NL1001513C1 - Catalytically producing combustible gases, e.g., for energy generation - Google Patents

Abstract

One component in a gas mixture is converted in a reaction at high temperature in a reactor containing a catalyst. The reaction is endothermic and an extra component is added to the reactor to create an exothermic reaction to offset the endothermic conversion. Also claimed is the catalytic treatment of tar-containing gas mixtures as described above.

Description

Process for the catalytic treatment of a gas mixture

The present invention relates to a process for catalytically converting a component of a gaseous mixture, wherein the gaseous mixture is fed to a reactor device containing catalyst material and a gas mixture treated at an elevated temperature is discharged.

Such a method is known, for example for the catalytic conversion of tar into tar-containing gas mixtures from gasification processes. In such gasification processes, an organic raw material is heated in the presence of an undersized oxygen. This creates a gas mixture that is free of oxygen and with a high content of flammable components. Such a gas mixture can be used for generating electricity with a gas turbine or gas engine. Electricity is generated more efficiently with a gas turbine than with direct combustion of the organic raw material used for gasification, such as coal or wood chips. The presence of tar in the gas mixture causes deposits in the gas turbine or gas engine, which makes trouble-free operation of such ash-working devices impossible. By catalytically converting tar, the gas mixture is brought into a form which is suitable for supply to a gas turbine.

The known process has the drawback that carbon deposits on the catalyst, which has a negative effect on the operation of the catalyst and shortens the operating time of the reactor. Carbon deposition can be prevented by operating the reactor at a high temperature, but heating the reactor is greatly at the expense of the overall efficiency.

The present invention aims to provide a method which makes it possible to operate a reactor device at elevated temperatures and to limit the loss of efficiency.

To this end, the process according to the invention is characterized in that the conversion of the component is endothermic and an agent is fed to the reactor device which undergoes a reaction to yield heat in such an amount as 1 0 0 1 5 1 3 2 necessary for the endothermic conversion to proceed. For example, the agent can react with a further component of the gaseous mixture. Therefore, heat is generated at the endothermic reaction, which is very efficient from an energetic point of view.

There is thus provided a method by which it is possible to efficiently supply the heat to a reactor device required for an endothermic conversion.

In a preferred embodiment, the gaseous mixture is a flammable gas mixture and oxygen is used as the agent fed to the reactor apparatus.

Reactions with oxygen with a flammable compound are at least substantially decreasing at high temperatures in general, and are therefore very suitable for further raising a hot gas mixture in temperature.

According to a preferred embodiment of the process according to the invention, a tar-containing gas mixture is used as the gas mixture fed to the reactor device.

The process according to the invention makes it possible to convert tar with great efficiency, thereby effectively preventing the formation of carbon on the catalyst material present in the reactor equipment.

A further preferred embodiment is characterized in that a reactor device is used with a first heat exchanger part, a catalyst part and a second heat exchanger part, wherein the gaseous mixture is supplied to the first heat exchanger part, heat is transferred from the first heat exchanger part, the thus the heated gaseous mixture in the catalyst portion is catalytically treated, and the catalytically treated gaseous mixture is passed through the second heat exchanger portion and heat is transferred from the catalytically treated gaseous mixture to the second heat exchanger portion.

With such a method, that part of the reactor device where the conversion of the component, i.e. the catalyst part, takes place, is efficiently kept at temperature and heat losses through the catalytically treated gaseous mixture remain limited.

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According to a favorable embodiment, the gaseous mixture is alternately supplied to the first and the second heat exchanger part and discharged via the second and the first heat exchanger part, respectively.

This method makes it possible to carry out energy-efficient reactions efficiently with relatively simple reactor equipment.

The present embodiment will now be elucidated by means of a non-limiting exemplary embodiment, with reference to the drawing, in which the figure is a schematic representation of an installation for gasifying biomass, cleaning synthesis gas obtained from the biomass and generating electricity.

Gasification reactor 1 has a supply line 2 for biomass to be gasified, such as wood chips, straw or roadside grass, and is, for example, a fluidized bed reactor. The gasification process, which takes place with an under-oxygen supply, produces a flammable gas mixture, so-called synthesis gas, which is fed via a first line 3 to a reactor installation 4. The reactor device 4 contains catalyst material that catalyzes the conversion of tar to synthesis gas. This conversion is endothermic. In the prior art processes, this conversion also results in the formation of carbon. It is known that the formation of carbon can be prevented by carrying out the conversion reaction at a temperature higher than usual (approx. 950 instead of 800 ° C). However, this greatly reduces the efficiency of the gasification process for generating electricity. In the process according to the invention, the conversion takes place at a temperature of 800-1200 ° C, preferably 900-1000 ° C. Cheap catalysts are available for this preferred temperature range, for example those based on dolomite, which are insufficiently active at lower temperatures. These inexpensive catalysts can be used efficiently with the process according to the invention, which is advantageous from a cost viewpoint.

The application of heat to a hot material is, as is well known, not very efficient. According to the invention, heat is not supplied by heating the reactor wall or by means for transferring heat provided in the reactor device, but by reaction of an agent which reacts with a component of the gas mixture. It is thus expedient to heat that part of the reactor device 4 where the desired conversion of a component of the gaseous mixture takes place. In addition, a relatively simple reactor design suffices in the process according to the invention, which is advantageous from a cost point of view.

For converting tar into a tar-containing gas mixture, a limited amount of oxygen, for example in the form of air, can advantageously be supplied as the agent to the reactor device 4. The supplied oxygen reacts with combustible components from the gaseous mixture to produce heat. Thus, the reactor device 4 can be operated efficiently at a high temperature. The oxygen 15 is supplied in an amount sufficient for the endothermic conversion to proceed. So the higher the proportion of tar, the more oxygen is supplied. To compensate for unavoidable heat losses via the wall of the reactor device 4 and via the discharge of catalytically treated gas mixture, to compensate for this, more oxygen can be supplied, resulting in the combustion of more flammable components of the gas mixture, so that the temperature of the reactor device 4 is maintained.

In order to limit heat losses by heat dissipation via a catalytically treated gas mixture, a reactor device is preferably used in which heat energy from the catalytically treated gas mixture is transferred to the gaseous mixture which is yet to be catalytically treated. In the shown embodiment, the device is provided for this purpose with a first heat exchanger part 5 and a second heat exchanger part 6, the catalyst material 7 being located between the two heat exchanger parts 5, 6. In the embodiment described here, the gaseous mixture to be treated catalytically is supplied alternately to the first and second heat exchanger parts 5, 6 and discharged via the second and first heat exchanger parts 6, 5, respectively, using a first valve 8 and a second valve 9. In the position of valves 8 and 9 shown in the figure, gaseous mixture which is to be treated catalytically still passes through the first heat exchanger part 5, whereby the gas mixture absorbs heat and then continues to heat. heated. It passes through the catalyst portion 7 whereby the catalyzed conversion reaction from tar to synthesis gas occurs. Thereafter, it releases heat in the second heat exchanger part 6. The supply of gas mixture to be treated catalytically is changed by controlling valve 8 to the second heat exchanger part 6, as soon as its temperature becomes so high that heat losses via the discharge of catalytically treated gas are considered too great. Likewise, the supply to the second heat exchanger part 6 is changed to the first heat exchanger part 5 as soon as the heat losses through discharge via this heat exchanger part 5 are considered too great. Preferably, the first heat exchanger part 5, the catalyst part 7 and the second heat exchanger part 6, as shown in the figure, are integrated in a reactor vessel 15. The material of the heat exchanger 5 is, for example, an inert, high-temperature resistant material, for example in the form of a packed bed, with good heat-absorbing and heat-releasing properties. Although this will not always be beneficial for cost reasons, the material may also be a catalyst material.

Such a method and apparatus for this have been known in the art for quite some time, for instance for removing small traces of flammable compounds from air. However, it has not been described that an elevated temperature reactor apparatus 25 can be operated to perform an endothermic reaction primarily by using an exothermic reaction conducted in the reactor apparatus to provide heat for the primary reaction to be carried out.

In particular, the method has not been proposed for solving the time-old problem of removing tar from tar-containing gas mixtures such as those from coal and biomass gasification. In particular, the method according to the invention is suitable for the catalytic treatment of gas mixtures from the gasification of dry vegetable material, such as in particular wood chips, straw and roadside grass.

Gas mixture subjected to catalytic treatment is fed via a second conduit 10 to a gas turbine 11, which drives a generator. Hot combustion gas from the gas turbine 11 can, as is known, be used for generating even more electricity with a steam turbine.

The introduction of the agent can be effected before mixing in a heat exchanger part 5, 6 by mixing with the gas mixture, but advantageously this takes place in the catalyst part 7, thereby ensuring that the heat generated by reaction of the agent is released there. with a component of the gas. The insertion takes place, for example, using a perforated tube, for example a ceramic tube.

The process of the invention can also be used to perform other endothermic conversions, such as those from ammonia to N2 and H2. Combustion of ammonia leads to the formation of harmful nitrogen oxides rather than the combustion of N2 and H2.

Another application of the process according to the invention is the dehydrogenation of ethane or propane, the heat required for this reaction being supplied by burning part of the ethane or propane.

It will be clear to the skilled person that the method can be carried out in various ways within the scope of the invention. For conversions in which no suitable constituents are present in the gas mixture, in addition to the agent, such as oxygen, a further agent for reaction therewith, such as a fuel, for example methane, can be added. The reaction of the agent with the further agent then provides the heat necessary for the desired conversion reaction to proceed. The component and the further component can be the same compound. The temperature at which the conversion reaction is carried out is, of course, dependent on the desired conversion, the catalyst used, etc. The agent fed to the reactor apparatus may also be an agent which decomposes into the catalyst portion to yield heat.

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Claims (15)

1. A method for catalytically converting a component of a gaseous mixture, wherein the gaseous mixture is fed to a reactor device containing catalyst material and a gas mixture treated at an elevated temperature is discharged, characterized in that the conversion of the component is endothermic and a medium is fed to the reactor apparatus which undergoes a reaction to provide heat in an amount necessary for the endothermic conversion to proceed. 2. Process according to claim 1, characterized in that the gaseous mixture is a flammable gas mixture, and oxygen is used as the medium supplied to the reactor device. 3. Process according to claim 1 or 2, characterized in that a tar-containing gas mixture is used as the gas mixture fed to the reactor device. A method according to claim 3, characterized in that the tar-containing gas mixture is prepared by gasifying substantially dry vegetable material. 5. Process according to claim 3 or 4, characterized in that the conversion is carried out at a temperature of 800-1200 ° C. A method according to any one of the preceding claims, characterized in that a reactor device (4) is used with a first heat exchanger part (5), a catalyst part (7) and a second heat exchanger part (6), wherein the gaseous mixture is added to the first heat exchanger part (5) is supplied, heat is transferred from the first heat exchanger part (5) to the gaseous mixture, the gaseous mixture thus heated in the catalyst part (7) is treated catalytically, and the catalytically treated gaseous mixture by the second heat exchanger part (6) is passed and heat from the catalytically treated gaseous mixture is transferred to the second heat exchanger part (6). Method according to claim 6, characterized in that the gaseous mixture is supplied alternately to the first and the 1001513 second heat exchanger part (5 and 6, respectively) and is discharged via the second and the first heat exchanger part (6 and 5, respectively) . A method according to claim 7, characterized in that a reactor device (4) is used in which the first heat exchanger part (5), the catalyst part (7) and the second heat exchanger part (6) are integrated in a reactor vessel. Process according to any one of claims 6 to 8, 10, characterized in that the agent fed to the reactor device (4) is introduced into the catalyst part (7). 10. Method for catalytically treating tar-containing, gasifying flammable gas obtained in a reactor, wherein the tar is catalytically converted at elevated temperature, characterized in that a reactor device (4) is used with a first heat exchanger part (5), a catalyst part (7) and a second heat exchanger part (6), in which the catalytically treated gas is supplied to the first heat exchanger part (5), heat is transferred from the first heat exchanger part (5) to the catalytically treated gas, the gas thus heated in the catalyst part (7) is catalytically treated whereby the tar is catalytically converted, and the catalytically treated gas is passed through the second heat exchanger part (6) and heat of the catalytically treated gas on the second heat exchanger part (6) is transferred. Method according to claim 10, characterized in that the catalytically to be treated gas is supplied alternately to the first and the second heat exchanger part (5 and 6, respectively) and via the second and the first heat exchanger part (6 and 5, respectively). ) is disposed of. Method according to claim 11., characterized in that a reactor device (4) is used, wherein the first heat exchanger part (5), the catalyst part (7) and the second heat exchanger part (6) are integrated in a reactor vessel. Process according to any one of claims 10 to 12, characterized in that the catalytic conversion is carried out at a temperature of 800-1200 ° C. 1001513 A method according to any one of claims 10 to 13, characterized in that the combustible gas obtained by gasification is obtained by gasification of wood chips, straw, or roadside grass. Method according to any one of claims 10 to 13, characterized in that the combustible gas obtained by gasification is obtained by gasification of coal, in particular coal or brown coal. 1001513