KR20030004526A - Apparatus for recycling powder of waste materials using atmospheric pressure plasma surface treatment - Google Patents

Abstract

PURPOSE: An apparatus is provided which recycles the waste materials by reforming the surface of powder that is manufactured from recyclable materials such a waste tire or weather strip using atmospheric pressure plasma surface treatment. CONSTITUTION: The apparatus for recycling powder of waste materials using atmospheric pressure plasma surface treatment comprises a means for introducing powder in the discharge pipe by gas; a discharge pipe(120) for generating plasma by atmospheric pressure dielectric discharging the gas using an electric source impressed to electrodes and reforming the surface of the powder using the plasma; and a separation means for exhausting the gas into the outside and supplying the powder into the introduction means again by receiving and separating the powder and gas primarily reformed in the discharge pipe into gas and powder, wherein the introduction means comprises a powder injection pipe(112) into which powder is introduced from the separation means, and a gas injection pipe(106) into which gas in injected, a nozzle(108) is installed adjacently to a position (A) where the powder injection pipe(112) meets the gas injection pipe(106) so that a low pressure zone is formed in the side of the powder injection pipe(112), the separation means is a cyclone(140), and the discharge pipe(120) comprises a tubular conductive working electrode(122), a tubular dielectric injection pipe(124) formed inside the working electrode, and a ground electrode(126) formed in the injection pipe.

Description

Apparatus for recycling powder of waste materials using atmospheric pressure plasma surface treatment}

The present invention relates to an apparatus for recycling a surface of a recyclable product, such as waste tires or weather strips, into a powder form by using an atmospheric pressure plasma treatment apparatus.

Recently, with increasing interest in environmental issues, various researches have been attempted to recycle waste resources such as tires and waste rubber, but the most widely used methods for treating such waste resources are incineration heat and powder use. And so on. Among them, a method of recycling the waste resources to be recycled is a powdering method. As the powdering method, a normal temperature grinding method or a nitrogen freezing grinding method is used.

However, in the case of recycling waste tires or waste rubber by powdering, the crushed rubber powder has strong CS and SS bonding on the surface of sulfur used for curing. Crosslinking between the powder particles, which is essential for maintaining the tensile strength, is not well performed, and thus, the tensile strength is low, which makes it difficult to recycle.

In order to solve this problem, it is necessary to surface-treat the powders to facilitate crosslinking. In the conventional method of reprocessing the powder, the chamber is evacuated to evenly rotate the powder like a watermill. That's the way. That is, after the vacuum is formed for a predetermined time while the powder is charged, the plasma discharge is formed in the vacuum while the discharge gas is introduced. After the plasma treatment is completed, a series of processes of venting to normal pressure, removing the powder, and charging the powder to form a vacuum are repeated.

However, such a conventional method requires expensive vacuum equipment because a vacuum must be formed for plasma processing, and it is difficult to construct an apparatus for uniform treatment of powder. Moreover, as it progresses in a vacuum, it is impossible to process powder continuously and there are many process losses when processing in large quantities. In addition, when processing for a long time takes the auxiliary equipment for cooling due to the temperature rise, in the case of rubber powder has a problem that loses the properties of the rubber if the temperature rises above a certain level.

The present invention has been proposed in order to solve the above problems, and because it discharges at normal pressure can not only rotate the powder continuously, but also use a cyclone to prevent the powder agglomeration, so that the collected powder can be rotated uniformly An object of the present invention is to provide a powder recycling apparatus using atmospheric pressure plasma in which a low pressure region is locally formed.

1 is a block diagram showing an apparatus for recycling powder using atmospheric pressure plasma according to the present invention;

FIG. 2 is an enlarged view of a portion A shown in FIG. 1;

3 is a flowchart illustrating an operation procedure according to the present invention;

Figure 4 is a graph showing the tensile strength of the rubber powder before the surface treatment according to the present invention,

5 is a graph showing the tensile strength of the plasma-treated rubber powder in accordance with the present invention.

* Explanation of symbols for main parts of the drawings

104,144: valve 106: gas inlet pipe

108: nozzle 110: first passage

120: discharge tube 132: second passage

140: cyclone 112: powder injection tube

142: gas discharge pipe

In order to achieve the above object, the apparatus of the present invention, the pulling means for introducing the powder into the discharge tube by the gas; A discharge tube for generating a plasma by performing atmospheric pressure dielectric discharge of the gas with a power applied to an electrode, and modifying the surface of the powder by the plasma; Receiving the primary reformed powder and gas from the discharge tube, the gas and the powder is separated and the gas is discharged to the outside, the powder is characterized in that consisting of the separating means for providing to the inlet means again.

And the inlet means forms a nozzle in the vicinity of the powder injection tube and the gas injection tube for injecting the gas from the separation means to form a low pressure region on the powder injection tube side to facilitate the powder circulating. And the separation means is preferably implemented by a cyclone.

According to the present invention, by applying atmospheric pressure plasma technology to the continuously cyclonic system can be provided a powder treatment technology to effectively cut the sulfur bonds on the surface of the rubber powder to produce a molded rubber having excellent characteristics. . In particular, when plasma treatment according to the present invention by making the molecular structure on the surface of the rubber powder to the active radicals by the plasma to form an active site that can react easily between the powder when the rubber powder is molded Enable crosslinking.

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

1 is a block diagram showing a recycling apparatus of a powder using an atmospheric pressure plasma according to the present invention, the apparatus of the present invention is a gas cylinder 102, a gas injection tube 104, a nozzle 108, the gas and powder passing through The first passage 110, the discharge tube 120, the second passage 132 through which gas and powder are discharged, the cyclone 140, the gas discharge tube 142, and the powder injection tube 112. The lower end is provided with a valve 144 for controlling the discharge of the powder, the gas injection pipe 104 is provided with a valve 104 for controlling the gas input.

Looking at the device configuration of the present invention made as described above, the gas cylinder 102 is connected to the gas injection pipe 106 via the valve 104, the gas injection pipe 106 is connected to the powder injection pipe 112 descending from the top Thus, the powder is loaded into the gas flow and input to the discharge tube 120 through the first passage 110. At this time, the portion (A) where the gas injection pipe 106 and the powder injection pipe 112 meet each other, as shown in FIG. 2, the nozzle 108 for controlling the gas flow is formed, so that the powder injection pipe 112 The low pressure region B is formed on the side of the cross section. By the low pressure region B formed as described above, the powder may be more easily loaded into the gas and injected into the discharge tube 120. That is, when the reaction gas or the carrier gas passes through the nozzle 108 and the flow velocity is relatively high, a vacuum is formed around the reaction gas. The vacuum force causes the powder to descend from the cyclone 140 to the reaction gas. As a result, the powder tends to enter the discharge tube 120 again.

Discharge tube 120 is formed in a cylindrical shape as a whole, the outermost cylindrical working electrode 122 is formed, there is a discharge tube 124 made of a dielectric inside the working electrode 122, the center of the rod-like ground The electrode 126 is formed. Although not shown in the drawing, an AC voltage having a predetermined frequency is applied between the working electrode 122 and the ground electrode 126, and when gas is injected into the injection tube 124, a discharge is generated to modify the surface of the powder. Further, the injection tube 124 is made of any one of oxides such as SiO ₂ , Al ₂ O ₃ , ZrO ₂ , TiO _2, and polymers such as Teflon and polycarbonate, and the powder is injected into the discharge tube at a predetermined angle. By flowing in this spiral shape, the flow of powder in the discharge tube can be made uniform. That is, an inlet for injecting the powder into the discharge tube is formed on the side of the discharge tube, and has an inclination at a predetermined angle, and an outlet for discharging the powder from the discharge tube is formed on the side of the discharge tube, but the powder is swirled by centrifugal force by having a predetermined slope. Swirl to smoothly flow the powder than to put in the right direction can reduce the clogging phenomenon of the powder.

In addition, the surface-modified powder in the discharge tube 120 is injected into the cyclone 140 through the second passage 132 together with the gas, and the cyclone 140 separates and reacts the light reactant gas and the relatively heavy powder. Gas is discharged to the outside through the gas discharge pipe 142, the powder is discharged to the powder injection pipe (112). As such, the powder discharged from the cyclone 140 passes through the nozzle 108 and is injected into the discharge tube 120 together with the gas.

By repeatedly performing such a series of processes for a certain time, a certain amount of powder can be plasma treated.

Next, the operation of the present invention configured as described above will be described in detail with reference to the flowchart of FIG. 3.

First, the rubber powder to be treated is put into the cyclone 140, the gas valve 104 is opened to allow gas to flow through the gas injection tube 104, and the powder valve 144 is opened to powder the powder injection tube 144. ) Through (S1 ~ S3).

As described above, the powder flowing down from above as the reaction gas flows uniformly passes through the passage 110 and into the discharge tube 120 (S4). At this time, in the discharge tube 120, the reaction gas is present in a plasma state separated by ions and electrons by a high voltage applied to the wicking electrode 122 and the ground electrode 126. Therefore, the powder uniformly passing through the discharge tube is affected by free radicals and atomic ions while passing through the plasma region (S5). Here, the effect of the plasma on the powder has different characteristics depending on the nature of the reaction gas (that is, the carrier gas). For example, helium or argon gas mainly forms stable radicals to perform surface modification, and when oxygen is added, it mainly introduces a polar group to the surface to improve hydrophilicity or improve wettability, thereby increasing adhesion. In the case of using a fluorine-based reaction gas, it is mainly used to give hydrophobicity. In the case of rubber powder, the C-S and S-S bonds crosslinked on the surface are broken or the covalently bonded C-H bonds on the surface are activated to increase the reactivity. When the powder activated by the plasma treatment is molded in this way, the bonding strength between the powders is increased to improve the tensile strength.

It is necessary to rotate the powder uniformly for a certain time in order to give the powder different surface properties depending on the reaction gas or carrier gas used as described above. This depends on how long the process powder remains in the plasma discharge tube.

Therefore, the powder having passed through the plasma region of the discharge tube enters the cyclone 140 together with the gas through the passage 132, where the gas and the powder are separated (S6 and S7). The powder settled under the cyclone 140 descends through the powder inlet tube 112 and again enters into the plasma discharge tube 120 by the reaction gas or the carrier gas. Subsequently, the powder is uniformly modified by the surface reaction by activated radicals, ions, atoms, etc. in the plasma while passing through the plasma state in the discharge tube 120. This series of processes is repeated until the appropriate number of times and discharged the treated powder when the treatment is completed (S8, S9).

Figure 4 is a graph showing the tensile strength of the rubber powder before the surface treatment according to the invention, Figure 5 is a graph showing the tensile strength of the rubber powder treated in accordance with the present invention. In the coordinates of FIGS. 4 and 5, the abscissa represents the tensile length in mm and the ordinate represents the stress in kg / cm 2.

In the graph of FIG. 4, it can be seen that the tensile length of the sample is about 22.5 mm to 25 mm, the maximum strength is about 35 kg / cm 2, and the graph of FIG. 5 shows that the tensile length is about 22.5 mm to 25 mm. It can be seen that the strength is about 60 kg / cm 2. Therefore, when comparing the graphs of FIGS. 4 and 5, it can be seen that the tensile strength of the plasma treated specimen is increased by about 40% to 60% compared to the untreated specimen. This may be stronger depending on the processing conditions.

In the above embodiment, the rubber powder has been described, but the technical idea of the present invention is not limited to the rubber powder, and any powder may be used. That is, the present invention can be applied to various fields that can uniformly treat the surface modification of the powder by varying the reaction gas by using a low-temperature atmospheric pressure plasma, and in particular, the specific surface area in the bulk state is limited to only modify the surface. However, it can be processed into a powder and continuous treatment to modify the properties of the whole. For example, when the present invention is applied to a metal powder, the surface of the metal powder is activated to allow sintering to occur at a low temperature.

As described above, according to the present invention, by applying atmospheric pressure plasma technology to a continuously circulating cyclone system, a powder processing technique for effectively cutting sulfur bonds on the surface of a rubber powder to produce molded rubber having excellent characteristics is provided. Can provide. In particular, when plasma treatment according to the present invention by making the molecular structure on the surface of the rubber powder to the active radicals by the plasma to form an active site that can react easily between the powder when the rubber powder is molded Make cross linking possible. Moreover, according to the present invention, it is possible to effectively surface the various powders in addition to the rubber powder.

Claims (7)

Drawing means for drawing the powder into the discharge tube by gas; A discharge tube for generating a plasma by performing atmospheric pressure dielectric discharge of the gas with a power applied to an electrode, and modifying the surface of the powder by the plasma; And Recycling the powder using atmospheric pressure plasma, characterized in that consisting of the separation means for receiving the primary reformed powder and gas from the discharge tube to separate the gas and powder, the gas is discharged to the outside, the powder is provided to the inlet means again Device. The powder recycling apparatus of claim 1, wherein the inlet means comprises a powder inlet tube through which powder is input from the separating means, and a gas inlet tube through which gas is injected. The powder recycling apparatus of claim 2, wherein a nozzle is installed near the powder injection pipe and the gas injection pipe so as to form a low pressure region on the powder injection pipe side. The powder recycling apparatus using atmospheric pressure plasma according to claim 1, wherein the separation means is a cyclone. The method of claim 1, wherein the discharge tube comprises a working electrode made of a tubular conductor, an injection tube made of a tubular dielectric inside the working electrode, and a ground electrode formed in the injection tube. Recycling device. The method of claim 5, wherein the injection tube is made of any one of an oxide such as SiO ₂ , Al ₂ O ₃ , ZrO ₂ , TiO ₂ , or a polymer such as Teflon or polycarbonate. Recycling device of powder. The method of claim 5, wherein the injection tube is formed such that the inlet and outlet of the powder is inclined at a predetermined angle so that the powder is introduced into the discharge tube at a predetermined angle so that the powder flows in a spiral shape in the discharge tube to make the powder flow uniform. A powder recycling apparatus using atmospheric pressure plasma, characterized in that.