KR20190058408A - Graphene oxide classification device - Google Patents

Abstract

Provided is a graphene oxide classifier capable of mass classification in an effective manner. The graphene oxide classifier according to the present invention comprises: a graphene oxide charging unit into which graphene oxide is charged; a blowing unit disposed at a lower end of the charging unit; a mesh filter disposed at an upper end of the charging unit; and a graphene oxide collecting unit disposed at a side of the mesh filter.

Description

Graphene oxide classification device [0001]

The present invention relates to an apparatus for classifying oxidized graphene, and more particularly to an apparatus for mass classifying oxidized graphene as a part of a process for producing oxidized graphene.

Graphite has a structure in which graphenes, which are plate-like two-dimensional sheets in which carbon atoms are formed into hexagonal shapes, are laminated. Graphite is excellent in electrical conductivity and thermal conductivity, and has an advantage of high mechanical strength, high elasticity and high transparency. It is also useful as an energy storage material such as a secondary battery, a fuel cell, a supercapacitor, a filter film, a chemical detector, And can be used in a variety of applications.

Since grephene, which is obtained by oxidizing graphite and separating it into several layers and then reducing it again, has excellent physical properties such as high thermal conductivity, high current transfer ability and excellent rigidity, , Optoelectronic devices, and high performance composites.

Graphene can generally be produced by chemical vapor deposition (CVD), chemical synthesis (graphite oxidation), or the like. Since the announcement that graphene can be produced by a mechanical stripping method known as the so-called Scotch tape method, many technologies have been researched and classified.

Among these methods, the chemical synthesis method capable of producing graphene at a relatively low cost as well as mass production using the top down method is known as the most realistic and simple method.

The chemical synthesis method is roughly described as follows. The graphite is oxidized to a strong acid and dispersed and separated by graphene oxide (GO), and then the GO is reduced through heat treatment to obtain reduced graphene oxide (rGO ). In other words, oxidized graphene corresponds to the raw material of graphene, which is a key starting material in the graphene based industry.

However, in the conventional method (Hummer's method) for producing oxidized graphene using the chemical synthesis method as described above, the interlayer distance of the graphite is very narrow to 0.34 nm, so that it takes a long time 2 to 5 days), which makes it difficult to produce competitive oxide graphene.

In order to shorten the manufacturing time, a method of adjusting the reaction rate through strong acid and temperature control has been proposed. However, in this case, environmental problems due to the increase of the waste acid solution and the cost for treating them are increased. This is the reason why the problem of manufacturing graphene oxide by chemical synthesis method is reduced and the environment-friendly method is being sought.

In order to continuously and mass-produce the graphene oxide through the chemical synthesis method, it is important to design the subsequent process suitable for continuous mass production as well as to cause interlayer chemical reaction in a short time. The subsequent processes include washing, peeling, drying, and classification.

Classification by size of oxidized graphene is an important subsequent process. When an application product is to be manufactured using oxidized graphene, a large amount of graphene oxide having a certain size suitable for the purpose is required. In order to meet such a demand, a large amount of oxidized graphene The process of selectively collecting graphene is essential.

In the case of classifying dried graphene grains using an existing graphen oscillator, due to the oxygen functional groups on the surface of the graphene oxide, the graphene grains are agglomerated to form small graphene grains and large graphene graphenes There was a problem that classification did not work well. Therefore, there is a need for a technique capable of preventing the re-agglomeration of dried graphene grains and classifying them easily by size.

SUMMARY OF THE INVENTION An object of the present invention is to provide an apparatus for classifying oxidized graphene capable of mass classification.

The apparatus for classifying oxidized graphene according to the present invention can prevent re-agglomeration of oxidized graphene, which is a disadvantage of the conventional classification method, and can classify large amounts of oxidized graphene.

According to a preferred embodiment of the present invention, the apparatus for classifying oxidized graphene comprises: an oxidized graphene input unit into which graphene oxide is charged; A blowing unit disposed at a lower end of the input unit; A mesh filter disposed at an upper end of the charging unit; And a graphene graphene located at the side of the mesh filter.

According to another preferred embodiment of the present invention, the oxidative graphene classifying apparatus further includes a device for imparting up-and-down or left-and-right vibrations to the oxidizing graphene charging section or the mesh filter.

According to another preferred embodiment of the present invention, the graphene oxide grafting unit is a detachable tray and is connected to a blower unit, and the blower unit is connected to the injector unit to blow upward in the lower part of the injector unit.

According to another preferred embodiment of the present invention, the mesh filter is one layer or two or more layers.

According to another preferred embodiment of the present invention, the mesh filter having two or more different pore sizes and located in close proximity to the oxide graphene inlet in the order of larger pore size.

According to another preferred embodiment of the present invention, the graphene trapping portion is an air suction type.

According to another preferred embodiment of the present invention, there is provided a graphite oxidation unit comprising: a graphite oxidation unit; A cleaning unit in which the oxidized graphite oxidized in the graphite oxidation unit is washed; A peeling unit in which the oxidized graphite washed in the cleaning unit is peeled off to form oxidized graphene; A drying unit in which the oxidized graphene is dried; And an oxidized graphene classifying unit according to claim 1, wherein the dried oxidized graphene is classified by size.

Wherein the graphite oxidation unit comprises: a first cylindrical portion having a first diameter; A second cylindrical portion having a second diameter larger than the first diameter and having the same rotation center as the first cylindrical portion; A graphite inlet for injecting graphite to be subjected to shear stress by rotation of the first cylindrical portion between the first cylindrical portion and the second cylindrical portion; An oxidant input port for inputting an oxidant for oxidizing the graphite; And an oxide graphite outlet through which oxidized graphite oxidized by the oxidant is discharged, wherein the oxidized graphite discharge portion and the oxidized graphite cleaning unit are connected to each other, and the cleaning unit and the peeling unit are connected to each other, And the drying unit are connected to each other, and the drying unit and the classification unit are connected to each other.

The present invention provides an apparatus for classifying oxidized graphene, which can prevent re-agglomeration of oxidized graphene which is a disadvantage of the conventional classification method, and can classify large amounts of oxidized graphene, shortening the time required for the classification process, There is an effect of reducing the manufacturing cost of graphene.

In addition, by providing an apparatus for producing an oxidized graphene by connecting the oxidized graphene classifying apparatus according to the present invention to the oxidized graphite drying unit, it is possible to efficiently perform a series of processes from the oxidation of graphite to the preparation of oxidized graphene .

1 is a schematic view of an apparatus for classifying oxidized graphene according to an embodiment of the present invention.
FIG. 2 is a cross-sectional view of an apparatus for producing an oxide graphene according to another embodiment of the present invention, and FIG. 3 is a sectional view of the graphite oxidizing unit in an apparatus for producing an oxide graphene.
4 is a cross-sectional view of an apparatus for manufacturing an oxide graphene according to another embodiment of the present invention.

DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings. However, the embodiments of the present invention can be modified into various other forms, and the scope of the present invention is not limited to the embodiments described below. The embodiments of the present invention are provided to enable those skilled in the art to more fully understand the present invention. It should be understood that while the present invention may be embodied in many different forms and should not be construed as limited to the embodiments set forth herein, The present invention is not limited thereto.

1 is a schematic view of an apparatus for classifying oxidized graphene according to an embodiment of the present invention. The apparatus for classifying oxidized graphene according to the present invention comprises: an oxidized graphene charging unit into which graphene oxide is charged; A blowing unit disposed at a lower end of the input unit; A mesh filter disposed at an upper end of the charging unit; And a graphene graphene located at the side of the mesh filter.

The oxidizing graphene charging portion is located at the lower end of the cylindrical oxidizing graphene classifying device. It is preferable to use a tray type which can be detached and attached to easily insert graphene oxide. The tray is removed from the classifier, and the graphene grains to be classified are placed in a tray, which is then coupled to the classifier. The lower end of the tray is made of a mesh so that wind can be easily introduced from the blower, and an auxiliary plate is further required to prevent the graft from coming off the mesh when removing the tray and introducing the graphene. After the oxide graphene is placed in the tray and the tray is attached to the classification device, the support plate is removed. The graphene grains to be classified are preferably in powder form.

The blower is located at the bottom of the oxidizing graphene inlet. Anything that is fan-shaped and that can send out the wind is okay. The blower blows air from the lower portion of the graphene graining portion to the upper portion. For the blowing, it is desirable to remove the auxiliary plate of the grafting portion of the oxidizing grains and to operate the blowing device simultaneously with the removal of the auxiliary plate.

The mesh filter can select the mesh size according to the size of the oxidized graphene to be classified. The mesh filter is one layer or two or more layers.

Mesh filters of two or more layers with different hole sizes are positioned closer to the grafting graphene tray from the larger holes. When the blowing device is operated, the oxidized graphene moves in the direction of the upper part of the classification device with the wind, and the oxidized graphene having a size larger than the mesh size can not move to the upper portion of the mesh, It is possible to classify the graphene oxide by using it.

The graphene grains classified according to the mesh size are collected by the collecting part. The collecting part is located on the side of the mesh filter by air intake type and sucks and collects the classified graphene graft between the mesh filter and the mesh filter. The collection section includes a storage space below the inlet so that the sucked oxide graphene does not flow back to the mesh filter.

In the oxidative graphene classifier, the oxidized graphene is pulverized in the form of powder. In the classification process, the oxidized graphene powder may clump in the input portion or the mesh filter. This degrades the classification efficiency, so the graphene oxide powder must be evenly spread by an appropriate method. Therefore, the oxidative graphene classifier of the present invention may further include a device for imparting vibration to the graphene oxide input portion or the mesh filter. The vibration can be applied in the vertical direction or the horizontal direction of the classifier, but in consideration of the blowing direction, it is preferable that the graphene oxide input portion is vertical vibration and the mesh filter is horizontal vibration.

FIG. 2 is a cross-sectional view of an apparatus for producing an oxide graphene according to another embodiment of the present invention, and FIG. 3 is a sectional view of the graphite oxidizing unit in an apparatus for producing an oxide graphene. According to this embodiment, a graphite oxidation unit 210; An oxidized graphite cleaning unit 220 in which the oxidized graphite in the graphite oxidation unit 210 is washed; A peeling unit (230) for peeling the oxidized graphite washed in the cleaning unit to become oxidized graphene; An oxidized graphene drying unit 240 for drying the oxidized graphene; And a classifying unit (250) for classifying the dried graphene grains (200).

The apparatus 200 for producing an oxide graphene according to the present embodiment includes a graphite oxidizing unit 210 for oxidizing graphite and an oxidized graphite cleaning unit 220 for oxidizing oxidized graphite, a peeling unit 230 for peeling the washed oxidized graphite, A drying unit 240 for drying the oxidized graphene, and a classifying unit 250 for classifying the dried oxidized graphene.

The graphite oxidizing unit 210 includes an oxidized graphite outlet 211 through which graphite is injected and an oxidized graphite outlet 212 through which oxidized oxidized graphite is discharged, (220). The graphite can be oxidized using an oxidizing agent or the like. An oxidizing agent or a strong acid or a solvent for oxidizing the graphite may be introduced through an oxidizing agent inlet (not shown).

When the oxidized graphite 224 is injected from the graphite oxidation unit 210 through the oxidized graphite cleaning unit 222, the cleaning solution is introduced into the cleaning solution unit 223 through the cleaning solution input unit 225, The cleaning liquid flows to the oxidized graphite cleaning portion 222, and the oxidized graphite 224 is cleaned. After the cleaning, the cleaning liquid is discharged through the cleaning liquid discharging portion 226 and the oxidized graphite discharged through the oxidizing graphite outlet 227 is obtained.

The oxidized graphite washed in the oxidized graphite cleaning unit 220 is introduced into the oxidized graphite peeling unit 230 and the oxidized graphite peeling unit 230 applies ultrasonic waves to the oxidized graphite or a double fluid flow Vortex is applied and peeled off with graphene oxide. The oxidized graphene is discharged to the oxidized graphene discharge port 232.

The oxidized graphene peeled off from the oxidized graphite peeling unit 230 is supplied to the oxidized graphene drying unit 240. In the oxidized graphene drying unit 240, heat of 200 DEG C or less is applied to the oxidized graphene, And dried. The dried graphene graphene is collected at the collecting portion 242.

The oxidized graphene dried in the oxidized graphene drying unit 240 is supplied to the oxidized graphene classifying unit 250. In the oxidized graphene classifying unit 250, the oxidized graphene powder is blown and classified through the mesh filter . The classified graphene graphene is collected by size and finally used in the apparatus 200 for producing an oxidized graphene of the present embodiment. When the graphite is charged into the graphite inlet 211, the graphene oxide graphene is classified through the graphene graphene collector 254 Oxidation graphene can be obtained in one system.

The graphite oxidation unit 210 is a unit in which graphite, an oxidizing agent and the like are mixed to obtain oxidized graphite. For example, the graphite oxidation unit 210 may be a unit using a Kuett-Taylor reactor. 3 is a cross-sectional view of a graphite oxidation unit using a Kuett-Taylor reactor in an apparatus for producing an oxide graphene.

Graphite is a two-dimensional material having a layered structure. In order to be oxidized, the oxidant must penetrate into the interlayer. For this purpose, the graphite can be oxidized by mixing the graphite and the oxidizing agent while mixing the strong acids together or increasing the reactivity by applying ultrasonic waves. In this embodiment, when the graphite is mixed with the oxidizing agent, the reactivity of the graphite is increased by using a Kuett-Taylor reactor so that the oxidation reaction can proceed in a short time.

The Couette-Taylor reactor is a device using a spiral vortex called a Taylor vortex. In the Couette-Taylor reactor, when the fluid flows between two cylinders having the same center as in FIG. 3, the inner cylinder 214 rotates, and the fluid flows in the rotating direction. At this time, due to the centrifugal force and the Coriolis force, the fluids on the inner cylinder 214 side are forced to move in the direction of the outer cylinder 215 and gradually become unstable as the rotation speed increases, A vortex of the high-paired array rotating in the opposite direction is formed.

This spiral vortex imparts shear stress to two-dimensional materials with layered structures such as graphite, which forces each layer in parallel to each layer of two-dimensional material with layered structure, making each layer more prone to spread .

That is, when a dispersion liquid in which a two-dimensional material having a layered structure is dispersed in the graphite inlet 211 in the graphite oxidation unit 210 is introduced, the fluid flows in a direction different from the first fluid flow 216-1 in accordance with the rotation of the inner cylinder A second fluid flow 216-2 is formed so that the dual fluid flow 216 is applied to a two-dimensional material having a layered structure. Accordingly, the two-dimensional material having a layered structure is increased in reactivity, reacted with the reactive material, or collapsed into a smaller number of layers and discharged to the oxidized graphite outlet 212.

Such a Kuett-Taylor reactor can be used not only as an oxidizing graphite but also as an oxidizing graphite peeling apparatus in forming oxidized graphene, as well as oxidizing the graphite, and oxidizing the washed oxidized graphite again. In this regard, it will be explained again in the description of FIG. 4 below.

4 is a cross-sectional view of an apparatus 400 for manufacturing an oxide graphene according to another embodiment of the present invention. In the present embodiment, the same explanations as those described above regarding the graphite oxidation unit 410, the oxidized graphite cleaning unit 420, the oxidized graphene drying unit 430 and the oxidized graphene classification unit 440 are omitted. In this embodiment, the oxidative graphene production apparatus 400 includes only the graphite oxidization unit 410, the oxidized graphite cleaning unit 420, the oxidized graphene drying unit 430 and the oxidized graphene classifying unit 440, The oxidized graphite washed in the oxidized graphite cleaning unit 420 is introduced into the graphite oxidizing unit 410 through the connecting portion 428 through the oxidized graphite inlet 414.

Since the oxidized graphite can be peeled off with the oxidized graphene in the graphite oxidizing unit 410, the oxidized graphene producing apparatus 400 according to the present embodiment can remove the oxidized graphite together with the graphite oxidizing unit 410, , And it is possible to manufacture graphene oxide by injecting graphite in a simpler system configuration.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, many modifications and changes may be made by those skilled in the art without departing from the spirit and scope of the invention as defined in the appended claims. The present invention can be variously modified and changed by those skilled in the art, and it is also within the scope of the present invention.

200, 400 Oxide graphene manufacturing equipment
210, 410 Graphite oxidation unit
211, 411 Graphite inlet
212, 412 oxidized graphite outlet
213, 228, 233, 413, 416, 428,
214 inner cylinder 215 outer cylinder
216 Dual fluid flow
220, 420 oxidized graphite cleaning unit
221, 421 filter unit
222, 422 oxidized graphite cleaning section
223 and 423,
224, 424 Oxidized graphite
225, 425 cleaning liquid input portion
226, 426,
227, 427 oxidized graphite discharge portion
230 oxidized graphite peeling unit
231, 414 oxidized graphite inlet
232, 415 Oxide graphene outlet
240, 430 Oxide graphene drying unit
241, 431 Oxide graphene supply part
242, 254, 432, 444 Oxidation graphene collection part
250, 440 Oxide graphene classifying unit
251, 441 Oxidation of graphene
252, 442 blower
253, 443 mesh filter

Claims (2)

In the classifying apparatus for graphene oxide,
A graining type oxide graft, which is a tray type in which graphene oxide is injected and can be detached;
A blowing unit disposed at a lower end of the input unit;
A mesh filter located at the upper end of the charging unit and having one or more layers; And
And a graphene graphene located at a side of the mesh filter,
Wherein the lower end of the oxidizing graphene charging portion is made of a mesh and includes an assisting plate for preventing the graphene oxide from escaping from the mesh when the oxidizing graphene is charged,
The oxidizing graphene injecting portion is connected to the blowing device, and the blowing device is connected to the injecting portion and blows upward in the lower portion of the introducing portion,
And a device for vibrating the graphene oxide input portion up and down or for vibrating the mesh filter from side to side,
Wherein when the mesh filter has two or more layers having different hole sizes, the mesh filter is positioned in close proximity to the graphene input portion in order of increasing hole size. A graphite oxidation unit;
A cleaning unit in which the oxidized graphite oxidized in the graphite oxidation unit is washed;
A peeling unit in which the oxidized graphite washed in the cleaning unit is peeled off to form oxidized graphene;
A drying unit in which the oxidized graphene is dried; And
And an oxidizing graphene classifying device according to claim 1, wherein the dried oxidized graphene is classified by size,
The graphite oxidation unit
A first cylindrical portion having a first diameter;
A second cylindrical portion having a second diameter larger than the first diameter and having the same rotation center as the first cylindrical portion;
A graphite inlet for injecting graphite to be subjected to shear stress by rotation of the first cylindrical portion between the first cylindrical portion and the second cylindrical portion;
An oxidant input port for inputting an oxidant for oxidizing the graphite; And
And an oxidized graphite outlet through which the oxidized graphite oxidized by the oxidant is discharged,
Wherein the oxidized graphite discharge portion and the oxidized graphite cleaning unit are connected to each other, the cleaning unit and the peeling unit are connected to each other, the peeling unit and the drying unit are connected to each other, and the drying unit and the classifying device are connected Gt; oxide graphene < / RTI &

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