CN113070012A

CN113070012A - Reaction device and method for generating methanol by using carbon dioxide and hydrogen

Info

Publication number: CN113070012A
Application number: CN202110290081.3A
Authority: CN
Inventors: 章旭明; 孙智
Original assignee: Zhejiang Lvran Environmental Engineering Technology Co ltd; Zhejiang University of Technology ZJUT
Current assignee: Zhejiang Lvran Environmental Engineering Technology Co ltd; Zhejiang University of Technology ZJUT
Priority date: 2021-03-16
Filing date: 2021-03-16
Publication date: 2021-07-06
Anticipated expiration: 2041-03-16
Also published as: CN113070012B

Abstract

The invention provides a reaction device and a method for generating methanol by using carbon dioxide and hydrogen, belonging to the technical field of chemical synthesis. The reaction device is divided into a first discharge area (4) and a second discharge area (5), because the outer surface of the first discharge area (4) is provided with a metal net (10), the first discharge area (4) becomes a high-temperature discharge area under the electrifying condition of the air inlet pipe (7), and carbon dioxide is converted into carbon monoxide under the high-temperature discharge condition and the action of a first catalyst and reacts with hydrogen to generate a small amount of methanol; because the outer surface of the second discharge area (5) is provided with the cooling device (12), under the condition that the air inlet pipe (7) is electrified, the second discharge area (5) becomes a low-temperature discharge area, and under the low-temperature discharge condition and the action of the second catalyst, carbon monoxide, unreacted carbon dioxide and hydrogen generate a large amount of methanol in the second discharge area (5).

Description

Reaction device and method for generating methanol by using carbon dioxide and hydrogen

Technical Field

The invention relates to the technical field of plasma chemical synthesis, in particular to a reaction device and a method for generating methanol by using carbon dioxide and hydrogen.

Background

With the rapid development of modern industryExhibition, CO₂The concentration rise has caused the consequences of global climate abnormality and grain yield reduction. Therefore, the emission reduction of carbon dioxide becomes a technical problem to be solved urgently. Among them, the conversion of carbon dioxide to produce fuels and chemicals is the most feasible strategy to achieve emission reduction and sustainable utilization of carbon resources. The reaction process for preparing methanol by directly hydrogenating carbon dioxide is capable of generating clean energy while reducing carbon emission, so that the method is widely concerned by people.

However, the reaction conditions for preparing methanol by directly hydrogenating catalytic carbon dioxide are severe, for example, the industrial hydrogenation reforming carbon dioxide reaction needs to be heated to more than 200 ℃ and pressurized to more than 3MPa under the action of a catalyst. The reaction conditions of high temperature and high pressure not only limit the large-scale production, but also bring about the waste of additional energy.

Dielectric barrier discharge is one type of plasma catalysis. Dielectric barrier discharge, also called silent discharge, is a gas discharge with an insulating dielectric inserted into the discharge space. When a sufficiently high ac voltage is applied across the electrodes, the gas between the electrodes breaks down to form an apparently uniform, stable discharge that is actually formed by a large number of fine, fast-pulse discharge channels, i.e., microdischarge channels. It belongs to non-thermal equilibrium discharge under high pressure. The insertion of a dielectric between the electrodes prevents the formation of a partial spark or arc discharge in the discharge space, thereby enabling the formation of a stable gas discharge at atmospheric pressure. Dielectric barrier discharge can be used to convert carbon dioxide to methanol at near ambient temperature and pressure, but carbon dioxide conversion and methanol selectivity are not high. Current catalysis of CO using plasma alone₂The highest carbon dioxide conversion rate of the prepared methanol is 8 percent, and the highest selectivity of the methanol is less than 1 percent.

Disclosure of Invention

In view of the above, the present invention is directed to a reaction apparatus and a method for generating methanol using carbon dioxide and hydrogen, wherein the apparatus provided by the present invention has a simple structure, and can effectively improve the conversion rate of carbon dioxide and the selectivity of methanol.

In order to achieve the above object, the present invention provides the following technical solutions:

the invention provides a reaction device for generating methanol by using carbon dioxide and hydrogen, which comprises an insulating tube 1, wherein the top of the insulating tube 1 is provided with an air inlet 2, and the bottom of the insulating tube 1 is provided with an air outlet 3; the insulating tube 1 is divided into a first discharge area 4 and a second discharge area 5 from top to bottom, and the volume ratio of the first discharge area 4 to the second discharge area 5 is 3: 1-1: 3; the first discharge area 4 and the second discharge area 5 are separated by a first screen 6; a first catalyst is placed on the first screen plate 6;

the air inlet pipe 7 penetrates through the upper wall of the insulating pipe 1 and extends to the bottom of the insulating pipe 1, and the air inlet pipe 7 is coaxial with the insulating pipe 1; the air inlet pipe 7 is provided with a first exhaust hole 8 and a second exhaust hole 9, the first exhaust hole 8 is located in the first discharge area 4, and the second exhaust hole 9 is located in the second discharge area 5; the air inlet pipe 7 is made of metal;

the metal net 10 is positioned on the outer surface of the first discharge area 4 of the insulating tube 1, and the metal net 10 is connected with the grounding device 11;

the cooling device 12 is positioned on the outer surface of the second discharge area 5 of the insulating tube 1;

and the second screen plate 13 is positioned at the bottom of the second discharge area 5, and a second catalyst is placed on the second screen plate.

Preferably, the opening area of the first exhaust hole 8 is 60-70% of the cross-sectional area of the air inlet pipe 7; the opening area of the second exhaust hole 9 is 30-40% of the cross section area of the air inlet pipe 7.

Preferably, the material of the air inlet pipe 7 is 304 stainless steel or 316 stainless steel.

Preferably, the coverage area of the metal mesh 10 is 30-35% of the outer surface area of the insulating tube 1.

Preferably, the cooling device 12 is a glass tube heat exchanger, and a heat exchange medium of the glass tube heat exchanger is water; the glass tube heat exchanger is provided with a water inlet 14 and a water outlet 15; the coverage area of the glass tube heat exchanger is 30-35% of the outer surface area of the insulating tube 1.

Preferably, the first catalyst is Cu @ Al₂O₃The second catalyst is Cu/Zn @ Al₂O₃。

The invention provides a method for generating methanol by using carbon dioxide and hydrogen by using the reaction device, which comprises the following steps:

(1) introducing H into the air inlet pipe 7₂Introducing CO into the gas inlet 2₂H discharged from the first exhaust port 8 by energizing the intake pipe 7₂With CO₂Carrying out pre-reaction in the first discharge area 4 to obtain pre-reaction produced gas, wherein the pre-reaction produced gas comprises CO and methanol;

(2) the pre-reaction produces gas and unreacted CO₂Enters a second discharge area 5, and under the action of a temperature reducing device 12, CO and CO are generated₂H discharged from the second exhaust hole 9₂Reforming reaction is carried out to obtain methanol.

Preferably, said H₂With CO₂The flow rate ratio of (1) to (3-4: 1).

Preferably, the frequency of the power supply during electrification is 7-12 kHz, the voltage is 5-10 kV, and the discharge power is 12-32W.

Preferably, the temperature controlled by the cooling device 12 is 5-30 ℃.

The invention provides a reaction device for generating methanol by using carbon dioxide and hydrogen, which comprises an insulating tube 1, an air inlet pipe 7 penetrating through the upper wall of the insulating tube 1 and extending to the bottom of the insulating tube 1, a metal net 10 positioned on the outer surface of a first discharge area 4 of the insulating tube 1, a cooling device 12 positioned on the outer surface of a second discharge area 5 of the insulating tube 1, a first mesh plate 6 for containing a first catalyst and a second mesh plate for containing a second catalyst. The reaction device is divided into a first discharge area 4 and a second discharge area 5, and as the metal mesh 10 is arranged on the outer surface of the first discharge area 4, under the condition that the air inlet pipe 7 is electrified, the air inlet pipe 7 is a high-voltage electrode, and the metal mesh 10 connected with the grounding device forms a grounding electrode, the first discharge area 4 becomes a high-temperature discharge area, carbon dioxide is converted into carbon monoxide under the high-temperature discharge condition and the action of a first catalyst, and the carbon monoxide reacts with hydrogen to generate a small amount of methanol; because the outer surface of the second discharge area 5 is provided with the cooling device 12, the second discharge area 5 becomes a low-temperature discharge area under the condition that the air inlet pipe 7 is electrified, and under the low-temperature discharge condition and the action of the second catalyst, carbon monoxide, unreacted carbon dioxide and hydrogen generate a large amount of methanol in the second discharge area 5. The reaction device is divided into the first discharge area 4 and the second discharge area 5, and the catalytic reforming reaction can be divided into two processes, so that the conversion rate of carbon dioxide and the selectivity of methanol are improved. The device can combine the discharge plasma catalysis with the catalyst catalysis, thereby further improving the carbon dioxide conversion rate and the methanol selectivity. The results of the examples show that the conversion rate of carbon dioxide obtained by the device provided by the invention is 38.65-51.3%, and the selectivity of methanol is 71.3-77.6%.

Meanwhile, the device provided by the invention has a simple structure, can realize the preparation of methanol by reforming the carbon dioxide to prepare hydrogen without additional heating and pressurizing devices, and can save resources and reduce production cost.

Drawings

FIG. 1 is a schematic structural diagram of a reaction apparatus of the present invention, wherein 1 represents an insulating tube, 2 represents an air inlet, 3 represents an air outlet, 4 represents a first discharge area, 5 represents a second discharge area, 6 represents a first mesh plate, 7 represents an air inlet, 8 represents a first exhaust hole, 9 represents a second exhaust hole, 10 represents a metal mesh, 11 represents a grounding device, 12 represents a temperature reduction device, 13 represents a second mesh plate, 14 represents a water inlet, and 15 represents a water outlet;

FIG. 2 is a schematic size diagram of a reaction apparatus according to the present invention.

Detailed Description

The invention provides a reaction device for generating methanol by using carbon dioxide and hydrogen, which comprises an insulating tube 1, wherein the top of the insulating tube 1 is provided with an air inlet 2, and the bottom of the insulating tube 1 is provided with an air outlet 3; the insulating tube 1 is divided into a first discharge area 4 and a second discharge area 5 from top to bottom, and the volume ratio of the first discharge area 4 to the second discharge area 5 is 1: 3-3: 1; the first discharge area 4 and the second discharge area 5 are separated by a first screen 6; a first catalyst is placed on the first screen plate 6;

and the second screen plate is positioned at the bottom of the second discharge area 5, and a second catalyst is placed on the second screen plate.

The reaction apparatus for generating methanol using carbon dioxide and hydrogen provided by the present invention comprises an insulating tube 1. In the present invention, the material of the insulating tube 1 is preferably a quartz glass tube; the invention has no special requirements on the size specification of the insulating tube 1, and can be designed correspondingly according to the actual situation. In the invention, the top of the insulating tube 1 is provided with an air inlet 2, and the air inlet 2 is used for introducing CO₂(ii) a And the bottom of the insulating tube 1 is provided with an air outlet 3 for discharging final produced gas.

In the invention, the insulating tube 1 is divided into a first discharge area 4 and a second discharge area 5 from top to bottom, and the volume ratio of the first discharge area 4 to the second discharge area 5 is 1: 3-3: 1, preferably 1: 2-2: 1, and further preferably 1: 1. In the present invention, the first and second arrester regions 4 and 5 are separated by a first mesh 6; the first screen 6 is provided with a first catalyst.

In the invention, the first mesh plate 6 is horizontally fixed in the insulating tube 1, and the material of the first mesh plate 6 is preferably metal, and more preferably stainless steel; in the present invention, the pore diameter of the first mesh plate 6 is preferably 40 to 60 mesh, and more preferably 50 mesh. In the present invention, the first steel plate is used to contain a first catalyst.

In the present invention, the first catalyst is preferably Cu @ Al₂O₃Catalyst, said Cu @ Al₂O₃The catalyst is Al₂O₃A Cu-supported catalyst, wherein the loading amount of Cu in the first catalyst is preferably 8%.

The reaction device for generating methanol by using carbon dioxide and hydrogen comprises an air inlet pipe 7 which penetrates through the upper wall of an insulating pipe 1 and extends to the bottom of the insulating pipe 1, wherein the air inlet pipe 7 is coaxial with the insulating pipe 1; intake pipe 7 is equipped with first exhaust hole 8 and second exhaust hole 9, first exhaust hole 8 is located first discharge area 4, second exhaust hole 9 is located second discharge area 5. In the present invention, the material of the intake pipe 7 is metal, and more preferably 304 stainless steel or 316 stainless steel. The invention has no special requirement on the inner diameter of the air inlet pipe 7, and the air inlet pipe 7 is designed correspondingly according to the actual gas flow, and as a specific embodiment of the invention, the inner diameter of the air inlet pipe 7 is preferably 2 mm.

In the present invention, the number of the first exhaust holes 8 is preferably plural; when the number of the first exhaust holes 8 is plural, the total opening area of the first exhaust holes 8 is preferably 60 to 70% of the cross-sectional area of the intake pipe 7, and more preferably 64 to 68%; in the present invention, the number of the first exhaust holes 8 is preferably plural; when the number of the first exhaust holes 8 is plural, the total opening area of the first exhaust holes 8 is preferably 30 to 40%, and more preferably 32 to 36% of the cross-sectional area of the intake pipe 7. The invention can lead H to be discharged through the arrangement of the first exhaust hole 8 and the second exhaust hole 9₂Respectively to the first discharge area 4 and the second discharge area 5. Furthermore, the invention can control the H in the first discharge area 4 and the second discharge area 5 by controlling the opening area of the first exhaust hole 8 and the second exhaust hole 9₂The flow rate of (c).

The reaction device for generating methanol by using carbon dioxide and hydrogen provided by the invention comprises a metal mesh 10 positioned on the outer surface of the first discharge area 4 of the insulating tube 1. In the invention, under the condition that the air inlet pipe 7 is electrified, the air inlet pipe 7, the insulating pipe 1 and the metal mesh 10 can form a high-temperature discharge area, and plasma is generated in the discharge process. In the present invention, the metal mesh 10 is preferably made of stainless steel; the mesh aperture of the metal net 10 is preferably 40-60 meshes, and more preferably 50 meshes. In the present invention, the coverage area of the metal mesh 10 is 30 to 35%, preferably 32 to 34% of the outer surface area of the insulating tube 1.

In the present invention, the metal mesh 10 is connected to a grounding device 11; in the present invention, the grounding device 11 is preferably a metal rod, and the metal rod is connected with a grounding wire; as an embodiment of the invention, the metal rod is positioned on the surface of the insulating tube 1 and fixed between the metal mesh 10 and the cooling device 12.

The reaction device for generating methanol by using carbon dioxide and hydrogen comprises a cooling device 12 positioned on the outer surface of the second discharge area 5 of the insulating tube 1. In the invention, the cooling device 12 is preferably a glass tube heat exchanger, and water is introduced into the glass tube heat exchanger; the glass tube heat exchanger is provided with a water inlet 14 and a water outlet 15; the coverage area of the glass tube heat exchanger is preferably 30-35% of the outer surface area of the insulating tube 1, and more preferably 32-34%.

The reaction device for generating the methanol by utilizing the carbon dioxide and the hydrogen comprises a second screen plate 13 positioned at the bottom of the second discharge area 5, and a second catalyst is placed on the second screen plate. In the invention, the second mesh plate is horizontally fixed in the insulating tube 1, and the material of the second mesh plate 13 is preferably metal, and more preferably stainless steel; in the present invention, the pore diameter of the second mesh plate 13 is preferably 40 to 60 mesh, and more preferably 50 mesh. In the present invention, the second mesh plate 13 is used to hold a second catalyst.

In the present invention, the second catalyst is preferably Cu/Zn @ Al₂O₃The Cu/Zn @ Al₂O₃The catalyst is Al₂O₃A catalyst supporting an active ingredient, the active ingredient being Cu and/or Zn; the loading amount of the active ingredient in the second catalyst is preferably 10%.

The device can combine the discharge plasma catalysis with the catalyst catalysis, thereby further improving the carbon dioxide conversion rate and the methanol selectivity. The present invention uses a Cu-based catalyst as the first catalyst because the Cu-based catalyst can generate partially oxidized Cu δ O particles in plasma to make CO₂CO can form intermediate products with carboxylate and formate structures, and the intermediate products are further hydrogenated to generate methanol; the invention uses Cu/Zn-based catalyst as the second catalyst, the Zn component enhances the adsorption energy of Cu to key intermediate products and utilizes H₂Protecting the generated methanol; the invention selects Al₂O₃As a carrier, can enhance the discharge in the discharge regionThe effect is to further improve the methanol selectivity. Therefore, the device provided by the invention can perfectly realize high CO₂Conversion and methanol selectivity.

In the present invention, a schematic diagram of the reaction apparatus for generating methanol using carbon dioxide and hydrogen is shown in fig. 1.

As an embodiment of the present invention, the size of the reaction apparatus for producing methanol using carbon dioxide and hydrogen is shown in FIG. 2, and the unit in FIG. 2 is mm.

The invention provides a method for generating methanol by utilizing carbon dioxide and hydrogen based on the reaction device, which comprises the following steps:

(2) gas production by pre-reaction and unreacted CO₂Enters a second discharge area 5, and under the action of a temperature reducing device 12, CO and CO are generated₂H discharged from the second exhaust hole 9₂Reforming reaction is carried out to obtain methanol.

In the present invention, before the energization, it is preferable to purge the insulating tube 1 with air to discharge the air in the insulating tube 1. In the present invention, the air washing method is preferably: continuously introducing H₂And CO₂5min。

The invention leads H into the air inlet pipe 7₂Introducing CO into the gas inlet 2₂H discharged from the first exhaust port 8 by energizing the intake pipe 7₂With CO₂And carrying out pre-reaction in the first discharge area 4 to obtain pre-reaction produced gas, wherein the pre-reaction produced gas comprises CO and methanol. In the present invention, said H₂With CO₂The flow rate ratio of (2) to (3-4: 1), preferably (3.2-3.5: 1). In the present invention, said H₂The introducing rate is preferably 300 to 600sccm, more preferably 400 to 500 sccm; the CO is₂The flow rate of (A) is preferably 100 to 150sccm, more preferably 120 sccm.

In the invention, the frequency of the power supply during electrification is preferably 7-12 kHz, and more preferably 8-10 kHz; the voltage is preferably 5-10 kV, and more preferably 6-8 kV; the discharge power is preferably 12 to 32W, and more preferably 20 to 30W.

In the invention, the temperature controlled by the cooling device 12 is preferably 5-30 ℃, and more preferably 10-20 ℃. When the cooling device 12 is a glass tube heat exchanger, the flow rate of water in the heat exchanger is 80-100 mL/min, and more preferably 90 mL/min.

The reaction apparatus and method for producing methanol using carbon dioxide and hydrogen according to the present invention will be described in detail with reference to the following examples, which should not be construed as limiting the scope of the present invention.

Example 1

Methanol was produced using carbon dioxide and hydrogen using the reaction apparatus shown in fig. 1, as follows:

(1) introducing carbon dioxide and hydrogen into the insulating tube 1 from an air inlet 2 and an air inlet pipe 7 respectively, continuously introducing air for 5min, and removing air in a pipeline;

(2) h is introduced into the air inlet pipe 7 at the rate of 300sccm₂Introducing CO into the gas inlet 2 at a rate of 100sccm₂Electrifying the air inlet pipe 7, wherein the power frequency is 8kHz, the voltage is 7kv, and the discharge power is 22W; h discharged from the first exhaust hole 8₂With CO₂Carrying out pre-reaction in the first discharge area 4 to obtain pre-reaction produced gas, wherein the pre-reaction produced gas comprises CO and methanol;

(3) gas production by pre-reaction and unreacted CO₂Entering a second discharge area 5, and introducing normal temperature water, CO and CO into the glass tube heat exchanger at a rate of 100mL/min₂H discharged from the second exhaust hole 9₂Reforming reaction is carried out to obtain methanol.

After the reaction is finished, the content of methanol in the final produced gas is measured by a gas chromatography-mass spectrometer (GC-MS), and the conversion rate of carbon dioxide is finally determined to be 38.65%, and the selectivity of methanol is finally determined to be 71.3%.

Example 2

(2) h is fed into the gas inlet pipe 7 at a rate of 150sccm₂Introducing CO into the gas inlet 2 at a rate of 450sccm₂Electrifying the air inlet pipe 7, wherein the power frequency is 10kHz, the voltage is 8kv, and the discharge power is 28W; h discharged from the first exhaust hole 8₂With CO₂Carrying out pre-reaction in the first discharge area 4 to obtain pre-reaction produced gas, wherein the pre-reaction produced gas comprises CO and methanol;

(3) gas production by pre-reaction and unreacted CO₂Entering a second discharge area 5, and introducing normal temperature water, CO and CO into the glass tube heat exchanger at a rate of 80mL/min₂H discharged from the second exhaust hole 9₂Reforming reaction is carried out to obtain methanol.

After the reaction is finished, the content of methanol in the final produced gas is measured by a gas chromatography-mass spectrometer (GC-MS), and the conversion rate of carbon dioxide is finally measured to be 41.4%, and the selectivity of methanol is finally measured to be 76.4%.

Example 3

(2) h is fed into the gas inlet pipe 7 at a rate of 150sccm₂Introducing CO into the gas inlet 2 at a rate of 600sccm₂Electrifying the air inlet pipe 7, wherein the power frequency is 10kHz, the voltage is 8kv, and the discharge power is 30W; h discharged from the first exhaust hole 8₂With CO₂Carrying out pre-reaction in the first discharge area 4 to obtain pre-reaction produced gas, wherein the pre-reaction produced gas comprises CO and methanol;

(3) gas production by pre-reaction and unreacted CO₂Entering a second discharge area 5, and introducing normal temperature water, CO and CO into the glass tube heat exchanger at a rate of 90mL/min₂H discharged from the second exhaust hole 9₂Reforming reaction is carried out to obtain methanol.

After the reaction is finished, the content of methanol in the final produced gas is measured by a gas chromatography-mass spectrometer (GC-MS), and the conversion rate of carbon dioxide is finally measured to be 51.3%, and the selectivity of methanol is finally measured to be 77.6%.

The foregoing is only a preferred embodiment of the present invention, and it should be noted that, for those skilled in the art, various modifications and decorations can be made without departing from the principle of the present invention, and these modifications and decorations should also be regarded as the protection scope of the present invention.

Claims

1. A reaction device for generating methanol by using carbon dioxide and hydrogen comprises an insulating tube (1), wherein the top of the insulating tube (1) is provided with an air inlet (2), and the bottom of the insulating tube is provided with an air outlet (3); the insulating tube (1) is divided into a first discharge area (4) and a second discharge area (5) from top to bottom, and the volume ratio of the first discharge area (4) to the second discharge area (5) is 3: 1-1: 3; the first discharge area (4) and the second discharge area (5) are separated by a first screen plate (6); a first catalyst is placed on the first screen plate (6);

the air inlet pipe (7) penetrates through the upper wall of the insulating pipe (1) and extends to the bottom of the insulating pipe (1), and the air inlet pipe (7) is coaxial with the insulating pipe (1); the air inlet pipe (7) is provided with a first exhaust hole (8) and a second exhaust hole (9), the first exhaust hole (8) is located in the first discharge area (4), and the second exhaust hole (9) is located in the second discharge area (5); the air inlet pipe (7) is made of metal;

the metal net (10) is positioned on the outer surface of the first discharge area (4) of the insulating tube (1), and the metal net (10) is connected with the grounding device (11);

the cooling device (12) is positioned on the outer surface of the second discharge area (5) of the insulating tube (1);

and the second screen plate (13) is positioned at the bottom of the second discharge area (5), and a second catalyst is placed on the second screen plate.

2. The reaction device according to claim 1, wherein the opening area of the first exhaust hole (8) is 60-70% of the cross-sectional area of the inlet pipe (7); the opening area of the second exhaust hole (9) is 30-40% of the cross section area of the air inlet pipe (7).

3. The reactor according to claim 1, characterized in that the material of the inlet pipe (7) is 304 stainless steel or 316 stainless steel.

4. The reactor device according to claim 1, wherein the area covered by the metal mesh (10) is 30-35% of the outer surface area of the insulating tube (1).

5. The reaction device according to claim 1, wherein the temperature reduction device (12) is a glass tube heat exchanger, and the heat exchange medium of the glass tube heat exchanger is water; the glass tube heat exchanger is provided with a water inlet (14) and a water outlet (15); the coverage area of the glass tube heat exchanger is 30-35% of the outer surface area of the insulating tube (1).

6. The reactor apparatus of claim 1, wherein the first catalyst is Cu @ Al₂O₃The second catalyst is Cu/Zn @ Al₂O₃。

7. The method for producing methanol using carbon dioxide and hydrogen gas in accordance with any one of claims 1 to 6, comprising the steps of:

(1) introducing H into the air inlet pipe (7)₂Introducing CO into the gas inlet (2)₂H discharged from the first exhaust hole (8) by energizing the intake pipe (7)₂With CO₂Carrying out pre-reaction in the first discharge area (4) to obtain pre-reaction produced gas, wherein the pre-reaction produced gas comprises CO and methanol;

(2) the pre-reaction produces gas and unreacted CO₂Enters a second discharge area (5) and is subjected to CO and CO under the action of a temperature reduction device (12)₂H discharged from the second exhaust hole (9)₂Reforming reaction is carried out to obtain methanol.

8. The method of claim 7, wherein H is₂With CO₂The flow rate ratio of (1) to (3-4: 1).

9. The method according to claim 7, wherein the power supply has a frequency of 7 to 12kHz, a voltage of 5 to 10kV, and a discharge power of 12 to 32W when energized.

10. The method according to claim 7, characterized in that the temperature controlled by the cooling device (12) is 5-30 ℃.