JP2013147411A - Method of manufacturing carbon monoxide from carbon dioxide by dielectric barrier discharge - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a method and a device of manufacturing carbon monoxide from carbon dioxide without using an expensive catalyst with high energy efficiency.SOLUTION: A method of manufacturing carbon monoxide includes process 1 in which electrons are generated by dielectric barrier discharge and process 2 in which a generation gas containing carbon monoxide is obtained by making electrons generated in process 1 come in contact with a material gas containing carbon dioxide. A manufacturing apparatus for carbon monoxide includes a reactor, a pair of electrodes, a dielectric, a high frequency power source, and a material gas supply device. The apparatus generates carbon monoxide by making electrons generated by applying a voltage between electrodes to perform dielectric barrier discharge in the reactor come in contact with the material gas containing carbon dioxide.

Description

  The present invention relates to a method and apparatus for producing carbon monoxide from carbon dioxide.

  The consumption of petrochemical fuel is expanding worldwide, and carbon dioxide emissions are increasing rapidly. In developed countries in particular, there is an urgent need to reduce carbon dioxide emissions, and methods such as converting carbon dioxide into flammable gases, fixing it in polymers, and embedding it underground are being investigated. .

  Carbon monoxide can be mixed with hydrogen to form a synthesis gas, and a hydrocarbon can be produced from the synthesis gas by a Fischer-Tropsch reaction. Carbon monoxide can also be used as a fuel. Therefore, a method for producing carbon monoxide from carbon dioxide has been studied in order to suppress carbon dioxide emission.

  Examples of the method for producing carbon monoxide from carbon dioxide include a method by a reverse shift reaction represented by the following reaction formula (1).

CO ₂ + H ₂ + 40.9kJ / mol → CO + H ₂ O (1)
However, the method based on this reaction requires a large amount of hydrogen and also requires a large amount of heat because of the endothermic reaction. In addition, expensive catalyst and raw material purification and composition adjustment are necessary, and the production cost is high.

  As another method for producing carbon monoxide from carbon dioxide, a method using microwave plasma (see, for example, Patent Document 1) has been proposed.

JP 2003-27241 A

  In the case of the method described in Patent Document 1, carbon dioxide is consumed, but hydrogen or water is necessary as a raw material. Moreover, since the method described in Patent Document 1 requires a catalyst, it is necessary to remove trace components such as sulfur that cause deterioration of the catalyst from the raw material. In particular, a separation and purification process is required when exhaust gas from a power plant, steel plant, factory, etc. is used as a carbon dioxide source.

  Therefore, an object of the present invention is to provide a method and an apparatus for producing carbon monoxide from carbon dioxide that does not require the use of an expensive catalyst and that has few limitations on the composition and impurities of the raw material gas.

  As a result of diligent investigation, the present inventor has found that by using dielectric barrier discharge, it is not necessary to use an expensive catalyst, and there is almost no influence of the composition of the source gas and impurities, and carbon monoxide can be produced from carbon dioxide. The present invention has been completed.

  That is, the present invention is as follows.

[1]
Step 1 for generating electrons by performing dielectric barrier discharge;
Step 2 of obtaining a product gas containing carbon monoxide by contacting the electrons generated in Step 1 with a raw material gas containing carbon dioxide;
A method for producing carbon monoxide comprising:

[2]
A source gas containing carbon dioxide is present between the electrodes with at least one of the opposing surfaces of the pair of electrodes covered with a dielectric, and a voltage is applied to the electrodes to discharge the carbon monoxide. The manufacturing method of carbon monoxide including the process of obtaining the product gas to contain.

[3]
The method for producing carbon monoxide according to [1] or [2], wherein the source gas further contains a rare gas.

[4]
The method for producing carbon monoxide according to any one of [1] to [3], wherein the dielectric contains an alkali metal or an alkaline earth metal.

[5]
The method for producing carbon monoxide according to any one of [1] to [4], wherein the dielectric is a ferroelectric.

[6]
A reactor,
A pair of electrodes disposed in the reactor;
A dielectric provided on at least one of the opposing surfaces of the pair of electrodes;
A high-frequency power source connected to the pair of electrodes and applying a voltage between the electrodes;
A raw material gas supply device for supplying a raw material gas containing carbon dioxide to the reactor;
With
In the reactor, carbon monoxide is produced by causing electrons generated by applying a dielectric barrier discharge by applying a voltage between the electrodes to contact a source gas containing carbon dioxide, thereby generating carbon monoxide. apparatus.

[7]
The manufacturing apparatus according to [6], wherein the dielectric contains an alkali metal or an alkaline earth metal.

[8]
The manufacturing apparatus according to [6] or [7], wherein the dielectric is a ferroelectric.

  According to the present invention, it is not necessary to use an expensive catalyst, and carbon monoxide can be produced from carbon dioxide without being trapped by the raw material gas composition.

1 is a schematic diagram of an example of a carbon monoxide production apparatus including a coaxial electrode reactor 3. FIG. It is sectional drawing of the reactor 3 of the carbon monoxide manufacturing apparatus in FIG. 1 is a schematic view of an example of a carbon monoxide production apparatus including a parallel plate electrode reactor 20. FIG. It is a graph which shows an example of a plasma emission spectrum.

  Hereinafter, a mode for carrying out the present invention (hereinafter referred to as “the present embodiment”) will be described in detail. In addition, this invention is not restrict | limited to the following embodiment, A various deformation | transformation can be implemented within the range of the summary.

≪Method for producing carbon monoxide≫
In the carbon monoxide production method of the present embodiment, Step 1 for generating electrons by performing dielectric barrier discharge, and contacting the electrons generated in Step 1 with a source gas containing carbon dioxide, And obtaining a product gas containing carbon monoxide.

[Step 1]
The method for producing carbon monoxide according to the present embodiment includes step 1 of generating electrons by performing dielectric barrier discharge.

  In the present embodiment, dielectric barrier discharge refers to discharge that occurs when an AC voltage is applied between electrodes in a state where at least one of the opposing surfaces of a pair of electrodes is shielded by a dielectric.

  In the present embodiment, the interelectrode distance is a distance between two dielectrics (see, for example, FIG. 2) when dielectrics are provided on both opposing surfaces of a pair of electrodes. When the dielectric is provided only on one of the opposing surfaces of the pair of electrodes, the distance from the electrode not provided with the dielectric to the dielectric is used.

  In the dielectric barrier discharge in step 1, the interelectrode distance d preferably satisfies d ≦ 5 mm, and more preferably satisfies 0 mm <d ≦ 5 mm. In order to prevent a short circuit between the electrodes while maintaining a stable discharge, it is more preferable to satisfy 0.5 mm ≦ d ≦ 5 mm, and it is particularly preferable to satisfy 0.5 mm ≦ d ≦ 2 mm.

Examples of the dielectric include glass, quartz, soda glass, quartz glass, alumina, and barium titanate, and there is no particular limitation as long as it is an insulator or a material with low conductivity. The dielectric preferably contains an alkali metal or alkaline earth metal, and is preferably a ferroelectric. When an alkali metal or an alkaline earth metal is present on the dielectric surface, the raw material CO ₂ is easily adsorbed on the dielectric surface in the carbon monoxide generation step described later, and the probability that electrons are irradiated to the CO ₂ increases. _It is considered that the conversion ratio of ₂ is improved. Therefore, it is preferable that an alkali metal or an alkaline earth metal is present on the dielectric surface from the viewpoint of the efficiency of electron irradiation to CO ₂ . The alkali metal or alkaline earth metal may be present not only on the dielectric surface but also inside the dielectric. As the dielectric, any material containing alkali metal or alkaline earth metal at least on the surface satisfies the requirements from the viewpoint of electron irradiation efficiency to CO ₂ . Preferred dielectrics are soda glass, soda lime glass, barium titanate, SrBi ₂ Ta ₂ O ₉ , K ₄ Fe (CN) ₆ 3H ₂ O.

If the dielectric constant of the dielectric is high, the amount of charge accumulated on the surface of the dielectric when a certain voltage is applied between the electrodes is high, and the amount of electrons emitted is large. When the amount of discharged electrons is large, (1) there are many electrons that irradiate CO ₂ present in the discharge field, CO ₂ conversion is high even in the same discharge field volume, and (2) gas with high dielectric breakdown voltage. Even so, it is easy to generate plasma, and it is easy to obtain stable plasma. Therefore, from the viewpoints of plasma generation stability and CO ₂ conversion, it is preferable that the derivative has a high dielectric constant. As the dielectric having a high dielectric constant, barium titanate, Pb (Zr, Ti) O ₃ , RbHSO ₄ , Sr ₂ CeS ₄ , and K ₂ SeO ₄ are preferable, and barium titanate is particularly preferable.

  In order to cause dielectric barrier discharge, at least one of the electrodes needs to be covered with a dielectric, but the number of dielectrics existing between the electrodes is not particularly limited. An integral dielectric may be sandwiched between both electrodes, a dielectric may be laminated on the opposing surface of one or both electrodes, or a plurality of electrodes may be laminated between both electrodes Good. Note that “covering” the electrode with the dielectric means that the dielectric exists so as to inhibit the passage of electrons, and it is not necessary that the dielectric of the integral object physically covers the electrode. As long as the structure does not discharge only at a specific location due to short-circuiting of electrons, there may be dielectric breaks or gaps in both the surface direction and the vertical direction.

  In the dielectric barrier discharge in step 1, the AC voltage applied between the electrodes is preferably a sine wave, rectangular wave or sawtooth AC voltage.

In the dielectric barrier discharge in step 1, the frequency at which a voltage is applied between the electrodes is preferably 1 kHz or more and 1 MHz or less, more preferably 3 kHz or more and 100 kHz or less.
It is preferable that the frequency be within the above range because energy efficiency is high and stable discharge can be performed.

  In the dielectric barrier discharge in step 1, the voltage applied between the electrodes is preferably 2 kV or more and 20 kV or less. A more preferable applied voltage varies depending on the raw material, the distance between the electrodes, and the frequency, but may be any voltage that generates plasma. For example, when the distance between the electrodes is 2 mm and the frequency is 40 kHz, it is preferable to apply a voltage of 3 kV to 7 kV to generate plasma.

[Step 2]
The method for producing carbon monoxide of the present embodiment includes step 2 of obtaining a product gas containing carbon monoxide by bringing the electrons generated in step 1 into contact with a raw material gas containing carbon dioxide.

(Mechanism of carbon monoxide production)
The dielectric barrier discharge method is a method of generating plasma by intermittently irradiating electrons, and is a non-equilibrium plasma generation method in which only the electron temperature rises and atoms or molecules exist at a temperature close to room temperature. . Molecules irradiated with electrons by dielectric barrier discharge are selectively cut sequentially from bonds with low dissociation energy. Therefore, carbon monoxide can be generated from carbon dioxide if the carbon dioxide is appropriately irradiated by dielectric barrier discharge and reacts under the condition that the electron irradiation is terminated when it is decomposed to carbon monoxide. On the other hand, since equilibrium plasma such as arc discharge is instantly dissociated to monoatomic radicals, it is extremely difficult to stop the reaction when carbon dioxide is decomposed to carbon monoxide.

(Raw material gas)
The source gas used in the present embodiment is not particularly limited as long as it is a gas containing carbon dioxide. However, if the content of a gas other than carbon dioxide is large in the source gas, the electrons irradiated for the excitation of the gas are consumed, and the carbon dioxide conversion efficiency for the input energy is reduced. Therefore, in order to make it react with high energy efficiency, the one where the carbon dioxide content in source gas is high is preferable. A preferable carbon dioxide content in the raw material gas is 0.1% by volume or more, more preferably 1% by volume or more and 80% by volume or less.

  Carbon monoxide can be generated even if oxygen or oxygen-containing compounds are mixed in the source gas. However, when the conversion rate of carbon monoxide is high, the explosion limit of carbon monoxide may be exceeded. From the viewpoint of safety, it is preferable that the oxygen content in the raw material gas is low. Specifically, the oxygen content in the raw material gas is preferably 10% by volume or less, more preferably 1% by volume or less. In addition, since oxygen and ozone generated when oxygen is irradiated with electrons by dielectric barrier discharge may oxidize carbon monoxide, if oxygen or ozone is present in step 2, the oxygen from ozone is one. Carbon oxide conversion may be reduced. In order to increase the carbon monoxide conversion rate, it is preferable that the content of oxygen and oxygen-containing compounds in the raw material gas is small.

  It is also possible to mix the exhaust gas as it is and use it as a raw material gas without purifying the exhaust gas, such as a thermal power generation, a steel mill, and a factory using a petrochemical raw material. Further, exhaust gases from a plurality of different factories can be mixed and used as a raw material gas. These exhaust gases contain impurities such as sulfur and often reduce catalytic activity in the case of catalytic reactions. However, in the case of a reaction using dielectric barrier discharge as in the manufacturing method of the present embodiment, there is no particular influence even if impurities such as sulfur are contained in the source gas. Therefore, in the present embodiment, for example, 3% by volume or less of a sulfur compound may be included in the raw material gas. However, when the generated carbon monoxide-containing gas is converted into another substance by a catalytic reaction, the production cost may be reduced by removing impurities in advance.

  When a rare gas is contained in the source gas, the discharge voltage can be reduced. Therefore, a rare gas may be included in the source gas in order to increase energy efficiency. From the viewpoint of energy efficiency, the rare gas content in the raw material gas is preferably 80% by volume or less, and more preferably 40% by volume or less.

The flow rate of the source gas is not particularly limited, and can be arbitrarily determined by the distance between the electrodes, the cross-sectional area and length of the gas flow surface in the discharge field, and the frequency of the applied high frequency. For example, when the distance between the electrodes is 2 mm, the sectional area of the gas flow surface in the discharge field is 0.5 cm ² , the length is 2 cm, and the frequency is 40 kHz, the flow rate of the source gas preferable from the viewpoint of analysis of the reaction gas is 25 cc / min or more It is below min.

  In the present embodiment, the discharge field refers to a space that is disposed inside the reactor and formed between a pair of electrodes.

[Other processes]
The method for producing carbon monoxide according to the present embodiment may further include steps such as a raw material purification step for desulfurization and deoxygenation, and a product purification step such as carbon dioxide separation.

  Note that when attention is paid to one electron, the above-described steps 1 and 2 occur continuously. However, when viewed as a set, it is needless to say that each step need not be sequentially performed. That is, in one reactor, the generation of plasma by discharge and the reduction of carbon dioxide by the generated electrons may of course proceed simultaneously. For example, when carbon dioxide is present between the electrodes in a state in which a dielectric is in contact with at least one of the opposing surfaces of the pair of electrodes, and voltage is applied to the electrodes, the electrons generated by the discharge are carbon dioxide present between the electrodes. To produce carbon monoxide.

  From this point of view, the method for producing carbon monoxide according to the present embodiment allows a source gas containing carbon dioxide to exist between the electrodes in a state where at least one of the opposed surfaces of the pair of electrodes is covered with a dielectric. The manufacturing method may include a step of obtaining a product gas containing carbon monoxide by applying a voltage to the electrode and discharging it.

≪Carbon monoxide production equipment≫
The carbon monoxide production apparatus of this embodiment is
A reactor,
A pair of electrodes disposed in the reactor;
A dielectric provided on at least one of the opposing surfaces of the pair of electrodes;
A high-frequency power source connected to the pair of electrodes and applying a voltage between the electrodes;
A raw material gas supply device for supplying a raw material gas containing carbon dioxide to the reactor;
With
In the reactor, carbon monoxide is generated by bringing electrons generated by performing dielectric barrier discharge by applying a voltage between electrodes into contact with a source gas containing carbon dioxide.

  The dielectric preferably contains an alkali metal or an alkaline earth metal, and is preferably a ferroelectric.

  The carbon monoxide production apparatus of the present embodiment can be suitably used in the above-described carbon monoxide production method.

  Hereinafter, the carbon monoxide production apparatus of the present embodiment will be described in detail with reference to FIGS.

  FIG. 1 is a diagram illustrating an example of a carbon monoxide production apparatus according to the present embodiment. The manufacturing apparatus is provided with a cylindrical coaxial electrode reactor 3 and a pair of electrodes 4 and 5 connected to a high-frequency power source 6. The electrode 4 is disposed so as to cover the outer surface of the reactor 3, and the electrode 5 is disposed in the center inside the reactor 3.

  In the carbon monoxide production apparatus of this embodiment, at least one of the pair of electrodes is disposed inside the reactor.

  A raw material tank 1 is connected to one end of the reactor 3 via a mass flow 2. In the example shown in FIG. 1, two raw material tanks 1 are connected to the reactor 3, but the number of raw material tanks 1 can be changed according to the number of constituent components of the raw material gas. The flow rate of the raw material gas supplied from the raw material tank 1 is controlled using the mass flow 2. The other end of the reactor 3 is connected to a product tank 7. If it is not necessary to temporarily store the product, the product tank 7 is not always necessary, and the reactor 3 may be connected to another reactor so that the generated carbon monoxide can be supplied as a raw material.

  FIG. 2 shows a cross section of the reactor 3. A cylindrical dielectric 10 is surrounded by a cylindrical electrode 4, and a rod-shaped electrode 5 is surrounded by a dielectric 11. In the example shown in FIG. 2, both electrodes 4 and 5 are covered with dielectrics 10 and 11, but only one electrode 4 or 5 may be covered with a dielectric. That is, one electrode 4 or 5 may be exposed. When the dielectrics 10 and 11 are provided on both the electrodes 4 and 5, the inter-electrode distance d is the gap between the dielectric 10 and the dielectric 11. When a dielectric is provided only on one of the electrodes 4 and 5, the distance from the electrode surface on the opposite side of the electrode provided with the dielectric to the surface of the dielectric is defined as an interelectrode distance d.

  In the carbon monoxide production apparatus of this embodiment, the inter-electrode distance d is preferably set to 5 mm or less. The lower limit of the interelectrode distance d is preferably 0.5 mm or more from the viewpoint of ease of observation of the plasma state. By setting the inter-electrode distance d within the above range, a short circuit between the electrodes can be prevented while maintaining a stable discharge. Although the diameter of the electrode 5 is arbitrarily determined, it is preferably 1 mm or more and 100 mm or less from the viewpoint of ease of handling. The thicknesses of the dielectric 10 and the dielectric 11 are arbitrarily determined, but are preferably 0.1 mm or more and 2 mm or less from the viewpoint of ease of handling. The dielectric 10 and the dielectric 11 need only be in contact with the electrode 4 and the electrode 5, respectively, without gaps, and need not be fixed to the electrodes 4 and 5 as long as they can be stably installed.

  The material for the electrodes 4 and 5 is not particularly limited as long as it has sufficient electrical conductivity. For example, metals such as Cu, Al, Fe, W, Ag, Au, and Pt, and stainless steel (SUS304, SUS316, etc.) are used. be able to.

As a material of the dielectrics 10 and 11, for example, an insulator or a material having a low conductivity such as soda glass, quartz glass, or alumina may be used. The upper limit of the conductivity in the dielectrics 10 and 11 is preferably 6 × 10 ⁻⁴ S / m or less from the viewpoint of preventing leakage during application of a high voltage. When an alkali metal or alkaline earth metal is present on the surfaces of the dielectrics 10 and 11, the efficiency of electron irradiation to CO ₂ is high. Soda glass, soda lime glass, barium titanate, SrBi ₂ Ta ₂ O ₉ and K ₄ Fe (CN) ₆ 3H ₂ O are preferable. When a dielectric such as barium titanate, Pb (Zr, Ti) O ₃ , RbHSO ₄ , Sr ₂ CeS ₄ , K ₂ SeO ₄ is used as the dielectrics 10 and 11, the discharge efficiency is increased. It is preferable in terms of efficiency.

  Note that the plasma emission intensity calculated based on the spectral spectrum measured during dielectric barrier discharge is an indicator of discharge efficiency. In this specification, the sum of the peak areas of spectral spectra from wavelengths 305 nm to 385 nm is defined as plasma emission intensity.

  FIG. 3 is a diagram showing another example of the carbon monoxide production apparatus of the present embodiment. In the manufacturing apparatus, a pair of electrodes 14 and 17 connected to a high-frequency power source 18 are placed in a parallel plate electrode reactor 20. There is a gap between electrodes 14 and 17 in which dielectrics 15 and 16 are placed. Only one of the dielectrics may be used. When the gap between the dielectric 15 and the dielectric 16 is the interelectrode distance d, in the carbon monoxide manufacturing apparatus of this embodiment, the interelectrode distance d is preferably set to 5 mm or less. The lower limit of the interelectrode distance d is preferably 0.5 mm or more from the viewpoint of ease of observation of the plasma state. By setting the inter-electrode distance d within the above range, a short circuit between the electrodes can be prevented while maintaining a stable discharge.

  The thicknesses of the dielectrics 15 and 16 are arbitrarily determined, but are preferably 0.1 mm or more and 2 mm or less in view of ease of handling. The dielectrics 15 and 16 need only be in contact with the electrodes 14 and 17 without any gap, and need not be fixed if they can be stably installed.

  The material for the electrodes 14 and 17 is not particularly limited as long as it has sufficient electrical conductivity. For example, a metal such as Cu, Al, Fe, W, Ag, Au, or Pt, or stainless steel (SUS304, SUS316, or the like) is used. be able to.

As a material for the dielectrics 15 and 16, for example, an insulator or a material having a low electrical conductivity such as soda glass, quartz glass, or alumina may be used. The upper limit of the conductivity of the dielectrics 15 and 16 is preferably 6 × 10 ⁻⁴ S / m or less from the viewpoint of preventing leakage during application of a high voltage. It is preferable to use a dielectric having an alkali metal or alkaline earth metal on the surface as the dielectrics 15 and 16, since the efficiency of electron irradiation to CO ₂ is increased. Specifically, soda glass and soda lime glass are preferable. Barium titanate, SrBi ₂ Ta ₂ O ₉ , and K ₄ Fe (CN) ₆ 3H ₂ O are preferable. When a dielectric such as barium titanate, Pb (Zr, Ti) O ₃ , RbHSO ₄ , Sr ₂ CeS ₄ , K ₂ SeO ₄ is used as the dielectrics 15 and 16, the discharge efficiency is increased. It is preferable in terms of efficiency.

  A raw material tank 12 is connected to the parallel plate electrode reactor 20. The number of raw material tanks 12 can be changed according to the number of constituent components of the raw material gas. The flow rate of the source gas supplied from the source tank 12 is controlled using the mass flow 13. The parallel plate electrode reactor 20 is connected to a product tank 19. If it is not necessary to temporarily store the product, the product tank 19 is not necessarily required.

  In the carbon monoxide production apparatus of the present embodiment, the frequency at which a voltage is applied between the pair of electrodes by a high frequency power source is preferably 1 kHz or more and 1 MHz or less, and more preferably 3 kHz or more and 100 kHz or less. It is preferable to apply a voltage at the frequency because energy efficiency is high and stable discharge can be performed.

[Example 1]
Carbon monoxide was produced from a raw material gas as follows using a production apparatus having a coaxial electrode reactor according to the production apparatus shown in FIG.

〔manufacturing device〕
The carbon monoxide production apparatus used in Example 1 includes a cylindrical coaxial electrode reactor 3, an electrode 4 disposed so as to cover the outer surface of the reactor 3, and the reactor 3, as shown in FIG. An electrode 5 disposed in the center of the inside, a dielectric 10 (a part of the reactor 3) provided on the opposing surface of the electrode 5, a high-frequency power source 6 connected to the electrodes 4 and 5, and the reactor 3 was provided with a raw material tank 1 for supplying a raw material gas containing carbon dioxide.

  As the internal electrode (electrode 5), a SUS316 rod having a diameter of 6 mm was used. No dielectric for the internal electrode was installed. As the reactor 3, a quartz glass tube having an inner diameter of 1 cm and a thickness of 1.5 mm was used. The reactor 3 also served as a dielectric for the external electrode (electrode 4). At this time, the inter-electrode distance d (distance between the electrode 5 and the dielectric) was 2 mm. An aluminum foil with a width of 2 cm was used as the external electrode. The aluminum foil (external electrode) was wound around the outer surface of the quartz glass tube (reactor 3).

[Raw gas]
As the source gas, a mixed gas containing 40% by volume of CO _{2 and} 60% by volume of N ₂ was used. The flow rate of the source gas was 50 cc / min.

[Production of carbon monoxide]
Electrons were generated by applying a dielectric barrier discharge by applying a voltage between the electrode 4 and the electrode 5 by the high frequency power source 6. The applied voltage was a sine wave of ± 6 kV and the frequency was 40 kHz.

  A raw material gas was supplied from the raw material tank 1 to the reactor 3 via the mass flow 2 and was brought into contact with the generated electrons to obtain a product gas containing carbon monoxide. The production time of the carbon monoxide was 1 hour in total.

  The produced gas was analyzed by gas chromatography. The gas chromatography used for the analysis was “GC-2010plus” (trade name) manufactured by Shimadzu Corporation. The column used was “SHINCARBON ST” (trade name) [inner diameter: 3 mm, length: 6 m] manufactured by Shinwa Kako Co., Ltd. The temperature of the sampling line was maintained at 150 ° C., and the amount of sample gas was 1 ml. The carrier gas was He and the column flow rate was 30 ml / min. The column temperature raising program was maintained at 90 ° C. for 4 minutes from the start of analysis, then heated to 200 ° C. at 10 ° C./min, and then held at 200 ° C. for 15 minutes.

As a result of analyzing the product gas in this manner, the carbon selectivity was 100% for the carbon-containing material, and the conversion rate for CO ₂ was 25%.

[Plasma emission intensity measurement]
The emission intensity of the plasma was calculated based on a spectrum measured by a multi-channel spectrometer “PMA-12” (trade name) manufactured by Hamamatsu Photonics. The detector was tilted 45 ° upward at a position 6 cm below the electrode 4 and 6 cm outside. The exposure time was 19 milliseconds. The measured plasma emission spectrum is shown in FIG. The sum of the peak areas of the spectrum from wavelengths 305 nm to 385 nm was defined as the plasma emission intensity. The obtained plasma emission intensity was 11105 counts.

[Example 2]
Carbon monoxide was produced in the same manner as in Example 1 except that the width of the external electrode was 4 cm.
As a result of analyzing the product gas in the same manner as in Example 1, the carbon selectivity was 100% for CO selectivity and 46% for CO ₂ conversion.

[Example 3]
Carbon monoxide was produced in the same manner as in Example 1 except that CO ₂ was 40% by volume, Ar was 60% by volume, and the applied voltage in dielectric barrier discharge was ± 4 kV. As a result of analyzing the product gas in the same manner as in Example 1, as a carbon-containing material, the CO selectivity was 100% and the CO ₂ conversion was 22%.

[Example 4]
Carbon monoxide was produced in the same manner as in Example 1 except that the constituent components of the source gas were 10% by volume of CO ₂ and 90% by volume of air. As a result of analyzing the product gas in the same manner as in Example 1, the carbon selectivity was 100% for CO selectivity and 15% for CO ₂ conversion.

[Example 5]
Carbon monoxide was produced in the same manner as in Example 1 except that CO ₂ was 40% by volume, N ₂ was 59% by volume, and H ₂ S was 1% by volume. As a result of analyzing the product gas in the same manner as in Example 1, as a carbon-containing material, the CO selectivity was 99.99% and the CO ₂ conversion was 29%.

[Example 6]
Carbon monoxide was produced under the same conditions as in Example 5 except that the production time of carbon monoxide was 50 hours in total. As a result of analyzing the generated gas in the same manner as in Example 1, as a carbon-containing material, the CO selectivity was 99.99%, the CO ₂ conversion was 29%, and the CO selectivity and CO ₂ conversion There was no decrease in rate.

[Example 7]
Carbon monoxide was produced in the same manner as in Example 1 except that a soda glass tube having an inner diameter of 1 cm and a thickness of 1.5 mm was used as the reactor 3. As a result of analyzing the product gas in the same manner as in Example 1, the carbon selectivity was 100% for CO selectivity and 32% for CO ₂ conversion.

[Example 8]
Carbon monoxide was produced in the same manner as in Example 1 except that a reactor tube made of barium titanate glass having an inner diameter of 1 cm and a thickness of 1.5 mm was used as the reactor 3. The plasma emission spectrum was measured in the same manner as in Example 1, and the plasma emission intensity was measured to be 14432 counts. In Example 8, the emission intensity was about 1.3 times despite the same applied voltage as in Example 1. This is presumably because the discharge efficiency was improved by using barium titanate glass, which is a ferroelectric substance, as the dielectric, and the number of molecules excited to the plasma state increased. As a result of analyzing the generated gas in the same manner as in Example 1, as a carbon-containing material, the CO selectivity was 100%, and the CO ₂ conversion was 34%. The CO ₂ conversion in Example 8 was about 1.36 times higher than in Example 1.

[Example 9]
As in Example 1, except that a soda glass tube having an inner diameter of 1 cm and a thickness of 1.5 mm was used as the reactor 3, 1N nitric acid was circulated in the glass tube before the reaction and Na was removed from the inner surface of the glass tube. To produce carbon monoxide. As a result of analyzing the generated gas in the same manner as in Example 1, the carbon selectivity was 100% for CO selectivity and 14% for CO ₂ conversion.

1: raw material tank, 2: mass flow, 3: coaxial reactor, 4: external electrode, 5: internal electrode, 6: high frequency power supply, 7: product tank, 8: raw material gas, 9: generated gas, 10: internal electrode 11: Dielectric for external electrode, d: Distance between electrodes, 12: Raw material tank, 13: Mass flow, 14: Upper electrode, 15: Dielectric for upper electrode, 16: Dielectric for lower electrode, 17: Lower electrode, 18: high frequency power supply, 19: product tank, 20: reactor, 21: source gas, 22: product gas

Claims (8)

Step 1 for generating electrons by performing dielectric barrier discharge;
Step 2 of obtaining a product gas containing carbon monoxide by contacting the electrons generated in Step 1 with a raw material gas containing carbon dioxide;
A method for producing carbon monoxide comprising:   A source gas containing carbon dioxide is present between the electrodes with at least one of the opposing surfaces of the pair of electrodes covered with a dielectric, and a voltage is applied to the electrodes to discharge the carbon monoxide. The manufacturing method of carbon monoxide including the process of obtaining the product gas to contain.   The method for producing carbon monoxide according to claim 1 or 2, wherein the source gas further contains a rare gas.   The method for producing carbon monoxide according to any one of claims 1 to 3, wherein the dielectric contains an alkali metal or an alkaline earth metal.   The method for producing carbon monoxide according to any one of claims 1 to 4, wherein the dielectric is a ferroelectric. A reactor,
A pair of electrodes disposed in the reactor;
A dielectric provided on at least one of the opposing surfaces of the pair of electrodes;
A high-frequency power source connected to the pair of electrodes and applying a voltage between the electrodes;
A raw material gas supply device for supplying a raw material gas containing carbon dioxide to the reactor;
With
In the reactor, carbon monoxide is produced by causing electrons generated by applying a dielectric barrier discharge by applying a voltage between the electrodes to contact a source gas containing carbon dioxide, thereby generating carbon monoxide. apparatus.   The manufacturing apparatus according to claim 6, wherein the dielectric contains an alkali metal or an alkaline earth metal.   The manufacturing apparatus according to claim 6 or 7, wherein the dielectric is a ferroelectric.