as aluminum and titanium and sintered, carbides such as aluminum carbide and titanium carbide are formed, so that the strengthening effect by the original graphene cannot be expected, so it is difficult to manufacture a graphene-metal composite.

On the other hand, functionalization of hydrogen refers to a form in which hydrogen or a functional group capable of generating hydrogen is bonded to or adsorbed to a matrix, and includes a form in which hydrogen or a functional group capable of generating hydrogen is confined to a matrix by a chemical bond such as a hydrogen bond, a covalent bond, or a non-covalent cross-linked bond between hydrogen or a functional group capable of generating hydrogen, such as a C-H or C-OH bond, or a structure of an adsorption matrix through electrostatic attraction such as a van der Waals bond.

In the case of hydrogen-functionalized graphene-metal composites, the bonding force between graphene and metal can be strengthened, the dispersion of graphene can be improved to minimize graphene aggregation, and during the casting process using a mixture of graphene and metal, the separation phenomenon due to the difference in density between graphene and metal can be suppressed, so that a graphene-metal alloy can be easily manufactured through a casting process.

As described above, hydrogen-functionalized graphene is known to exhibit more improved functions, such as ease of manufacturing graphene-metal composites, hydrogen storage, and increased electrical and magnetic properties, compared to conventional graphene. However, hydrogen-functionalized graphene has problems in mass production more difficult than general graphene. In addition, in the case of the conventional method for manufacturing graphene flakes through chemical exfoliation, there is a problem in that waste liquid of strong acid or base is generated, and the waste liquid of strong acid or strong base cannot be recycled and is discharged to the outside as it is. There are problems such as environmental pollution.

The present invention was derived to solve the above problems, and enables mass production of high-purity and high-quality graphene to significantly reduce production costs, minimizes environmental pollution caused by discharge of strong acids or strong bases generated in the mass production process, and mass-produces hydrogen-functionalized graphene to facilitate the development of new materials using high-purity graphene flakes.

In one aspect of the present invention for solving the above-mentioned problems, a material preparation step of preparing an aqueous solution containing a carbon-based material having a layered structure and at least one ion of a group 1 or group 2 element; After introducing the prepared carbon-based material and the aqueous solution into a homogenizer, the homogenizer is operated at a predetermined temperature and a predetermined rotation speed for a predetermined period of time to generate at least one ion of a group 1 or group 2 element contained in the aqueous solution between layers of the carbon-based material; After adding hydrogen peroxide to the mixture generated through the mixture generating step, operating the homogenizer again for a predetermined time at a predetermined temperature and a predetermined rotation speed to oxidize and discharge group 1 or group 2 element ions inserted between the layers of the carbon-based material, and a hydrogen peroxide mixing step of widening the interlayer spacing of the carbon-based material through oxidative discharge of ions; an electrolytic peeling step of exfoliating the carbon-based material in the hydrogen peroxide mixture having an increased interlayer gap by passing a current having a predetermined current value for a predetermined time to the hydrogen peroxide mixture generated through the hydrogen peroxide mixing step; And, the hydrogen peroxide mixture subjected to the electrolytic separation step is subjected to vacuum filtering to separate solid powder and liquid, and the separated solid powder is washed with ultrapure water until the pH of the separated solid powder reaches 7. A solid powder-liquid separation and washing step of removing impurities remaining in the separated solid powder; A predetermined amount of water is removed from the liquid and washing water separated through the solid powder liquid separation and washing step through fractional distillation, and then an aqueous solution containing at least one ion of a group 1 or group 2 element is mixed with a predetermined amount and reused as the aqueous solution in the material preparation step.

In an eco-friendly mass production method for producing high-purity graphene flakes according to an embodiment of the present invention, the solid powder separated from the hydrogen peroxide mixture and washed through the solid powder liquid separation and washing steps is introduced into a dry exfoliation device, and then the dry exfoliation step of increasing the degree of exfoliation of the solid powder by operating the dry exfoliation device in an inert gas atmosphere at a predetermined temperature and for a predetermined time; It may be further formed to include,

Preferably, the solid powder subjected to the dry exfoliation step is introduced into a hydrogen functionalization device in which the internal temperature is formed at a predetermined temperature, and an inert gas and hydrogen gas are mixed at a predetermined volume ratio into the hydrogen functionalization device into which the solid powder is introduced. After flowing a mixed gas at a predetermined volume ratio, a hydrogen functionalization step of rapidly cooling the solid powder introduced into the hydrogen functionalization device; It may be further included.

The method for mass-producing high-purity graphene flakes according to the present invention enables mass-production of high-purity and high-quality graphene, thereby significantly reducing production costs, minimizing environmental pollution caused by discharge of strong acids or strong bases generated in the mass production process, and mass-producing graphene functionalized with hydrogen to facilitate the development of new materials using high-purity graphene flakes.

1 is a process block diagram showing an eco-friendly mass production manufacturing method of high-purity graphene flakes step by step according to the present invention;
2 is an SEM and TEM image showing the high-purity graphene flakes manufactured through the dry exfoliation step in the eco-friendly mass production method of high-purity graphene flakes according to the present invention;
3 is an SEM and TEM image of a hydrogen-functionalized high-purity graphene flake in an eco-friendly mass production method of high-purity graphene flakes according to the present invention;
4 is a TEM image and elemental mapping analysis image of the hydrogen-functionalized high-purity graphene flake in the eco-friendly mass production method of high-purity graphene flakes according to the present invention;
5 is a CHNS analysis of hydrogen-functionalized high-purity graphene flakes in the eco-friendly mass production method of high-purity graphene flakes according to the present invention;
6 is an eco-friendly mass production manufacturing method of high-purity graphene flakes according to the present invention, a dispersity comparison test image in ultrapure water and a dispersibility test image in plastic of the hydrogen-functionalized high-purity graphene flake;
7 is a test image of a change in mechanical properties when an aluminum casting material is used by combining hydrogen-functionalized high-purity graphene flakes with aluminum in the eco-friendly mass production manufacturing method of high-purity graphene flakes according to the present invention; and,
8 is a schematic view briefly showing hydrogen-functionalized high-purity graphene flakes in the eco-friendly mass production method of high-purity graphene flakes according to the present invention.

Hereinafter, embodiments of the present invention in which the above object can be realized in detail will be described with reference to the accompanying drawings. In describing the present embodiments, the same names and symbols are used for the same components, and additional descriptions accordingly are omitted below.

1 is a process block diagram showing an eco-friendly mass production manufacturing method of high-purity graphene flakes step by step according to the present invention.

As shown in FIG. 1, the method for mass production of high-purity graphene flakes according to the present invention, as shown in FIG. 1, largely includes a material preparation step, a mixture generating step of mixing the prepared materials in a predetermined ratio through a homogenizer, a hydrogen peroxide mixing step of homogeneously mixing after injecting hydrogen peroxide into the mixture generated through the mixture generating step, an electrolytic peeling step of exfoliating a carbon-based material by passing a current through the hydrogen peroxide mixture, and an electrolytic peeling step. After separating solid powder and liquid from the hydrogen peroxide mixture, it is formed by including a solid powder liquid separation and washing step of washing the separated solid powder.

The material preparation step is a step of preparing an aqueous solution containing a carbon-based material used as a material for mass production of high-purity graphene flakes and at least one ion of a group 1 or 2 element. The carbon-based material may include all carbon-based materials having a layered structure while having conductivity, such as natural graphite, artificial graphite, expanded graphite, and functional graphite, and at least one carbon-based material selected from the group consisting of the natural graphite, artificial graphite, expanded graphite, and functional graphite. can be used. In addition, an aqueous solution containing at least one ion of a group 1 or 2 element, such as an aqueous NaOH solution, an aqueous KOH solution, or an aqueous KCl solution, is prepared along with the carbon-based solution.

In the mixture generating step, the prepared carbon-based material and an aqueous solution containing one or more ions of Group 1 or 2 elements are introduced into a homogenizer, and then the homogenizer is operated at a predetermined temperature and a predetermined rotation speed for a predetermined period of time to combine and intercalate the ions of one or more Group 1 or 2 elements contained in the aqueous solution through mixing and homogenization of the carbon-based material and the aqueous solution.

Preferably, the internal temperature of the homogenizer can be maintained at a temperature of 80 ~ 200 ° C, the rotation speed of the homogenizer can be operated at 100 ~ 1000 rpm, and the operating time of the homogenizer can be operated for 1 hour to 1 hour and 30 minutes. When the internal temperature of the homogenizer is lower than 80 ° C, the diffusion of ions is slow, and when the temperature is higher than 200 ° C, the manufacturing cost may be increased. When the rotation speed is lower than 100 rpm, the homogenization is slow, and when the rotation speed is higher than 1000 rpm, smooth diffusion of ions can be prevented. there is

In the hydrogen peroxide mixing step, after adding hydrogen peroxide to the mixture generated through the mixture generating step, the homogenizer is operated again for a predetermined time at a predetermined temperature and a predetermined rotation speed to oxidize and discharge group 1 or group 2 element ions inserted between the layers of the carbon-based material, and widen the interlayer spacing of the carbon-based material through oxidation and discharge of the group 1 or group 2 element ions intercalated between the layers of the carbon-based material.

Preferably, 10 to 70 parts by weight of hydrogen peroxide is mixed with 100 parts by weight of the mixture, the internal temperature of the homogenizer is maintained at 80 to 200 ° C, the rotation speed of the homogenizer is operated at 100 to 1000 rpm, and the operating time of the homogenizer is operated for 1 hour to 1 hour and 30 minutes to obtain the group 1 or Oxidation of group 2 element ions is promoted, and intercalation of intercalated ions generated at this time is promoted to widen the interlayer spacing of the carbon-based material. If the amount of hydrogen peroxide introduced is less than 10 parts by weight, the amount of ion oxidation is small, the efficiency of the electrolytic separation performed in the next step is reduced, and if it is more than 70 parts by weight, the oxidation degree of graphene may increase. If the temperature inside the homogenizer is lower than 80 ° C, the diffusion of ions is slow, if it is higher than 200 ° C, manufacturing cost may increase, and if the rotation speed is lower than 100 rpm, homogenization is slow , If it is higher than 1000 rpm, smooth diffusion of ions may be hindered, if the operating time is shorter than 1 hour, homogenization is not completely achieved, and if it is longer than 1 hour and 30 minutes, manufacturing cost may increase.

In the electrolytic peeling step, a current of a predetermined current value is passed for a predetermined time to the hydrogen peroxide mixture generated through the hydrogen peroxide mixing step, and the carbon-based material in the hydrogen peroxide mixture in which the interlayer gap is widened through oxidative discharge of ions is exfoliated.

The electrolytic peeling method in the electrolytic peeling step can perform a conventional electrolytic peeling method in addition to the hydrogen peroxide mixture as its target, so the description of the conventional electrolytic peeling method is omitted. , if it is higher than 1 A, there is a problem in that the risk of explosion and the quality are lowered.

In the solid powder-liquid separation and washing step, the hydrogen peroxide mixture subjected to the electrolytic separation step is vacuum-filtered to separate into a carbon-based solid powder and a liquid, and the separated carbon-based solid powder is repeatedly washed with ultrapure water until the pH of the separated carbon-based solid powder reaches '7', that is, until it becomes neutral, thereby removing impurities and ions remaining in the separated carbon-based solid powder. In particular, in the method for mass-producing high-purity graphene flakes according to the present invention, instead of discharging the liquid and washing water generated in the process of the solid powder liquid separation and washing step to the outside as they are, the separated liquid and washing water are collected together to remove a predetermined amount of water through fractional distillation, and then an aqueous solution containing one or more ions of group 1 or group 2 elements is mixed in a predetermined amount and reused as the aqueous solution in the material preparation step, thereby reusing the aqueous solution in the material preparation step. It is possible to solve the problem of causing environmental pollution by discharging the acid or strong basic solution to the outside without reuse, and it is possible to significantly reduce the production cost of high-purity graphene flakes because the expensive solution can be recycled.

Preferably, the carbon -based solid powder having the washing is separated from the hydrogen peroxide mixture through the solid powder liquid separation and the washing step, and then injected in the dry peeling apparatus, and then dried the carbon solid powder for a predetermined temperature and a predetermined time in an inert gas atmosphere, while the intercept of impurities and ions was expanded according to the discharge of impurities and ions while drying the carbon solid powder. By further conducting a dry peeling step of separating each layer through the gap, the peeling view of the solid powder is increased. An Ar atmosphere is created inside the dry exfoliation device to prevent oxidation of the carbon-based solid powder, the internal temperature is maintained at 80 degrees to facilitate drying, and the carbon-based solid powder is dried and uniformly exfoliated by operating for 24 hours. The process of increasing the degree of exfoliation through the dry exfoliation step may use an exfoliation method using mechanical energy such as an attrition mill, a ball mill, or a jed mill.

In addition, after performing the dry exfoliation step, the carbon-based solid powder subjected to the dry exfoliation step is introduced into a hydrogen functionalization device in which the internal temperature is formed at a predetermined temperature, and a mixed gas in which an inert gas and hydrogen gas are mixed at a predetermined volume ratio is flowed into the hydrogen functionalization device into which the carbon-based solid powder is introduced for a predetermined time, and then a hydrogen functionalization step of quenching the carbon-based solid powder introduced into the hydrogen functionalization device may be performed.

The hydrogen functionalization refers to a form in which hydrogen or a functional group capable of generating hydrogen is bonded to or adsorbed to a matrix, and includes a form in which hydrogen or a functional group capable of generating hydrogen is trapped in a matrix by a chemical bond such as a hydrogen bond or a covalent bond between a functional group capable of generating hydrogen or a matrix, or an adsorption matrix structure through electrostatic attraction such as a van der Waals bond. The reduction of pin helps to form high-purity graphene, and at the same time, some hydrogen enters the reduced position to form a covalent bond between graphene and hydrogen, and some hydrogen is trapped by the Walder Waals force between layers of graphene, and then rapidly cooled to contain several wt% hydrogen.

Preferably, while maintaining the temperature inside the hydrogen functionalization device at 300 to 500 ° C., a mixed gas in which the volume ratio of argon gas and hydrogen gas is 5: 5 to 9: 1 is mixed at a constant flow rate into the hydrogen functionalization device. After flowing and maintaining for 5 to 6 hours, it can be quenched. When the temperature inside the hydrogen functionalization device is lower than 300 ° C, the impurity removal due to hydrogen reduction is not uniformly performed, and when the temperature is higher than 500 ° C, the cost efficiency is lowered. If the mixing ratio of hydrogen in the mixed gas is low, the impurity removal efficiency is low.

In addition, the carbon solid powder, that is, the graphene powder, can be exposed to the high temperature maintenance device of more than 1000 ° C., and the interlayer space of the graphene powder heated at high temperature instantly to increase the peeling view of the graphene flake, and at the same time, the surface of the graphene flake which is instantly heated. As the cow is exiting, the remaining impurities are almost completely removed, and hydrogen -functional high -purity graphene flakes can be produced.

Hereinafter, embodiments according to the present invention will be described.

In the eco-friendly mass production method of high-purity graphene flakes according to the present invention, in the material preparation step, 100 parts by weight of impression graphite and 900 parts by weight of 0.6M KOH aqueous solution were prepared, and the prepared impression graphite and KOH aqueous solution were introduced into a homogenizer maintaining an internal temperature of 80 ° C. Then, the mixture was generated by operating at a rotation speed of 120 rpm for 8 hours to insert ions between graphite layers.

After adding 20 parts by weight of hydrogen peroxide to 100 parts by weight of the mixture produced through the mixture generating step, it was operated for 1 hour at a rotational speed of 120 rpm while maintaining the temperature at 80 ° C. The hydrogen peroxide mixing step of widening the interlayer gap through the elution of ions intercalated between the layers of the carbon-based material was performed.

The hydrogen peroxide mixture that had gone through the hydrogen peroxide mixing step was energized at a current value of 0.1 A for 12 hours to perform the electrolytic peeling step, and the hydrogen peroxide mixture that had gone through the electrolytic peeling step was vacuum filtered to separate into carbon-based solid powder and liquid. The separated carbon-based solid powder was repeatedly washed with ultrapure water until the pH reached '7' to perform the solid-powder-liquid separation and washing step.

After the carbon-based solid powder separated through the solid powder liquid separation and washing step was put into a ball mill device, the dry exfoliation step was performed by operating the ball mill device for 24 hours while maintaining a temperature of 80 ° C. in an argon atmosphere.

After the dry exfoliation step, the carbon-based solid powder, that is, graphene flake, was introduced into a hydrogen functionalization device maintaining an internal temperature of 300 ° C., and then a mixed gas containing argon gas and hydrogen gas at a volume ratio of 8: 2 was flowed at a flow rate of 100 sccm. After maintaining for 5 hours, the hydrogen functionalization step was performed by rapidly cooling to room temperature.

After carrying out the hydrogen functionalization step, the hydrogen-functionalized graphene flake was additionally put into a high-temperature maintaining device heated to 1200 ° C. and maintained for 1 minute.

2 is an SEM and TEM image showing the high-purity graphene flakes produced through the dry exfoliation step in the eco-friendly mass production method of high-purity graphene flakes according to the present invention, confirming that the exfoliation of graphite is well done,

3 is an SEM and TEM image of the hydrogen-functionalized high-purity graphene flake produced in the above-described example in the eco-friendly mass-production method of high-purity graphene flakes according to the present invention. It can be confirmed that graphite is well exfoliated to form graphene,

4 is a TEM image and elemental mapping analysis of the hydrogen-functionalized high-purity graphene flake produced in the above-described example in the eco-friendly mass production method of high-purity graphene flakes according to the present invention. Through the data, it can be confirmed that the graphene flake is hardly oxidized and at the same time, no impurities exist.

5 is a CHNS analysis of the hydrogen-functionalized high-purity graphene flakes prepared in the above-described example in the eco-friendly mass-production method of high-purity graphene flakes according to the present invention. It can be confirmed that hydrogen at a level of 2 At% is functionalized.

6 is a photograph of a dispersity comparison test in ultrapure water of the hydrogen-functionalized high-purity graphene flakes prepared in the above-described example in the method for eco-friendly mass production of high-purity graphene flakes according to the present invention.

7 is a mechanical property change test when an aluminum casting material is used by combining the hydrogen-functionalized high-purity graphene flakes prepared in the above-described embodiment with aluminum in the eco-friendly mass production method of high-purity graphene flakes according to the present invention. Although it was difficult to use as a casting material with conventional carbon-based materials, it was confirmed that casting is possible in the case of hydrogen-functionalized high-purity graphene flakes according to the present invention, and it can be confirmed that the material properties of the cast alloy are improved.

Although several embodiments have been illustratively described above, the fact that the present invention can be embodied in many different forms without departing from its spirit and scope is apparent to those skilled in the art.

Accordingly, the embodiments described above are to be regarded as illustrative rather than restrictive, and all embodiments coming within the scope of the appended claims and their equivalents are included within the scope of this invention.

Claims (1)

A material preparation step of preparing an aqueous solution containing a carbon-based material having a layered structure and at least one ion of a group 1 or group 2 element;
After introducing the prepared carbon-based material and the aqueous solution into a homogenizer, the homogenizer is operated at a predetermined temperature and a predetermined rotation speed for a predetermined period of time to generate at least one ion of a group 1 or group 2 element contained in the aqueous solution between layers of the carbon-based material;
After adding hydrogen peroxide to the mixture generated through the mixture generating step, operating the homogenizer again for a predetermined time at a predetermined temperature and a predetermined rotation speed to oxidize and discharge group 1 or group 2 element ions inserted between the layers of the carbon-based material, and a hydrogen peroxide mixing step of widening the interlayer spacing of the carbon-based material through oxidative discharge of ions;
A constant current electrolytic peeling step of exfoliating the carbon-based material in the hydrogen peroxide mixture having an increased interlayer interval by applying current to the hydrogen peroxide mixture generated through the hydrogen peroxide mixing step for a predetermined time while maintaining a constant current at a predetermined current value; and,
The hydrogen peroxide mixture subjected to the electrolytic separation step is vacuum filtered to separate solid powder and liquid, and the separated solid powder is repeatedly washed with ultrapure water until the pH of the separated solid powder reaches 7. A solid powder liquid separation and washing step of removing impurities remaining in the separated solid powder; formed, including
The liquid separated through the solid powder liquid separation and washing step and the washing water used in the repeated washing process of the separated solid powder are collected together, mixed, and fractionated, and the distilled water generated in the fractional distillation process is discharged to the outside to remove a predetermined amount of water from the mixture of the collected liquid and the washing water. A predetermined amount of an aqueous solution containing at least one species is mixed and reused as the aqueous solution in the material preparation step,

After passing through the solid powder-liquid separation and washing step, the solid powder separated from the hydrogen peroxide mixture and washed is put into a dry exfoliation device, and then the dry exfoliation device is operated at a predetermined temperature and for a predetermined time in an inert gas atmosphere to increase the degree of exfoliation of the solid powder;
Injecting the solid powder that has undergone the dry exfoliation step into a hydrogen functionalization device having an internal temperature at a predetermined temperature, and flowing a mixed gas in which an inert gas and hydrogen gas are mixed at a predetermined volume ratio into the hydrogen functionalization device into which the solid powder is introduced, After flowing for a predetermined time, the solid powder introduced into the hydrogen functionalization device is quenched to bind a predetermined amount of hydrogen to a carbon-based matrix forming the solid powder; and,
By carrying out the hydrogen functionalization step, the solid powder in which a predetermined amount of hydrogen is bonded to the carbon-based matrix is put into the high temperature maintaining device, and the inside of the high temperature maintaining device into which the solid powder is injected is maintained at a predetermined temperature value of 1000 ° C. or higher for a predetermined time. A rapid high temperature maintaining step of maintaining; Eco-friendly mass production manufacturing method of high-purity graphene flakes, characterized in that formed by further comprising.