KR102603325B1 - Apparatus for manufacturing graphene - Google Patents

Abstract

A graphene manufacturing device is provided. A graphene manufacturing apparatus according to an embodiment of the present invention includes a supply unit for supplying graphite oxide powder or graphene oxide powder; The supply unit is coupled to one side, has a moving surface inside which has a predetermined width and extends from one side in one direction, and has a moving unit body with a moving space formed on an upper side of the moving surface, and the graphite oxide powder supplied from the supply unit or the A moving part that receives graphene oxide powder from one side of the moving space and moves it to the other side; A laser irradiation unit that irradiates a laser on a movement path of the graphite oxide powder or the graphene oxide powder to produce the graphite oxide powder or the graphene oxide powder into graphene powder; and a collection unit connected to the other side of the moving unit to separate and collect the graphene powder from the graphite oxide powder or the graphene oxide powder; may include.

Description

Graphene manufacturing device {APPARATUS FOR MANUFACTURING GRAPHENE}

The present invention relates to a graphene production device, and more specifically, to a graphene production device that produces graphene powder by irradiating a laser to graphite oxide powder or graphene oxide powder. It's about.

Graphene is one of the allotropes of carbon and has a structure in which carbon atoms come together to form a two-dimensional plane. Each carbon atom forms a hexagonal lattice, and the carbon atom is located at the vertex of the hexagon.

Graphene has very high intrinsic electron mobility, high thermal conductivity, Young's modulus, and has a very large theoretical specific surface area. Additionally, because it is composed of one layer, it has very low absorption of visible light.

Due to these characteristics of graphene, graphene is used to make thin, light, and durable objects such as airplanes, automobiles, and construction materials, or it is used to make fibers with the strength of graphene and use it for light and safe combat uniforms and body armor. Carbon fiber using is attracting attention. Additionally, graphene's fast electrical conductivity reduces electrical resistance and is expected to lead to advancements in the medical industry.

Such graphene is produced from graphite, and in the past, physical exfoliation methods, chemical vapor deposition methods, chemical exfoliation methods, and epitaxial synthesis methods have been used to produce graphene, but they are still insufficient to produce graphene stably. am.

These methods not only make it difficult to manufacture graphene so that the residual oxygen impurities of graphene are less than 10%, but also have problems in that the manufacturing method is complicated and the manufacturing time is long.

In particular, in the case of the epitaxial synthesis method, heat treatment of 1500 to 2500 degrees or more is required to reduce the residual oxygen impurity content to 10% or less, and even when such heat treatment is used, there is a problem with the produced graphene restacking. .

Therefore, unlike the conventional method described above, there is a need for a graphene production device that can easily produce graphene and reduce residual oxygen impurities in graphene.

Japanese Patent Publication No. 2021-063002 (Method for producing single-layer graphene, method for producing single-layer graphene dispersion, and single-layer graphene dispersion)

In order to solve the above problems, the purpose of the present invention is to provide a graphene production device that can produce graphene without complicated processing processes.

Additionally, the purpose is to provide a graphene production device that can continuously produce large amounts of graphene.

Additionally, the purpose is to provide a graphene manufacturing device that can increase graphene manufacturing efficiency.

The problems of the present invention are not limited to the problems mentioned above, and other problems not mentioned can be clearly understood by those skilled in the art from the description below.

In order to solve the above problem, a graphene manufacturing apparatus according to one aspect of the present invention includes a supply unit for supplying graphite oxide powder or graphene oxide powder; The supply unit is coupled to one side, has a moving surface inside which has a predetermined width and extends from one side in one direction, and has a moving unit body with a moving space formed on an upper side of the moving surface, and the graphite oxide powder supplied from the supply unit or the A moving part that receives graphene oxide powder from one side of the moving space and moves it to the other side; A laser irradiation unit that irradiates a laser on a movement path of the graphite oxide powder or the graphene oxide powder to produce the graphite oxide powder or the graphene oxide powder into graphene powder; And a collection part connected to the other side of the moving part to collect the graphene powder; may include.

At this time, the laser irradiation unit may irradiate a linear laser extending in the width direction of the moving surface.

At this time, the supply unit may supply the graphite oxide powder or the graphene oxide powder to one side of the moving surface so that the graphite oxide powder or the graphene oxide powder is distributed in the width direction.

At this time, the laser power intensity of the laser irradiation unit may be 30 W/mm ² or more and 150 W/mm ² or less.

At this time, the speed at which the moving part moves the graphite oxide powder or the graphene oxide powder may be 5 mm/s or more and 50 mm/s or less.

At this time, the moving part body is formed in a cylindrical shape so that the moving space is formed therein, and a moving surface having a predetermined angle with the direction of its own weight is formed on the lower inner surface of the moving part body; and a vibration generator disposed on one side of the moving unit body and generating vibration. It includes, and the vibration generator may transfer the vibration to the moving unit body to move the graphite oxide powder or the graphene oxide powder along the moving surface.

At this time, a quartz substrate 230 formed in an area where the laser irradiation unit irradiates the laser; It may further include.

At this time, the quartz substrate may be formed integrally with the moving unit body.

At this time, the laser irradiation unit is disposed outside the moving unit, and is formed on the moving unit body 210 so that the laser L irradiated from the laser irradiating unit 300 passes through and reaches the moving surface 212. lens 240; It may further include.

At this time, a collection unit coupled to the other side of the moving unit to separate and collect the manufactured graphene powder from the graphite oxide powder or the graphene oxide powder; It may further include.

At this time, the collection unit includes a suction member that provides suction force to collect the graphene powder floating in the moving space as the laser is irradiated to the graphite oxide powder or the graphene oxide powder to form the graphene powder; and a collection container connected to the suction member to store the collected graphene powder. may include.

At this time, the suction member may be a cyclone hopper.

At this time, the collection unit includes a gas supply member that forms a flow so that the graphene powder can move along the movement space; It may further include.

At this time, the gas supplied by the gas supply member may be an inert gas.

At this time, the gas supply member is formed in plural pieces, a part of the gas supply member is disposed behind the area irradiated with the laser by the laser irradiation unit, and another part of the gas supply member is irradiated by the laser irradiation unit. The laser may be placed in front of the irradiated area.

At this time, a guide member protruding from the upper inner surface of the moving unit body may be formed to guide the flow formed by the gas supply member toward the collecting unit.

At this time, a recovery unit that recovers the graphite oxide powder or the graphene oxide powder moved to the other side of the moving unit and supplies it to the supply unit; It may further include.

The graphene production device according to an embodiment of the present invention can produce graphene without a complicated processing process by irradiating a laser to graphite oxide powder or graphene oxide powder.

Additionally, the graphene production device according to an embodiment of the present invention can continuously produce a large amount of graphene by providing graphite oxide powder or a moving part that continuously moves graphene oxide powder.

Additionally, the graphene production device according to an embodiment of the present invention can increase graphene production efficiency by providing a recovery unit to separate graphite oxide or graphene oxide that has not been converted into graphene after laser irradiation.

The effects of the present invention are not limited to the effects described above, and should be understood to include all effects that can be inferred from the configuration of the invention described in the description or claims of the present invention.

1 is a diagram illustrating graphite oxide powder or a movement state of graphene oxide powder in a graphene production apparatus according to an embodiment of the present invention.
Figure 2 is an enlarged view of the moving part of the graphene manufacturing apparatus according to an embodiment of the present invention.
Figure 3 is a diagram showing a laser irradiation state of a graphene manufacturing apparatus according to an embodiment of the present invention.
Figure 4 is an enlarged cross-sectional view showing AA of Figure 3.
Figure 5 is an enlarged perspective view showing a state in which a laser is irradiated to graphite oxide powder or graphene oxide powder of a graphene manufacturing apparatus according to an embodiment of the present invention.
Figure 6 is a diagram showing the Raman shift value of graphene manufactured under first experimental conditions using the graphene manufacturing method according to an embodiment of the present invention.
Figure 7 is a diagram showing the Raman shift value of graphene manufactured under second experimental conditions using the graphene manufacturing method according to an embodiment of the present invention.
Figure 8 is a diagram showing the Raman shift value of graphene manufactured under third experimental conditions using the graphene manufacturing method according to an embodiment of the present invention.
Figure 9 is a diagram showing the Raman shift value of graphene manufactured under fourth experimental conditions using the graphene manufacturing method according to an embodiment of the present invention.
Figure 10 is a diagram showing the Raman shift value of graphene manufactured under the fifth experimental condition using the graphene manufacturing method according to an embodiment of the present invention.

Hereinafter, with reference to the attached drawings, embodiments of the present invention will be described in detail so that those skilled in the art can easily implement the present invention. The present invention may be implemented in many different forms and is not limited to the embodiments described herein.

Unless otherwise defined, terms used in the embodiments of the present invention may be interpreted as meanings commonly known to those skilled in the art.

In order to clearly explain the present invention in the drawings, parts not related to the description are omitted, and identical or similar components are given the same reference numerals throughout the specification.

In order to clearly express the characteristics of the composition in the drawing, the thickness or size is exaggerated, and the thickness or size of the composition shown in the drawing is not shown in reality.

The present invention relates to a graphene production device, and provides a graphene production device that produces graphene powder by irradiating a laser to graphite oxide powder or graphene oxide powder.

1 is a diagram illustrating graphite oxide powder or a movement state of graphene oxide powder in a graphene production apparatus according to an embodiment of the present invention. Figure 2 is an enlarged view of the moving part of the graphene manufacturing apparatus according to an embodiment of the present invention. Figure 3 is a diagram showing a laser irradiation state of a graphene manufacturing apparatus according to an embodiment of the present invention. Figure 4 is an enlarged cross-sectional view taken along line A-A of Figure 3. Figure 5 is an enlarged perspective view showing a state in which a laser is irradiated to graphite oxide powder or graphene oxide powder of a graphene manufacturing apparatus according to an embodiment of the present invention.

As shown in Figure 1, the graphene manufacturing apparatus 1 according to an embodiment of the present invention includes a supply unit 100, a moving unit 200, a laser irradiation unit 300, a quartz substrate 230, and a collection unit ( 700).

As shown in FIG. 1, the supply unit 100 supplies graphite oxide powder or graphene oxide powder (G1). At this time, a supply port 110 through which graphite oxide powder or graphene oxide powder (G1) is discharged may be formed to protrude on one side of the supply unit 100.

The supply port 110 may be formed to extend in the width direction, and the graphite oxide powder or graphene oxide powder (G1) discharged through the supply port 110 may be continuously arranged to be distributed in a predetermined width (W). You can. Accordingly, the laser irradiation unit 300, which will be described later, can irradiate the laser L to the graphite oxide powder or graphene oxide powder G1 in a wide area.

As shown in FIG. 1, the moving part 200 is connected to the supply port 110 of the supply part 100. At this time, the moving unit 200 receives graphite oxide powder or graphene oxide powder (G1) from the supply unit 100 and moves the graphite oxide powder or graphene oxide powder (G1) from one side to the other side.

To explain this in more detail, the moving unit 200 of the graphene manufacturing apparatus 1 according to an embodiment of the present invention includes a moving unit body 210, a moving surface 212, and a moving space 211.

As shown in FIG. 1, a moving surface 212 is formed inside the moving unit body 210, has a predetermined width W and extends from one side in one direction. The moving surface 212 is formed on the lower side of the moving part body 210 along the direction of its own weight and serves as a movement path for the graphite oxide powder or graphene oxide powder (G1) supplied through the supply part 100.

A moving space 211 is formed on the upper side of the moving surface 212, and the moving space 211 extends in the longitudinal direction like the moving surface 212. At this time, the moving unit body 210 may be formed in a cylindrical shape as shown in FIG. 1, but there is no limitation thereto.

A supply port 110 is coupled to one side of the moving unit body 210, and thus the graphite oxide powder or graphene oxide powder (G1) supplied from the supply unit 100 is disposed on one side of the moving surface 212. At this time, the vibration generating unit 400 is coupled to the moving unit body 210.

The vibration generator 400 vibrates the moving unit body 210 so that the moving unit body 210 vibrates at a predetermined frequency. At this time, as shown in FIG. 2, the moving surface 212 is formed to have a predetermined angle with the axis C extending in the direction of its own weight. Through this, when the vibration generator 400 vibrates the moving part body 210, the graphite oxide powder or graphene oxide powder (G1) is separated from the moving surface 212 and moves back toward the moving surface 212 under gravity in the direction of its own weight. In the process of moving, it moves in one direction along the inclined moving surface 212.

At this time, the frequency of vibration generated by the vibration generator 400 may vary as needed. The moving speed of the graphite oxide powder or graphene oxide powder (G1) moving along the moving surface 212 may be 5 mm/s or more and 50 mm/s or less depending on the frequency, and may preferably be 16.67 mm/s. At this time, when the moving speed of the graphite oxide powder or graphene oxide powder (G1) moving along the moving surface 212 is 16.67 mm/s, the graphite oxide is irradiated by the laser (L) irradiated by the laser irradiation unit 300, which will be described later. The exposure time of the powder or graphene oxide powder (G1) may be 0.024 seconds.

When the graphite oxide powder or graphene oxide powder (G1) is moved in one direction by a separate moving means, a separation inevitably occurs between the separate moving means and the moving unit body 210, and the graphite oxide powder or graphene The oxide powder (G1) may unintentionally accumulate in the space created by the above-mentioned separation. Accordingly, not only does it cause a breakdown of the means of transportation, but the graphite oxide powder or graphene oxide powder (G1) may be lost, thereby reducing graphene production efficiency. Therefore, in this embodiment, the above problem can be prevented by moving the graphite oxide powder or graphene oxide powder (G1) along the moving surface 212 by vibration.

As shown in FIG. 3, the laser irradiation unit 300 irradiates the laser L to the graphite oxide powder or graphene oxide powder G1 moving along the moving surface 212 to generate graphite oxide powder or graphene oxide powder ( G1) is manufactured from graphene powder (G2).

At this time, when the graphite oxide powder or graphene oxide powder (G1) is exposed to the laser (L), the graphite oxide or graphene oxide is reduced to graphene, and the graphene powder (G2) formed by reduction is formed in the moving part body ( It floats in the moving space 211 of 210).

At this time, the intensity (LASER Power Intensity) of the laser L irradiated by the laser irradiation unit 300 may be 30 W/mm ² or more and 150 W/mm ^{2 or} less, and preferably 84,85 W/mm ² there is.

As shown in Figures 4 and 5, the laser L irradiated by the laser irradiation unit 300 is a linear laser extending in the width direction of the moving surface 212 perpendicular to the extending direction of the moving surface 212, that is, a line laser. You can. Accordingly, the graphite oxide powder or graphene oxide powder (G1) distributed in the width direction on the moving surface 212 moves in the extending direction of the moving surface 212, so that the area (A) to which the laser (L) is irradiated can be expanded. do. Accordingly, more graphene powder (G2) can be manufactured.

The laser irradiation unit 300 may be disposed on the outside of the moving unit body 210. Accordingly, the laser L penetrates the laser irradiating unit 300 side of the moving unit body 210 to produce graphite oxide powder or graphene oxide powder. A lens 240 may be provided to reach (G1). Any known lens may be used as the lens 240, and there is no limitation on the shape or material of the lens 240.

By arranging the laser irradiation unit 300 on the outside, the movement flow of the graphene powder G2 can be smoothened, as will be described later. In addition, by providing the lens 240 to prevent the moving space 211 of the moving part body 210 from being exposed to the outside for laser (L) irradiation, the graphene powder (G2) produced during laser irradiation is prevented from being exposed to the outside of the moving part body 210. It is possible to prevent leakage to the outside of the body 210.

As shown in FIGS. 3, 4, and 5, a quartz substrate 230 is formed as a part of the moving surface 212 of the moving unit body 210 in the area where the laser L is irradiated. The quartz substrate 230 prevents the moving unit body 210 from being damaged by the laser L.

At this time, since the quartz substrate 230 and the moving unit body 210 are formed as one body, it is possible to prevent steps from occurring on the moving surface 212. Through this, it is possible to prevent the graphite oxide powder or graphene oxide powder (G1) from accumulating between the quartz substrate 230 and the moving part body 210, thereby impeding the smooth movement of the graphite oxide powder or graphene oxide powder (G1). It becomes possible.

Meanwhile, as shown in FIG. 3, the collection unit 700 converts the graphene powder (G2) generated by exposing the graphite oxide powder or graphene oxide powder (G1) to the laser (L) into graphite oxide powder or graphene oxide powder. Collect separately from powder (G1).

At this time, the collecting part 700 is coupled to the other side of the moving part body 210. More specifically, the collecting part is formed on the other side of the moving part body 210 to enable fluid communication between the moving space 211 and the outside. It is combined with (260). The collection unit 700 separates the graphene powder (G2) from the graphite oxide powder or graphene oxide powder (G1) by sucking the graphene powder (G2) floating in the moving space 211 through the collection port 260. This makes it possible to capture it.

To this end, the collection unit 700 of the graphene production apparatus 1 according to an embodiment of the present invention is provided with a suction member 710 and a collection container 720.

As shown in FIG. 3, one side of the suction member 710 is coupled to the collecting port 260 and provides suction force through the collecting port 260. At this time, various known methods by which the suction member 710 provides suction force may be used. For example, suction member 710 may be a cyclone hopper suitable for collecting powder.

A collection container 720 in which the graphene powder (G2) discharged through the collection port 260 by the suction member 710 can be stored is coupled to the other side of the suction member 710. The collection container 720 is not limited in shape as long as it can provide a space where the graphene powder (G2) can be stored.

Meanwhile, the graphene manufacturing apparatus 1 according to an embodiment of the present invention may further include a gas supply member 500 and a guide member 220.

The gas supply member 500 forms a gas flow so that the graphene powder (G2) floating in the moving space 211 can be moved to one side of the moving part body 210, that is, to the collecting port 260 side.

For this purpose, the gas supply member 500 supplies gas to the collection port 260. At this time, the gas supply member 500 forms a gas flow by supplying gas at a fine intensity so that the graphite oxide powder or graphene oxide powder (G1) does not float.

The gas supplied from the gas supply member 500 may be an inert gas such as nitrogen to prevent the gas from reacting with the graphene powder (G2).

Additionally, as shown in FIG. 3, the gas supply members 500 may be formed in plural numbers to move the graphene powder G2 more efficiently. There is no limit to the number of gas supply members 500, and in this embodiment, the first gas supply member 500a and the second gas supply member 500b are disposed.

As shown in FIG. 3, the first gas supply member 500a is in front of the area A where the laser irradiation unit 300 irradiates the laser L and moves the graphite oxide powder or graphene oxide powder G1. The direction side and rear may be disposed on the side opposite to the movement direction of the graphite oxide powder or graphene oxide powder (G1). Accordingly, the graphene powder (G2) suspended by laser (L) irradiation is prevented from moving to the rear of the movement space 211 and is induced to move to the collection hole 260.

At this time, as shown in FIG. 3, the moving unit body ( A guide member 220 protruding from the inner upper side of 210 may be formed.

As shown in FIG. 3, the guide member 220 may be formed with an inclination so that the graphene powder G2 moves adjacent to the collecting hole 260.

Meanwhile, the graphene manufacturing apparatus 1 according to an embodiment of the present invention may further include a recovery unit 600.

The recovery unit 600 recovers the graphite oxide powder or graphene oxide powder (G1) that has not been reduced to graphene even after irradiation with the laser (L) and supplies it to the supply unit 100 to produce graphite oxide powder or graphene oxide powder ( G1) is continuously exposed to the laser (L) so that it can be reduced to graphene.

The recovery unit 600 is disposed on the other side of the moving unit body 210, and there is no limit to the location in front of the area A to which the laser L is irradiated.

There is no limitation to the method by which the recovery unit 600 moves the graphite oxide powder or graphene oxide powder (G1) to the supply unit 100. In this embodiment, for this purpose, the recovery unit 600 uses the recovery guide member 610 and the recovery guide member 610. A moving member 620 may be provided.

As shown in FIG. 3, the recovery guide member 610 is coupled to the recovery port 250 formed on the other side of the moving unit body 210. The recovery port 250 is formed to penetrate downward on the other side of the moving surface 212, and the graphite oxide powder or graphene oxide powder (G1) moving along the moving surface 212 is moved through the recovery port 250 to the moving unit body ( 210) is discharged to the outside.

The graphite oxide powder or graphene oxide powder (G1) discharged through the recovery port 250 is guided by the recovery guide member 610 and moves to the moving member 620. The moving member 620 moves the graphite oxide powder or graphene oxide powder (G1) to the supply unit 100, and the supply unit 100, which has received the graphite oxide powder or graphene oxide powder (G1), returns to the supply port ( Graphite oxide powder or graphene oxide powder (G1) is supplied to the moving part body 210 through 110). At this time, the moving member 620 may be a variety of known parts used to move the graphite oxide powder or graphene oxide powder (G1), but is not limited.

Hereinafter, with reference to FIGS. 6 to 10, the relationship between the intensity per unit area of the laser (L) and the purity of graphene in the graphene production method according to another embodiment of the present invention will be examined. Figure 6 is a diagram showing the Raman shift value of graphene manufactured under first experimental conditions using the graphene manufacturing method according to an embodiment of the present invention. Figure 7 is a diagram showing the Raman shift value of graphene manufactured under second experimental conditions using the graphene manufacturing method according to an embodiment of the present invention. Figure 8 is a diagram showing the Raman shift value of graphene manufactured under third experimental conditions using the graphene manufacturing method according to an embodiment of the present invention. Figure 9 is a diagram showing the Raman shift value of graphene manufactured under fourth experimental conditions using the graphene manufacturing method according to an embodiment of the present invention. Figure 10 is a diagram showing the Raman shift value of graphene manufactured under the fifth experimental condition using the graphene manufacturing method according to an embodiment of the present invention.

By irradiating a laser (L) to graphite oxide or graphene oxide, the residual oxygen impurity content is 3 to 5% when converted to graphene, and high quality graphene can be produced. At this time, the Raman shift value can be checked by irradiating light to determine the degree to which graphite oxide or graphene oxide is reduced to graphene.

When the degree of reduction to graphene is high, the G peak value of the Raman shift value comes out higher than the D peak value, and the 2D peak value comes out higher than in other experiments.

The experimental conditions of FIGS. 6 to 10 are that when the graphene oxide powder (G1) moves at 16.67 mm/s, the area to which the laser (L) is irradiated is linear and has an area of 132 mm ² , and the maximum The output is 16 W, and it is assumed that the graphene oxide powder (G1) moves once when the laser (L) is irradiated.

The six first experiments conducted individually in Figure 6 are the results of testing the output of the laser (L) at 30% of the maximum output, and accordingly, the intensity per unit area of the laser (L) is 36.36 W/mm ² , and the unit area The exposure time to this laser (L) is 0.024 s.

The second experiment of six individually conducted in Figure 7 is the result of testing the output of the laser (L) at 50% of the maximum output. Accordingly, the intensity per unit area of the laser (L) is 60.61 W/mm ² , and the unit area The exposure time to this laser (L) is 0.024 s.

The third experiment, performed six times individually in Figure 8, is the result of testing the output of the laser (L) at 70% of the maximum output. Accordingly, the intensity per unit area of the laser (L) is 84.85 W/mm ² , and the unit area The exposure time to this laser (L) is 0.024 s.

The fourth experiment of six cases conducted individually in Figure 9 is the result of testing the output of the laser (L) at 90% of the maximum output, and accordingly, the intensity per unit area of the laser (L) is 109.09 W/mm ² , and the unit area The exposure time to this laser (L) is 0.024 s.

The fifth experiment of six cases conducted individually in Figure 10 is the result of testing the output of the laser (L) at 100% of the maximum output. Accordingly, the intensity per unit area of the laser (L) is 121.21 W/mm ² , and the unit area The exposure time to this laser (L) is 0.024 s.

As can be seen in Figures 6 to 10, the times when the D peak value becomes relatively small and the G peak value becomes large are the third, fourth, and fifth experiments, and the results of the third, fourth, and fifth experiments Since there is no significant difference, high purity graphene can be manufactured when the intensity per unit area of the laser (L) is at least 70 W/mm ² or more for efficient power use of the laser (L), and the unit of laser (L) is Graphene of optimal purity can be produced when the intensity per area is 84.85 W/mm ² .

Although the graphene manufacturing apparatus according to various embodiments of the present invention has been described above, the graphene manufacturing apparatus according to this embodiment is not applicable only for graphene manufacturing, and continuously irradiates the provided raw materials with a laser. Therefore, it will be clear to those skilled in the art that the present invention can be used as a device for manufacturing a specific material.

As described above, the preferred embodiments according to the present invention have been examined, and the fact that the present invention can be embodied in other specific forms in addition to the embodiments described above without departing from the spirit or scope thereof is recognized by those skilled in the art. It is self-evident to them. Therefore, the above-described embodiments should be considered illustrative rather than restrictive, and accordingly, the present invention is not limited to the above description but may be modified within the scope of the appended claims and their equivalents.

1 Graphene manufacturing device 500 gas supply absence
100 Supply Department 600 Recovery Department
110 Supply port 610 Recovery guide member
200 moving part 620 moving member
210 body 700 collection unit
211 moving space 710 suction member
212 Dongmyeon 720 Collection container
220 guide member 500a first gas supply member
230 Quartz substrate 500b second gas supply member
240 Lens A Laser irradiation area
250 recovery port
G1 graphite oxide powder or graphene oxide powder
260 collection port G2 graphene powder
300 Laser irradiation unit L laser
400 Vibration generation area W width

Claims (16)

A supply unit that supplies graphite oxide powder or graphene oxide powder;
The supply unit is coupled to one side, has a moving surface inside which has a predetermined width and extends from one side in one direction, and has a moving unit body with a moving space formed on an upper side of the moving surface, and the graphite oxide powder supplied from the supply unit or the A moving part that receives graphene oxide powder from one side of the moving space and moves it to the other side;
A laser irradiation unit that irradiates a laser on a movement path of the graphite oxide powder or the graphene oxide powder to produce the graphite oxide powder or the graphene oxide powder into graphene powder;
A collection unit connected to the other side of the moving unit to separate and collect the graphene powder from the graphite oxide powder or the graphene oxide powder; and
a vibration generator disposed on one side of the moving unit body and generating vibration; Including,
The moving surface is formed to have a predetermined angle with the direction of its own weight,
The vibration generator transmits the vibration to the moving unit body to move the graphite oxide powder or the graphene oxide powder along the moving surface. According to claim 1,
The laser irradiation unit irradiates a linear laser extending in the width direction of the moving surface. According to claim 1,
The supply unit supplies the graphite oxide powder or the graphene oxide powder to one side of the moving surface so that the graphite oxide powder or the graphene oxide powder is distributed in the width direction. According to clause 2,
The laser power intensity of the laser irradiation unit is 30 W/mm ² or more and 150 W/mm ² or less. According to clause 4,
The speed at which the moving part moves the graphite oxide powder or the graphene oxide powder is 5 mm/s or more and 50 mm/s or less. delete According to claim 1,
a quartz substrate formed in an area where the laser irradiation unit irradiates the laser; A graphene manufacturing device further comprising: According to clause 7,
The graphene manufacturing device, wherein the quartz substrate is formed integrally with the moving unit body. According to claim 1,
The laser irradiation unit is disposed outside the moving unit,
a lens formed on the body of the moving unit so that the laser irradiated from the laser irradiation unit passes through and reaches the moving surface; A graphene manufacturing device further comprising: According to claim 1,
The collection unit
A suction member that provides suction force to collect the graphene powder floating in the moving space as the laser is irradiated to the graphite oxide powder or the graphene oxide powder to form the graphene powder; and
A collection container connected to the suction member to store the collected graphene powder; Graphene manufacturing device comprising: According to claim 10,
Graphene manufacturing apparatus, wherein the suction member is a cyclone hopper. According to claim 10,
The collection unit includes a gas supply member that forms a flow so that the graphene powder can move along the movement space; A graphene manufacturing device further comprising: According to claim 12,
Graphene manufacturing apparatus, wherein the gas supplied by the gas supply member is an inert gas. According to claim 12,
The gas supply member is formed in plural pieces,
A portion of the gas supply member is disposed behind the area irradiated with the laser by the laser irradiation unit,
Another part of the gas supply member is disposed in front of the area irradiated with the laser by the laser irradiation unit. According to claim 12,
A graphene manufacturing apparatus in which a guide member protruding from an upper inner surface of the moving unit body is formed to guide the flow formed by the gas supply member toward the collecting unit. According to claim 1,
a recovery unit that recovers the graphite oxide powder or the graphene oxide powder moved to the other side of the moving unit and supplies it to the supply unit; A graphene manufacturing device further comprising:

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