RU80450U1 - DEVICE FOR PRODUCING A HYDROGEN-CONTAINING GAS IN A MICROWAVE DISCHARGE PLASMA - Google Patents

Abstract

The utility model relates to the field of production of hydrogen-containing gases. Hydrogen-containing gases are widely used as raw materials for various chemical synthesis processes, as well as for the production of high-purity hydrogen from them. The problem to which the proposed utility model is directed is to create a device that is simple to manufacture and does not include expensive mechanical and electronic devices, which will allow obtaining hydrogen-containing gases with a high degree of conversion using a wide range of gaseous hydrocarbons and carbon dioxide, oxygen or air. To solve this problem, a device for producing hydrogen-containing gas in a microwave plasma contains a buffer tank for mixing gases, a reaction chamber, a microwave oscillator and a resonator and is equipped with a variable power supply unit and a waveguide made in the form of coaxially located external and internal electrodes, the external electrode being is a reaction chamber, and the inner electrode is made hollow with a nozzle for sequential supply of argon from the buffer tank and a gas mixture consisting of hydrocarbon gases and at least one gas selected from the series: air, oxygen, carbon dioxide, into the reaction chamber, while the nozzle is made of refractory material. 1 ill.

Description

The utility model relates to the field of production of hydrogen-containing gases. Hydrogen-containing gases are widely used as raw materials for various chemical synthesis processes, as well as for the production of high-purity hydrogen from them.

The traditional way to obtain hydrogen-containing gases is the steam conversion of hydrocarbon-containing raw materials or coal. The use of steam conversion requires preliminary compression and heating of the gaseous feedstock, the use of relatively bulky and complicated equipment, which leads to energy losses due to the low efficiency of the used heating devices (burners or electric heaters).

Currently, plasma technology and technology are used for gas processing.

A device for producing hydrogen by the decomposition of ammonia or other gases containing hydrogen atoms [US patent No. 7037484 B1, IPC С01В 3/02], consisting of a resonator separated by a dielectric diaphragm to prevent contact of the gas with the antenna, antenna, microwave oscillator, injector and exhaust valve. Ammonia or another gas containing hydrogen atoms is injected through the injector into the cavity, where, under the influence of the electromagnetic field created by the antenna, a microwave discharge is ignited and the gas decomposes into hydrogen and by-products. The resulting gas mixture is discharged through an exhaust valve and separated.

The disadvantages of the known device are: the complexity of initiating an electrodeless discharge, the need for high-precision execution of the resonator chamber, the complexity of scaling the design and the limited use of the known device by the decomposition of ammonia and methane, the formation of by-products.

A known installation for producing hydrogen in a microwave discharge plasma [application EP No. 1881944 A1, IPC С01В 3/02, 2008], which includes a reaction chamber, a gas supply unit, a microwave oscillation generator, a waveguide, a gas pumping unit and a separator. The installation works as follows: gas is pumped out of the reaction chamber to maintain a reduced pressure in it, hydrocarbon gas is passed through the reaction chamber, the gas is treated with microwave radiation, the gas is decomposed into carbon and hydrogen, and hydrogen is separated from the resulting mixture.

The disadvantages of the known installation are: the need to maintain low pressure in the reaction chamber, which reduces the energy efficiency of the device and limits its productivity, the formation of a by-product of carbon, the need to remove it from the reaction chamber, the danger of damage to the device when carbon is deposited on the parts.

A device for producing hydrogen from hydrocarbon fuels is known [WO application No. 2007116225 A1, IPC С01В 3/34, 2007], consisting of a mixer, heat exchangers, a reaction chamber, a microwave oscillation generator, two electrodes located opposite each other in the reaction chamber, one of the electrodes is hollow and serves to remove the product from the reaction chamber, and the gas mixture is fed into the reaction chamber at an angle so that the movement of gases in the reaction chamber is vortex. The initial gas mixture is exposed to a microwave discharge plasma when passing through the gap between the electrodes and is converted into a hydrogen-containing gas, which is removed through the hollow electrode.

The disadvantages of the known device are: the need for high-precision execution of the reaction chamber to find the electrodes near the maximum of the microwave field, the presence of small gaps in the structure, including between the electrodes (about 0.2 mm), which increases the gas-dynamic resistance of the structure and limits the gas flow rate, causes intense emission one of the electrodes and limits the time of continuous operation of the device.

The closest in technical essence and the achieved result to the claimed utility model is a device for converting fossil fuels into a hydrogen-containing gas in a microwave discharge plasma [application WO No. 0109031, IPC С01В 3/34, 2001], selected for the prototype.

This device includes an air heater, water and fuel evaporators, a heat exchanger, a mixer, a reaction chamber, a microwave oscillator, a resonator, a discharge initiator, and a cyclone heat exchanger.

The device operates as follows. Air is preheated using an arc plasmatron, water and fuel are evaporated in evaporators, air and water vapor are additionally heated using a heat exchanger due to recirculated heat, air is mixed with water and fuel vapors, then a microwave discharge is initiated in the reaction chamber, and the resulting mixture is microwaved radiation in the reaction chamber, the reaction products are separated and cooled in a cyclone heat exchanger, while removing the recirculated heat.

The disadvantages of the prototype are: the complexity and bulkiness of the design, the limited time of the continuous operation of the device due to the use of an arc plasmatron in the air heater, possible contamination of the hydrogen-containing gas produced by the erosion products of the arc plasma torch electrodes, the need to use special devices to initiate a discharge in the reaction chamber, and the multi-stage process . High energy costs for preheating the air and evaporating water and fuel reduce the energy efficiency of the device and increase its cost and design complexity. In addition, in the known device, the microwave discharge is located near the axis of the reaction chamber and because of this, the near-wall part of the gas stream is not subjected to plasma treatment, which reduces the degree of conversion of raw materials in this device.

The problem to which the proposed utility model is directed is to create a device that is simple to manufacture and does not include expensive mechanical and electronic devices, which will allow obtaining hydrogen-containing gases with a high degree of conversion using a wide range of gaseous hydrocarbons and carbon dioxide, oxygen or air.

The problem is solved by the described device for producing a hydrogen-containing gas in a microwave discharge plasma containing a mixing buffer tank, a reaction chamber, a microwave oscillator and a resonator, which, according to a utility model, further comprises a unit

variable power supply and a waveguide made in the form of coaxially arranged external and internal electrodes, the external electrode being a reaction chamber and the internal electrode made hollow with a nozzle for sequential supply of argon and a gas mixture consisting of hydrocarbon gases and at least , one gas selected from the series: air, oxygen, carbon dioxide, into the reaction chamber, while the nozzle is made of refractory material.

In a particular embodiment, the nozzle is made of tantalum.

The basis of the microwave torch is a waveguide. The internal hollow electrode of the waveguide is shorter than the external. Near the tip of the nozzle - there is a maximum of the electric field of the wave. As energy accumulates in the waveguide, the field increases and gas breakdown occurs. An extended plasma jet (torch) is formed in the gas stream.

The invention is illustrated by a figure.

A device for producing a hydrogen-containing gas includes technologically related: a buffer tank for mixing gases 1, a reaction chamber 2, an internal hollow electrode 3, a nozzle 4, a power source 5, a microwave oscillator (magnetron) 6, and a resonator 7.

A plasma-forming gas (argon) through a buffer tank for gas mixing 1, designed to smooth out pressure pulsations in the working chamber and mixing the source gases, is fed through an internal hollow electrode 3 with a nozzle 4 made of a refractory material pointed at the end into the reaction chamber 2, which is external electrode.

After turning on the power source 5, the microwave oscillator (magnetron) 6 generates a microwave field in the resonator 7. Using the internal hollow electrode 3, microwave energy is removed from the resonator and concentrated at the end of the nozzle 4. The use of argon as a plasma-forming gas and pointed at the end of the nozzle 4 provides a breakdown of gas at atmospheric pressure and obtaining a stable plasma torch.

After the torch is brought into a stationary state, the plasma-forming gas (argon) is replaced by a working gas mixture (carbon dioxide, hydrocarbon-containing gases, water vapor, oxygen, air).

The proposed device is illustrated by the following examples.

Example 1

Argon is fed through a mixing buffer tank at atmospheric pressure through a central hollow electrode, which is the internal electrode of the waveguide. After the magnetron is turned on, a discharge is initiated at the nozzle end, which propagates along the axis of the waveguide, forming a torch. After the steady state operation of the torch has been established, carbon dioxide and methane are supplied to the mixing buffer tank at a ratio of 60:57, while the flow of argon is stopped. To select the optimal operating mode, the gas flow rate varies from 200 l / h to 500 l / h. The input of microwave energy is carried out by a power source with adjustable power from 200 to 1000 watts. The energy consumption for producing synthesis gas with a ratio of H ₂ : CO = 1: 1 is 0.70-0.88 kWh / m ³ .

Example 2

To obtain a hydrogen-containing gas (synthesis gas - a mixture of H ₂ and CO in a ratio of 2: 1) after feeding argon into the mixing buffer tank, a mixture of air and methane in a volume ratio of 90:40 is fed. Gas flow rates range from 200 l / h to 500 l / h. The input of microwave energy is carried out by a power source with adjustable power from 200 to 1000 watts. The energy consumption for producing synthesis gas with a ratio of H ₂ : CO = 2: 1 is 1.25-1.48 kWh / m ³ .

The proposed utility model allows to obtain a hydrogen-containing gas from a mixture of various gaseous hydrocarbons and carbon dioxide, oxygen, air or water vapor using a simple to manufacture and not including expensive mechanical and electronic devices. The design of the device ensures the passage through the plasma torch of the entire source gas stream and, due to this, achieve a high degree of conversion of hydrocarbon feedstocks.

By changing the ratio of the source gases, it is possible to obtain a hydrogen-containing gas of various compositions.

The device also allows you to generate a plasma torch near the internal electrode using a conventional magnetron used in household microwave ovens having a power of less than 1 kW and a radiation frequency of 2.45 GHz.

Claims (2)

1. A device for producing hydrogen-containing gas in a microwave discharge plasma containing a mixing tank, a reaction chamber, a microwave oscillator and a resonator, characterized in that the device further comprises a variable power supply and a waveguide made in the form of coaxially located external and internal electrodes moreover, the outer electrode is a reaction chamber, and the inner electrode is made hollow with a nozzle for sequential supply of argon and gas mixture from the buffer tank, consisting of hydrocarbon gases and at least one gas selected from the series: air, oxygen, carbon dioxide, water vapor, into the reaction chamber, while the nozzle is made of refractory material. 2. The device according to claim 1, characterized in that the nozzle is made of tantalum.