KR102219321B1 - method for producing hydrogen and nano carbon from hydrocarbon using liquid phase plasma reaction - Google Patents

Abstract

The present invention relates to a method for simultaneously generating hydrogen and nanocarbons from hydrocarbons using a liquid phase plasma reaction. More particularly, the present invention relates to a method capable of simultaneously generating a large amount of hydrogen gas and nanocarbon particles without emission of environmental pollutants such as greenhouse gases by only a single process of generating plasma in liquid hydrocarbons. The present invention includes a first step of introducing liquid hydrocarbons into a reactor, and a second step of generating hydrogen gas and nanocarbon particles at the same time by producing plasma in the hydrocarbons.

Description

Method for producing hydrogen and nano carbon from hydrocarbon using liquid phase plasma reaction

The present invention relates to a method of simultaneously generating hydrogen and nanocarbon from hydrocarbons using a liquid plasma reaction, and more particularly, hydrogen without emission of environmental pollutants such as greenhouse gases by only a single process of generating plasma from liquid hydrocarbons. It relates to a method capable of generating gas and nanocarbon particles in large quantities at the same time.

Petroleum energy has been a driving force for industrial development and has given humanity abundance by inducing the development of various technologies. However, as it is known as a material that is the main cause of environmental pollution such as global warming, interest in the development of clean energy that can replace it is attracting attention.

Since hydrogen is converted into water after combustion, it does not emit environmental pollutants. Since it can be obtained by decomposing water, raw materials are also endless. Hydrogen is one of the clean energy sources and is regarded as the ultimate alternative energy source or energy medium in the future. This is because hydrogen can be made from water that exists infinitely on the earth as a raw material, can be easily stored as gas or liquid, and has the advantage of being a non-polluting energy source that discharges only water except for the generation of very small amounts of nitrogen during combustion. .

As a method of producing hydrogen, a steam reforming method, an electrolysis method, and a photochemical decomposition method of water are known.

Most of the hydrogen industrially required is produced by steam reforming. The steam reforming method is a method obtained by separating hydrogen from carbon atoms in methane, methanol and natural gas using high-temperature steam. Hydrogen produced by this method is used as a major raw material in the manufacture of fertilizers and chemical products rather than as a fuel, and is also used to improve the quality of petrochemical products. Although this manufacturing method is the most efficient hydrogen manufacturing method in terms of price competition, it has a disadvantage in that the total energy efficiency is lowered because fossil fuel is used as a heat source in the manufacturing process, and there is a problem in that carbon dioxide, a greenhouse gas, is emitted in the production process.

Another method of producing hydrogen is an electrolysis method in which water is separated into its constituent elements, hydrogen and oxygen. The electrolysis process is a method of decomposing water molecules into hydrogen and oxygen by passing an electric current through water. At this time, hydrogen is obtained from the cathode and oxygen is obtained from the anode. Although hydrogen produced by electrolysis is of high purity, it has a disadvantage in that it is very expensive to manufacture because it uses electricity obtained from renewable energy as an energy source.

Meanwhile, a method for producing hydrogen by photolysis reaction in which UV or visible light is used as an energy source and a photocatalyst responsive thereto is applied together is drawing attention.

Korean Patent Registration No. 10-1814128 discloses a method for producing hydrogen using a liquid plasma and a photocatalyst.

The hydrogen production method generates hydrogen by adding a photocatalyst to water to generate plasma. This method of producing hydrogen requires a photocatalyst, and accordingly, there is a problem in that the process is increased, and the photolysis reaction efficiency by the photocatalyst is low and the hydrogen generation rate is low.

Korean Patent Registration No. 10-1814128: Hydrogen production method using liquid plasma and photocatalyst

The present invention was created to improve the above problems, and it is possible to generate a large amount of hydrogen gas without the emission of environmental pollutants such as greenhouse gases with only a single process of generating plasma from liquid hydrocarbons, thereby providing economical and eco-friendly production technology. It has its purpose to provide.

In addition, an object of the present invention is to provide a production technology capable of simultaneously generating hydrogen gas and nano-carbon particles by simultaneously generating nano-carbon particles together with hydrogen gas in one process.

The present invention for achieving the above object comprises a first step of introducing a liquid hydrocarbon into a reactor; And a second step of simultaneously generating hydrogen gas and nanocarbon particles by generating plasma from the hydrocarbon.

The hydrocarbon is a compound consisting of only hydrogen atoms and carbon atoms.

The hydrocarbon is an aliphatic or aromatic hydrocarbon.

A pair of electrodes in contact with the hydrocarbon are installed in the reactor, and in the second step, a plasma is generated by supplying a power of 200 to 300 V to the electrode and discharging it with a pulse width of 1 to 10 µs.

As described above, the present invention can provide an economical and eco-friendly production technology since it is possible to generate a large amount of hydrogen gas without emission of environmental pollutants such as greenhouse gases with only a single process of generating plasma from liquid hydrocarbons.

In addition, the present invention has the advantage of being able to simultaneously generate nanocarbon particles together with hydrogen gas in one process.

As described above, the present invention is a novel technology, which has a higher hydrogen production rate than that of a conventional method for producing hydrogen by water decomposition reaction, and does not generate greenhouse gases as in the steam reforming method. Therefore, it is possible to overcome the low hydrogen production rate, which is a disadvantage of the hydrogen production method, from the decomposition of water, thereby obtaining an effect of increasing the hydrogen production rate. In addition, the nano-carbon material produced at the same time can be used as a high-tech material that can be applied to various fields, so it has the effect of ultimately lowering the hydrogen production cost.

The hydrogen and nanocarbon production method of the present invention can be directly applied to the actual industry. The product consists entirely of hydrogen and nanocarbon, and therefore, it can be conveniently applied in the field of hydrogen energy industry, which is used as a fuel, since it does not have to go through the separation process of the product. In addition, nano-carbon particles can be separated and recovered and used immediately in various industrial fields.

1 is a schematic configuration diagram showing a liquid plasma reaction apparatus applied to an example of the present invention,
2 is a photograph showing a state in which a plasma is generated in benzene to generate nanocarbons over time,
3 is a graph showing the emission spectrum of plasma measured by generating plasma in benzene,
4 is a graph showing the measurement of the rate of hydrogen generated when plasma is generated in benzene, toluene, and xylene,
5 is an electron micrograph of nanocarbon particles generated when plasma is generated from benzene, toluene, and xylene.

Hereinafter, a method of simultaneously generating hydrogen and nanocarbon from hydrocarbons using a liquid plasma reaction according to a preferred embodiment of the present invention will be described in detail.

An example of a liquid plasma reaction device for generating plasma in a liquid phase will be described first.

Referring to FIG. 1, the liquid plasma reaction apparatus includes a cylindrical reactor 10, a pair of electrodes 20 installed in the reactor 10, and a bipolar pulse power supply for supplying power to the electrodes 20. ) 30, and a thermostatic cooler 40 for circulating cooling water outside the reactor 10 to maintain the contents of the reactor at a constant temperature.

The reactor 10 has a double cylindrical structure. Hydrocarbons are introduced into the reactor 10, and cooling water supplied from the thermo-cooler 40 circulates outside the reactor 10 to prevent the contents of the reactor 10 from increasing in temperature due to plasma. A magnetic stirrer for stirring the contents may be installed at the lower inner side of the reactor 10.

A pair of electrodes 20 is installed in the reactor 10. The electrode 20 protrudes into the reactor 10 and comes into contact with the liquid content introduced into the reactor 10. The electrode 20 is made of a tungsten material, and the outside of the electrode 20 is covered with an insulator made of a ceramic material. The distance between the two electrodes 20 may be maintained at about 0.2 to 0.5 mm.

When power is supplied to the electrode 20 through the power supply 30, plasma is generated in the liquid by electric discharge. In order to prevent an increase in temperature of the contents when plasma is generated by electric discharge, a thermostat 40 is installed. The constant temperature cooler 40 serves to maintain the contents of the reactor 10 at a constant temperature, such as 18 to 25°C, with cooling water outside the reactor 10 using a circulation pump. The reactor 10 and the thermostat 40 are connected by a circulation line.

A method of simultaneously generating hydrogen and nanocarbon from hydrocarbons using the liquid plasma reaction apparatus described above will be described step by step.

1. Step 1

First, prepare a hydrocarbon.

Hydrocarbon is a compound consisting of a hydrogen atom and a carbon atom, and in the present invention, a liquid hydrocarbon is used. Since the present invention is a technology for generating plasma in a liquid phase, only liquid hydrocarbons can be used.

Since hydrocarbons containing atoms other than hydrogen and carbon generate by-products, a hydrocarbon consisting of only hydrogen atoms and carbon atoms is used in the present invention. When a hydrocarbon with an oxygen atom is used, by-products such as carbon dioxide are generated.

The hydrocarbon used in the present invention may be an aliphatic hydrocarbon or an aromatic hydrocarbon. Any of the aliphatic hydrocarbons or aromatic hydrocarbons in the liquid phase and consisting of only hydrogen and carbon can be used in the present invention. The hydrocarbon used in the present invention includes even derivatives.

Alkane having 5 to 17 carbon atoms may be used as the aliphatic hydrocarbon, or benzene, toluene, xylene, and the like may be used as the aromatic hydrocarbon.

When hydrocarbons are prepared, they are introduced into the reactor for liquid plasma reaction.

2. Step 2

Next, a second step of generating hydrogen gas and nanocarbon particles by generating plasma in the hydrocarbon in the reactor is performed.

When power is supplied to the electrode 20 through the power supply 30, plasma is generated in the liquid by electric discharge. The flow of ions and electrons according to the application of electric energy in the liquid generates plasma in the liquid. A liquid phase plasma (LPP) reaction that generates a high energy plasma in a liquid can generate light energy in a liquid with various active species. Liquid plasma generates plasma in a solution. Not only does it generate very strong and various reactive active species and electrons, but also generates energy such as high temperature and shock waves that can decompose hydrocarbons in the solution, effectively decomposing hydrocarbons to decompose hydrogen and carbon. Can produce.

When power is supplied, it is preferable to supply power in pulses (Pulse width 1 to 10 µs) rather than continuously supplying power to the electrodes. If the power is supplied in pulses, the melting of the electrode in contact with the hydrocarbon can be suppressed, and thus the elution of the electrode component into the hydrocarbon can be greatly suppressed.

Power conditions supplied to the electrode to generate plasma may be a voltage of 200 to 300V, a pulse width of 1 to 10 μs, and a frequency of 20 to 30 KHz.

When plasma is generated among liquid hydrocarbons, the high energy of the plasma decomposes the hydrocarbon into hydrogen and carbon. Hydrogen gas and nanocarbon particles are simultaneously generated by plasma.

As described above, the present invention is an economical and eco-friendly production technology since it is possible to generate hydrogen gas without emitting environmental pollutants such as greenhouse gases with only a single process of generating plasma. In addition, the present invention has the advantage of being able to simultaneously generate nanocarbon particles together with hydrogen gas in one process.

Carbon materials are high-tech materials that support modern society, and are used as lightweight materials in various fields. Carbon materials used as electrodes such as lithium secondary batteries and supercapacitors are being applied as key source materials in the energy field. In addition, carbon materials have long been used as filters in various separation processes and environmental fields. In the present invention, the nanocarbon particles generated together with hydrogen gas can be usefully utilized in various industrial fields as described above.

Hereinafter, the present invention will be described through experimental examples. However, the following experimental examples are intended to specifically illustrate the present invention, and are not intended to limit the scope of the present invention to the following experimental examples.

(Example)

Benzene, toluene, and xylene were used as hydrocarbons, respectively.

Hydrocarbon decomposition experiments were performed using the liquid plasma reactor as shown in FIG. 1.

200 ml of hydrocarbons are added to a reactor equipped with a pair of electrodes spaced at 0.3 mm intervals, and then the hydrocarbons are vigorously stirred with a magnetic stirrer and discharged for 60 minutes under conditions of voltage of 240 V, frequency of 25 kHz, and pulse width of 5 µs to generate plasma in the hydrocarbons. To decompose hydrocarbons.

In order to prevent the hydrocarbon temperature inside the reactor from rising due to plasma generation, the temperature inside the reactor was kept constant at 20°C using a thermostat. The gaseous products generated inside the reactor were transferred to a gas chromatograph (GC).

<Plasma reaction observation and product analysis>

Figure 2 shows a photograph of an experiment in which plasma is generated in benzene to generate hydrogen gas and nanocarbon particles over time.

Referring to FIG. 2, it can be seen that black nano-carbon particles start to be generated among hydrocarbons as soon as plasma is generated. In addition, as time passed, the amount of nanocarbon particles produced significantly increased, and after 60 seconds, the entire contents of the reactor turned black.

Through this, it could be confirmed visually that nanocarbon particles were generated in a very short time.

In order to analyze the type and intensity of the material generated through the plasma reaction, the emission spectrum of the light source generated from the plasma was measured in the range of 300 nm to 1100 nm using Optical Emission Spectroscopy (OES), and is shown in FIG. 3.

Referring to FIG. 3, as a result of measuring the emission spectrum, a hydrogen peak (H ₂ , H _α ) and a carbon peak (C ₂ ) were observed. Therefore, it was confirmed that hydrogen and carbon were simultaneously generated in the reactor when plasma was generated. In addition, it can be seen that the black particles shown in FIG. 2 are carbon particles.

<Measurement of hydrogen generation rate>

When plasma was generated in benzene, toluene, and xylene, the speeds of hydrogen gas generated respectively were measured and shown in FIG. 4.

Referring to FIG. 4, it was found that the hydrogen gas started to be generated immediately after the reaction and continued to increase, and the increase in the generation rate decreased after about 50 minutes. And it was found that the rate of generation of hydrogen in the order of benzene, toluene and xylene was high.

<Nanocarbon particle image>

FIG. 5 shows a transmission electron microscope (TEM) image of nanocarbon particles generated when plasma is generated in benzene, toluene, and xylene, respectively.

Referring to FIG. 5, it was confirmed that carbon produced from benzene, toluene, and xylene were all composed of nanometer-sized fine particles.

In the above, the present invention has been described with reference to the embodiments, but these are merely exemplary, and those of ordinary skill in the art will understand that various modifications and equivalent embodiments are possible therefrom. Therefore, the true scope of protection of the present invention should be determined only by the appended claims.

10: reactor 20: electrode
30: power supply 40: thermostat

Claims (4)

delete A first step of injecting a liquid hydrocarbon into a reactor equipped with a pair of electrodes spaced at intervals of 0.2 to 0.5 mm;
A second step of simultaneously generating hydrogen gas and nanocarbon particles by supplying power to the electrode in contact with the hydrocarbon while maintaining the hydrocarbon at a constant temperature of 18 to 25°C to generate plasma in the liquid; Including,
The hydrocarbon is a compound consisting of only hydrogen atoms and carbon atoms,
In the second step, hydrogen and nanocarbon from hydrocarbons using a liquid plasma reaction characterized in that plasma is generated by supplying power of 200 to 300 V to the electrode and discharging for 1 to 60 minutes with a pulse width of 1 to 10 µs. How to generate simultaneously. The method of claim 2, wherein the hydrocarbon is an aliphatic or aromatic hydrocarbon, and hydrogen and nanocarbon are simultaneously produced from a hydrocarbon using a liquid plasma reaction. delete

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