EP4083258A1 - Method and system for the production of hydrocarbons - Google Patents

Abstract

The invention relates to a method for producing hydrocarbons (6), with the steps: a) carrying out an electrolysis (3) of water, whereby hydrogen and oxygen are produced; b) generating a carbon source comprising carbon dioxide and/or carbon monoxide or consisting essentially of carbon dioxide and/or carbon monoxide; c) Production (5) of the hydrocarbons (6) from the hydrogen produced in step a) and the carbon source produced in step b), wherein at least part of the hydrocarbons produced is present as liquid hydrocarbons and an exhaust gas is also formed in addition to the hydrocarbons (6). containing hydrogen, carbon dioxide and/or carbon monoxide; d) separating the exhaust gas from the liquid hydrocarbons (6); e) performing an exhaust gas utilization (8), in which a reaction of the exhaust gas with the oxygen generated in step a) and/or with water is carried out, whereby utilization products are formed which have carbon dioxide and/or carbon monoxide, water and optionally hydrogen.

Description

The invention relates to a method and a plant for producing hydrocarbons.

Regenerative hydrocarbons are characterized in that they are produced using regenerative starting materials. The regenerative starting materials can include, for example, regenerative carbon dioxide, which is obtained, for example, from biomass, and regenerative hydrogen, which is obtained, for example, by electrolysis of water, in particular using regeneratively generated electricity. The production of the regenerative starting materials and also the conversion of the regenerative starting materials to form the regenerative hydrocarbons are energy-intensive and therefore also cost-intensive. Currently, the costs for the production of regenerative hydrocarbons are several times the production costs of the same hydrocarbons from fossil raw materials.

So far, there have been various routes that enable the production of regenerative hydrocarbons. At this point, only the most important routes, which are the Fischer-Tropsch synthesis, the alcohol-to-fuel routes, the methanol route and the TIGAS process, are briefly presented.

The Fischer-Tropsch synthesis enables the production of various synthetic hydrocarbon fuels, in particular diesel, kerosene, gasoline and LPG. However, this technology has two disadvantages: the first disadvantage is that the products mentioned are produced side by side and only with low selectivity, which entails the need to have to market all the products mentioned at the same time. The desirability of producing a particular product while only producing small amounts of the other products is over this route is practically inaccessible. The second disadvantage of the Fischer-Tropsch synthesis is that carbon monoxide is required as a starting material. Regeneratively obtained carbon dioxide must therefore first be reduced to carbon monoxide, which is only possible using the two immature technologies Reverse Water Gas Shift (RWGS) and Solid Oxide Electrolysis (SOEC). The high temperatures in the range of more than 800 °C associated with RWGS and SOEC place extreme demands on the required materials and catalysts. In addition, under these conditions, relatively rapid coking of the active surfaces is to be expected.

The alcohol-to-fuel routes are based on the production of ethanol by synthesis gas fermentation, in which carbon dioxide and/or carbon monoxide and hydrogen are microbiologically converted into ethanol. The ethanol is then dehydrated to ethylene, which is oligomerized to oligomers. The oligomers are then hydrogenated to the hydrocarbons. In this way, various of the hydrocarbons can be produced with comparatively high selectivities, such as kerosene. In addition to the typically low space-time yield of syngas fermentation, various aspects of the scale-up are viewed critically. This raises the question of whether alcohol-to-fuel routes can play a dominant role on a large industrial scale in the future.

The methanol route, based on the production of methanol from carbon dioxide and hydrogen (CO ₂ + 3 H ₂ ⇄ CH ₃ OH + H ₂ O) and/or from carbon monoxide and hydrogen (CO + 2 H ₂ ⇄ CH ₃ OH) as well based on the further processing of the methanol into hydrocarbons is more selective than the Fischer-Tropsch synthesis, but less selective than the alcohol-to-fuel routes. The scale-up possibilities are assessed positively and the direct usability of regenerative carbon dioxide is another major advantage of this Route. A disadvantage of the prior art is the need to separate off the water of reaction formed in the methanol synthesis carried out with carbon dioxide by an energy-intensive distillation. The methanol dewatered in this way can then be converted into various end products. The methanol-to-kerosene technology is still in the development stage (technical scale). Methanol-to-olefin technologies aimed at the production of ethylene, propylene and butylene have been partially developed to production scale. The best known is the methanol-to-gasoline technology, which has already been applied to the large-scale production of synthetic gasoline. In addition to the main product, petrol, liquid gas and, in small quantities, a C ₁ /C ₂ hydrocarbon mixture are produced.

In figure 1 the process according to the prior art methanol route is shown. A mass flow 78 which has carbon dioxide and/or carbon monoxide and hydrogen or consists of carbon dioxide and/or carbon monoxide and hydrogen is fed to a synthesis of methanol 13 . This creates a mass flow 71 which has methanol, water and unreacted starting materials. Even with very high turnovers of more than 90%, the losses are not accepted. Therefore, a separation 14 of the mass flow 71 is carried out, the water and the methanol being separated from the unreacted starting materials by a condensation in the separation 14 . The unreacted starting materials form a mass flow 72 which is fed back to the synthesis of methanol 13 . The mixture of methanol and water formed in the separation 14 is fed in a mass flow 73 to a distillation 15 in order to separate the methanol from the water. The water can be fed to a waste water treatment 17 in a mass flow 75 . The methanol must be supplied in a mass flow 74 to a condensation 16 (condenser at the top of the distillation column) and in a subsequent mass flow 76 to an evaporation 18, since the subsequent hydrocarbon synthesis 19 takes place in the gas phase. A portion of the condensate 16 formed in the condensation 16 can be returned to the top of the column as a mass flow 79 . In the separation 14 a first cooling 81 has to take place, in the distillation 15 a first heating 82 has to take place, in the condensation 16 a second cooling 83 has to take place and in the evaporation 18 a second heating 84 has to take place. This makes the process energy-intensive and therefore cost-intensive. It is nevertheless necessary to return the unreacted educts in the mass flow 72, which becomes understandable when the high energy consumption in the regenerative production of these educts is taken into account.

An alternative technology to the methanol-to-gasoline technology is the TIGAS process, in which a mixture is produced in the first step that mainly contains methanol, dimethyl ether and water. This mixture is converted directly into gasoline without separating the water. Despite this simplification and various technological and economic advantages, the TIGAS technology is currently not suitable for the production of regenerative hydrocarbons, because similar to the Fischer-Tropsch synthesis, the TIGAS process uses carbon monoxide as a starting material (3 CO + 3 H ₂ -> CH ₃ -O-CH ₃ + CO ₂ ), so that the described problem of the low maturity of the RWGS technology and SOEC technology also comes into play here.

In order to be able to produce the liquid hydrocarbons inexpensively, it is necessary in all processes that the starting materials used are used as completely as possible and/or that as little energy as possible is used in the process.

The object of the invention is therefore to create a method and a plant with which liquid hydrocarbons can be produced inexpensively.

The method according to the invention for producing hydrocarbons comprises the steps of: a) performing an electrolysis of water, whereby hydrogen and oxygen are produced; b) generating a carbon source comprising carbon dioxide and/or carbon monoxide or consisting essentially of carbon dioxide and/or carbon monoxide; c) Production of the hydrocarbons from the hydrogen produced in step a) and the carbon source produced in step b), wherein at least part of the hydrocarbons produced is present as liquid hydrocarbons and, in addition to the hydrocarbons, an exhaust gas is also formed which contains hydrogen, carbon dioxide and/or carbon monoxide and optionally gaseous hydrocarbons; d) separating the exhaust gas from the liquid hydrocarbons; e) performing exhaust gas utilization in which the exhaust gas is reacted with the oxygen produced in step a) and/or with water, whereby utilization products are formed which have carbon dioxide and/or carbon monoxide, water and optionally hydrogen.

Exhaust gas utilization advantageously produces heat, which can also be utilized, for example by converting the heat into electricity, for example by carrying out the reaction in step e) in a gas turbine, and/or by using the heat, for example for evaporation and/or carry out a distillation. Advantageously, by converting or using the heat to electricity, the process for producing the hydrocarbons is inexpensive. Exhaust gas utilization can be carried out by carrying out combustion of the exhaust gas with the oxygen produced in step a), which is particularly rich in energy due to its purity. This has the additional advantage that the oxygen generated in step a) in the electrolysis is also utilized, making the process even cheaper. Alternatively, the Exhaust gas utilization can be carried out by gasification of the exhaust gas is carried out by a reaction with the water. The gasification can be carried out without the addition of oxygen or with the addition of the oxygen produced in step a) in the electrolysis. Here, too, the utilization of the oxygen in the gasification process makes the process particularly cost-effective. By carrying out the reaction in step e) using the oxygen generated in step a) and not using air, it is also advantageously achieved that essentially no undesirable substances, such as nitrogen and/or noble gases, are present at this point in the procedure to be entered.

In order to achieve that part of the hydrocarbons produced is present as the liquid hydrocarbons, cooling of the reaction products produced in step c) can be carried out. The resulting liquid hydrocarbons can be marketed particularly well.

It is preferred that the process has the step: f) separating water from the utilization products. As a result, the recycling products essentially consist of carbon dioxide, carbon monoxide and/or hydrogen. As a result, the recycling products have a higher value than if the water were still contained in the recycling products.

The water separated off in step f) is preferably used in step a) for the electrolysis in order to generate the hydrogen and the oxygen therefrom, and/or used in step e) to carry out the reaction with the exhaust gas. In contrast to fresh water, the water separated off in step f) is already demineralized. Therefore, the amount of fresh water to be fed to the process and to be demineralized beforehand can be reduced, making the process even more cost-effective becomes. In addition, the method is also suitable for being carried out in regions in which only few fresh water resources are available.

It is preferred that in step c) the hydrocarbons are also produced from the utilization products generated in step e). Advantageously, this means that little or no carbon is lost from the process, making the process even more cost-effective. It is particularly preferred here to separate off the water in step f), because the production of the hydrocarbons is an equilibrium reaction and water contained in the utilization products would reduce the yield of the liquid hydrocarbons in step c).

Heat generated in step e) is preferably supplied partially or completely to an endothermic step or to a plurality of endothermic steps of the process. This can reduce the cost of performing the method. The endothermic step or steps can be, for example, an evaporation and/or a distillation.

It is preferred that the process is carried out continuously. This results in particular in a continuous mass flow of the liquid hydrocarbons, a continuous mass flow of the exhaust gas and a continuous mass flow of the utilization products.

It is preferred that in step c) some of the hydrocarbons produced are present as gaseous hydrocarbons and in step e) the reaction is also carried out with at least some of the gaseous hydrocarbons produced in step c). This advantageously produces more heat in step e) than if the reaction was only with the carbon dioxide and/or the Carbon monoxide and hydrogen is carried out. This is particularly relevant when not enough heat is released in step e) to sustain endothermic processes of the process. It is particularly preferred that the reaction is gasification.

It is preferred that in step c) the part of the gaseous hydrocarbons is formed as part of the exhaust gas and/or the part of the gaseous hydrocarbons is separated from the liquid hydrocarbons by distillation and then mixed with the exhaust gas.

The gaseous hydrocarbons particularly preferably contain C ₁ hydrocarbon, C ₂ hydrocarbon, C ₃ hydrocarbon and/or C ₄ hydrocarbon or consist particularly essentially of C ₁ hydrocarbon, C ₂ hydrocarbon, C ₃ hydrocarbon and /or C ₄ hydrocarbon. These hydrocarbons usually have a lower commercial value than the hydrocarbons that have longer chains. The C ₁ carbon and the C ₂ carbon may be contained in the exhaust gas. It is conceivable that the C ₁ hydrocarbon, the C ₂ hydrocarbon, the C ₃ hydrocarbon and/or the C ₄ hydrocarbon are at least partially dissolved in the liquid hydrocarbons. It is conceivable that the C ₁ hydrocarbon and the C ₂ hydrocarbon are separated off in a first distillation column and then at least partially mixed with the exhaust gas. It is also conceivable that the C ₃ hydrocarbon and the C ₄ hydrocarbon are separated off in a second distillation column and then at least partially mixed with the exhaust gas.

Water is also formed in step c) and the process preferably comprises the step: g) separating the water from the exhaust gas and the hydrocarbons. This can be done, for example, by condensing the water and separating the phases from the liquid hydrocarbons take place. It is particularly preferred that the water separated off in step g) is used in step a) for the electrolysis in order to generate the hydrogen and the oxygen therefrom, and/or is used in step e) to carry out the reaction with the exhaust gas . In contrast to fresh water, the water separated off in step g) is already demineralized. Therefore, the amount of fresh water to be fed to the process and to be demineralized beforehand can be reduced, making the process even more cost-effective. In addition, the method is also suitable for being carried out in regions in which only few fresh water resources are available. If the water separated off in step g) is used in step e) to carry out the reaction with the exhaust gas, there is also the advantage that any hydrocarbons dissolved in the water are also gasified.

In step b), carbon dioxide is preferably extracted from air, biomass is burned, biomass is gasified and/or combustion exhaust gases are generated. Methods for extracting carbon dioxide from the air are known by the term "direct air capture" (DAC). For example, the carbon dioxide is extracted from the air by adsorption or by a reaction with sodium hydroxide or potassium hydroxide before it is usually desorbed again by supplying energy and is thereby made available for subsequent processes. By extracting the carbon dioxide from the air or from the biomass, the hydrocarbons can advantageously be obtained regeneratively, ie without using fossil carbon sources. Alternatively, it is conceivable that the combustion exhaust gases from an unavoidable combustion process are used. If the carbon dioxide is extracted from the air, this has the advantage that essentially no undesired substances, such as nitrogen and/or noble gases, enter the process.

It is preferred that the biomass is burned or gasified using the oxygen generated in step a). This advantageously ensures that essentially no undesired substances, such as nitrogen and/or noble gases, get into the process.

It is preferred that in step c) methanol is produced in a first process stage in an equilibrium reaction and the methanol, the hydrogen that has not reacted in the equilibrium reaction and the carbon source that has not reacted in the equilibrium reaction are fed to a second process stage in which the hydrocarbons are be produced from the methanol. Compared to the prior art method (see figure 1 ) the unreacted hydrogen and the unreacted carbon source are not recycled to the synthesis of methanol (see mass flow 72). This eliminates the energy-intensive separation of the methanol, making the process particularly cost-effective. This is made possible by the fact that the unreacted hydrogen and the unreacted carbon source are converted into the recycling products after the second process stage in the waste gas utilization in step e).

It is particularly preferred that the equilibrium reaction of the first stage of the process produces water which is not separated from the methanol, the hydrogen which has not reacted in the equilibrium reaction and the carbon source which has not reacted in the equilibrium reaction. This also makes the method particularly cost-effective. The water formed in the equilibrium reaction of the first stage of the process can be removed in step g).

The hydrocarbons preferably include saturated hydrocarbons and/or olefins or preferably consist of saturated hydrocarbons and/or olefins. For the liquid hydrocarbons, in particular the saturated hydrocarbons, it can be, for example, gasoline, kerosene, diesel and/or liquid gas.

The specific reaction conditions in step c) for producing the hydrocarbons depend, for example, on which hydrocarbons are produced. For example, in the production of gasoline, the pressure can be from 20 bar to 30 bar, the temperature can be from 200°C to 400°C, in particular from 250°C to 400°C, and a heterogeneous catalyst can be present, such as for example a zeolite catalyst, in particular a ZSM-5 catalyst.

The system according to the invention is set up to carry out the method according to the invention or a preferred embodiment thereof.

• Figur 1 ein Ablaufdiagramm eines herkömmlichen Verfahrens,
• Figur 2 ein Ablaufdiagramm des erfindungsgemäßen Verfahrens,
• Figur 3 ein Ablaufdiagramm einer bevorzugten Ausführungsform des erfindungsgemäßen Verfahrens.

The invention is explained in more detail below with reference to the accompanying schematic drawings. Show it

• figure 1 a flowchart of a conventional method,
• figure 2 a flowchart of the method according to the invention,
• figure 3 a flow chart of a preferred embodiment of the method according to the invention.

like it out figure 2 As can be seen, a process for producing hydrocarbons comprises the steps of: a) performing an electrolysis 3 of water, whereby hydrogen and oxygen are produced; b) generating a carbon source 4 comprising carbon dioxide and/or carbon monoxide or consisting essentially of carbon dioxide and/or carbon monoxide; c) Manufacture 5 of the hydrocarbons from the hydrogen produced in step a) and the carbon source produced in step b), wherein at least a part of the produced hydrocarbons are present as liquid hydrocarbons 6 and, in addition to the hydrocarbons 6, an exhaust gas is also formed which has hydrogen, carbon dioxide and/or carbon monoxide; d) separating the exhaust gas from the liquid hydrocarbons 6; e) performing an exhaust gas utilization 8 in which a reaction of the exhaust gas with the oxygen generated in step a) and/or with water is carried out, whereby utilization products are formed which have carbon dioxide and/or carbon monoxide, water and optionally hydrogen.

The waste gas utilization can be carried out, for example, by burning the waste gas with the oxygen produced in step a). In another example, the exhaust gas utilization can be performed by performing gasification of the exhaust gas through a reaction with the water. The gasification can be carried out without the addition of oxygen or with the addition of the oxygen produced in step a) in the electrolysis.

figure 2 shows that fresh water 1 can be supplied to electrolysis 3 in a mass flow 51 . The hydrogen produced in step a) can be fed in a mass flow 53 to a reactor in which the hydrocarbons 6 are produced in step c). The oxygen generated in step a) can be conducted in a mass flow 55 that is separate from the mass flow 53, so that the hydrogen and the oxygen cannot be mixed.

In order to provide the carbon source in step b), a carbon-containing starting material 2 can be provided in a mass flow 52 . The carbon source can be produced from the mass flow 52 and can be fed to the reactor in a mass flow 54 . For example, carbon dioxide can be extracted from air in step b), so that the carbonaceous starting material 2 is the air. In step b) biomass can be burned and / or gasified, whereby the carbonaceous Starting material 2 is the biomass. If the biomass is burned, mainly carbon dioxide will be produced, if the biomass is gasified, mainly carbon monoxide will be produced. It is conceivable that the biomass is burned or gasified using the oxygen generated in step a). This has the advantage that no nitrogen or noble gases get into the process. For this purpose, the oxygen generated in step a) can be provided partially or completely in a mass flow 70 which is conducted separately from the mass flow 53, so that the oxygen cannot mix with the hydrogen. In another example, combustion exhaust gases can be generated, in particular by gasification and/or combustion of fossil fuels as the carbonaceous feedstock.

The hydrocarbons can be produced in step c) at a temperature in the reactor of at least 200° C., in particular from 250° C. to 400° C. The pressure may be from 20 bar to 30 bar and a heterogeneous catalyst may be present, such as a zeolite catalyst, especially a ZSM-5 catalyst.

• Wasserstoff,
• Kohlenstoffdioxid und/oder Kohlenstoffmonoxid,
• optional gasförmige Kohlenwasserstoffe, insbesondere C₁-Kohlenwasserstoff, C₂-Kohlenwasserstoff, C₃-Kohlenwasserstoff und/oder C₄-Kohlenwasserstoff,
  aufweisen oder im Wesentlichen aus
• Wasserstoff,
• Kohlenstoffdioxid und/oder Kohlenstoffmonoxid,
• optional gasförmigen Kohlenwasserstoffen, insbesondere C₁-Kohlenwasserstoff, C₂-Kohlenwasserstoff, C₃-Kohlenwasserstoff und/oder C₄-Kohlenwasserstoff,
  bestehen. In dem Fall, dass in Schritt c) auch Wasser gebildet wird, kann dazu das Verfahren den Schritt aufweisen:
  • g) Abtrennen des Wassers 7 von dem Abgas und den flüssigen Kohlenwasserstoffen 6. Dadurch entsteht ein im Wesentlichen reiner Massenstrom 56 der flüssigen Kohlenwasserstoffe 6. Das Abtrennen des Wassers 7 von dem Abgas kann durch eine Kondensation und eine Phasenabscheidung des Wassers 7 erfolgen. Das in Schritt g) abgetrennte Wasser 7 kann einen Massenstrom 57 bilden und beispielsweise zumindest teilweise in Schritt a) für die Elektrolyse 3 verwendet wird, um daraus den Wasserstoff und den Sauerstoff zu erzeugen. Alternativ ist denkbar, dass das Wasser 7 in einer Kläranlage gereinigt und abgelassen wird.

The exhaust gas separated off in step d) can be provided in a mass flow 58 and

• Hydrogen,
• carbon dioxide and/or carbon monoxide,
• optionally gaseous hydrocarbons, in particular C ₁ hydrocarbon, C ₂ hydrocarbon, C ₃ hydrocarbon and/or C ₄ hydrocarbon,
  have or essentially
• Hydrogen,
• carbon dioxide and/or carbon monoxide,
• optionally gaseous hydrocarbons, in particular C ₁ hydrocarbon, C ₂ hydrocarbon, C ₃ hydrocarbon and/or C ₄ hydrocarbon,
  exist. In the event that water is also formed in step c), the method can have the following step:
  • g) separating the water 7 from the exhaust gas and the liquid hydrocarbons 6. This results in a substantially pure mass flow 56 of the liquid hydrocarbons 6. The water 7 can be separated from the exhaust gas by condensation and phase separation of the water 7. The water 7 separated off in step g) can form a mass flow 57 and can be used, for example, at least partially in step a) for the electrolysis 3 in order to produce the hydrogen and the oxygen therefrom. Alternatively, it is conceivable that the water 7 is cleaned and drained in a sewage treatment plant.

In the event that in step e) the combustion or the gasification is carried out with the oxygen generated in step a), the mass flow 55 can be mixed with the mass flow 58 in order to carry out the exhaust gas utilization 8 . If the gasification is carried out in step e), the water 7 separated in step g) can be used at least partially in step e) to carry out the reaction with the exhaust gas, compare the mass flows 67 and 65. Alternatively or additionally For this purpose, the gasification in step e) can be carried out using another fresh water 11, compare the mass flows 66 and 65.

After step e), a mass flow 59 is produced which has carbon dioxide, carbon monoxide, hydrogen and/or water and/or essentially consists of carbon dioxide, carbon monoxide, hydrogen and/or water. If the combustion is carried out in step e), the carbon contained in the exhaust gas is essentially converted to carbon dioxide. If the gasification is carried out in step e), the proportion of carbon monoxide in the mass flow 59 will be higher than the proportion of carbon dioxide. figure 2 also shows that the method can have the step: f) separating 9 water 12 from the utilization products. The separation of the water 12 can be done by condensing the Water 12 done. This creates a mass flow 63 which is formed by the water 12 separated off in step f). The water 12 separated in step f) can be used in step a) for the electrolysis 3 (compare mass flow 69) in order to generate the hydrogen and oxygen from it, and/or in step e) used to react with the perform exhaust gas. The portion of the mass flow 63 not used in the mass flow 69 can form a mass flow 64 . As an alternative to using the water 12 separated in step f), the water 12 can also be cleaned and drained in a sewage treatment plant.

figure 2 shows that in step c) the hydrocarbons can also be produced from the utilization products produced in step e). For this purpose, a mass flow 60 which has carbon dioxide, carbon monoxide and/or hydrogen or consists essentially of carbon dioxide, carbon monoxide and/or hydrogen can be conducted downstream of the separation 9 of the water 12 in the direction of the reactor. Optionally, part of the mass flow 60 can be discharged in a mass flow 61 as a residual waste gas 10 in order to discharge any by-products that may occur and thus to prevent their accumulation in the process. A mass flow 62, which is formed by the mass flow 60 optionally minus the mass flow 61, is then fed to the reactor.

The process can be carried out continuously. This means, for example, that the mass flows 53, 54 and 58 in particular are continuous.

Heat generated in step e) is preferably supplied partially or completely to an endothermic step or to a plurality of endothermic steps of the process, such as evaporation and/or distillation.

It is also conceivable that in step c) a part of the hydrocarbons produced as gaseous Hydrocarbons are present and in step e) the reaction is also carried out with at least part of the gaseous hydrocarbons 6 produced in step c). In step c), part of the gaseous hydrocarbons can be formed as part of the exhaust gas (this would mean that in figure 2 already at the start of mass flow 58, which contains the part of the gaseous hydrocarbons) and/or the part of the gaseous hydrocarbons can be separated from the liquid hydrocarbons 6 as a mass flow 68 by distillation and then mixed with the exhaust gas, i.e. added to mass flow 58. The gaseous hydrocarbons can have C ₁ hydrocarbon, C ₂ hydrocarbon, C ₃ hydrocarbon and/or C ₄ hydrocarbon or consist essentially of C ₁ hydrocarbon, C ₂ hydrocarbon, C ₃ hydrocarbon and/or C ₄ - hydrocarbon exist. The C ₁ hydrocarbon and the C ₂ hydrocarbon are preferably present at the beginning of the mass flow 58 and the C ₃ hydrocarbon and the C ₄ hydrocarbon are preferably present in the mass flow 68 and are admixed to the mass flow 58 after its beginning.

like it out figure 3 As can be seen, methanol can be produced in step c) in a first process stage in an equilibrium reaction 13 and the methanol, the hydrogen which has not reacted in the equilibrium reaction and the carbon source which has not reacted in the equilibrium reaction can be fed to a second process stage in which the hydrocarbons from the methanol are produced. In order to produce the methanol 13, a mass flow 78 can be provided which has hydrogen and has carbon monoxide and/or carbon dioxide or which consists essentially of hydrogen and consists of carbon monoxide and/or carbon dioxide. In the first stage of the process, the reaction conditions can have, for example: a temperature of 200° C. to 300° C., a pressure of at least 50 bar, in particular of 50 bar to 250 bar and a metal oxide catalyst may be present.

The fact that the methanol is produced 13 results in a mass flow 71 which has methanol and hydrogen, as well as carbon monoxide and/or carbon dioxide and optionally water. The mass flow 71 is fed to a preparation 19 of the hydrocarbons with methanol as starting material, ie fed to the second process stage, without any of the aforementioned substances being separated off. For example, in the second stage of the process, the pressure can be from 20 bar to 30 bar, the temperature can be from 200° C. to 400° C., in particular from 250° C. to 400° C., and a heterogeneous catalyst can be present, such as, for example a zeolite catalyst, especially a ZSM-5 catalyst. Steps d) and e) are analogous to in figure 1 carried out. The exhaust gas can also contain C ₁ to C ₄ hydrocarbons.

It is conceivable that in the equilibrium reaction of the first process stage, water is formed (if the methanol is produced with carbon dioxide as the starting material), which is fed to the second process stage. The water is only separated off in step d).

In the event that the hydrocarbons have C ₁ hydrocarbon, C ₂ hydrocarbon, C ₃ hydrocarbon and/or C ₄ hydrocarbon, the C ₁ hydrocarbon, the C ₂ hydrocarbon, the C ₃ hydrocarbon and/or or the C ₄ -hydrocarbon can be recycled particularly easily, for example, if the process is carried out at a location where there is also a refinery. The C ₁ hydrocarbon, the C ₂ hydrocarbon, the C ₃ hydrocarbon and/or the C ₄ hydrocarbon can be used as starting material in the refinery. For example, the refinery can be a steam cracker. In the steam cracker ethylene can be produced which has a high commercial value.

The heat generated in step e) can also be marketed if the process is carried out at a location where other plants of the chemical or pharmaceutical industry are also located. The heat generated in step e) can be used, for example, to carry out an endothermic process, such as evaporation or distillation, in the other plants.

A system is set up to carry out the method.

Claims (15)

Process for producing hydrocarbons (6), comprising the steps of: a) performing an electrolysis (3) of water, whereby hydrogen and oxygen are produced; b) generating a carbon source (4) comprising carbon dioxide and/or carbon monoxide or consisting essentially of carbon dioxide and/or carbon monoxide; c) Production (5) of the hydrocarbons (6) from the hydrogen produced in step a) and the carbon source produced in step b), wherein at least some of the hydrocarbons produced are present as liquid hydrocarbons and an exhaust gas is also formed in addition to the hydrocarbons (6). containing hydrogen, carbon dioxide and/or carbon monoxide; d) separating the exhaust gas from the liquid hydrocarbons (6); e) performing an exhaust gas utilization (8), in which a reaction of the exhaust gas with the oxygen produced in step a) and/or with water is carried out, whereby utilization products are formed which have carbon dioxide and/or carbon monoxide, water and optionally hydrogen. A method according to claim 1, comprising the step of: f) separating (9) water (12) from the utilization products. Process according to claim 2, wherein the water (12) separated in step f) is used in step a) for the electrolysis (3) in order to produce the hydrogen and the oxygen therefrom and/or in step e) is used to carry out the reaction with the exhaust gas. Process according to one of claims 1 to 3, wherein in step c) the hydrocarbons (6) are also produced from the utilization products produced in step e). Process according to any one of claims 1 to 4, wherein the process is carried out continuously. Process according to any one of claims 1 to 5, wherein in step c) a portion of the hydrocarbons produced is present as gaseous hydrocarbons and in step e) the reaction is also carried out with at least a portion of the gaseous hydrocarbons produced in step c). Process according to claim 6, wherein in step c) the part of the gaseous hydrocarbons is formed as part of the exhaust gas and/or the part of the gaseous hydrocarbons is separated from the liquid hydrocarbons (6) by distillation and is then admixed with the exhaust gas. A process according to claim 6 or 7, wherein the portion comprises C ₁ hydrocarbyl, C ₂ hydrocarbyl, C ₃ hydrocarbyl and/or C ₄ hydrocarbyl or consists essentially of C ₁ hydrocarbyl, C ₂ hydrocarbyl, C ₃ hydrocarbyl and/or C ₄ hydrocarbon. Process according to any one of claims 1 to 8, wherein in step c) water is also formed and the process comprises the step: g) separating the water (7) from the exhaust gas and the hydrocarbons (6). Process according to claim 9, wherein the water (7) separated in step g) is used in step a) for the electrolysis (3) in order to produce the hydrogen and the oxygen therefrom and/or in step e) is used to carry out the reaction with the exhaust gas. Method according to one of claims 1 to 10, wherein in step b) carbon dioxide is extracted from air, biomass is burned, biomass is gasified and/or combustion exhaust gases are generated. Method according to claim 11, wherein the biomass is burned or gasified by means of the oxygen generated in step a). The method according to any one of claims 1 to 12, wherein in step c) in a first process stage in an equilibrium reaction, methanol is produced (13) and the methanol, the unreacted hydrogen in the equilibrium reaction and the carbon source unreacted in the equilibrium reaction are fed to a second process stage are, in which the hydrocarbons (6) are produced from the methanol. Process according to Claim 13, in which water is formed in the equilibrium reaction and is fed to the second process stage. Plant set up to carry out a method according to one of Claims 1 to 14.

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