EP4466219A1 - Ammonia synthesis and urea synthesis with reduced co2 footprint - Google Patents

Abstract

The present invention relates to a system for the synthesis of ammonia, wherein the system comprises at least one reformer for converting a hydrocarbon to hydrogen, wherein the system comprises a converter (50) for converting hydrogen and nitrogen to ammonia, wherein the converter (50) is integrated in a recirculatory system (100), wherein a first carbon dioxide separator (40) is located between the reformer and the recirculatory system (100), and the recirculatory system (100) comprises an ammonia separator (70).

Description

Ammonia synthesis and urea synthesis with reduced carbon footprint

The invention relates to a system network and a method for generating ammonia from a combination of hydrogen from natural gas and from electrolysis using renewable energies and simultaneous use of the carbon dioxide in the urea synthesis and / or the nitrogen in the ammonia synthesis, which arise when generating the hydrogen from natural gas.

Steam reforming, in particular, is used to produce hydrogen, in which a hydrocarbon is reacted with steam to form carbon monoxide and hydrogen and then the carbon monoxide is reacted in a water-gas shift reaction to form carbon dioxide and hydrogen. For this purpose, energy must be provided from the outside for this endothermic reaction, which takes place, for example, by burning hydrocarbons in an adjacent combustion chamber. Alternatively, autothermal reforming is used, in which partial oxidation takes place and thus provides the required energy.

Methane is usually reacted with water and air in the primary and secondary reformer to form carbon dioxide and hydrogen, with the target composition of 3:1 of hydrogen to nitrogen usually being set. This usually takes place in steps, with methane first being reacted with water in a primary reformer with the supply of energy and then in a secondary reformer with supply of oxygen, usually in the form of air, and a subsequent shift reaction to convert carbon monoxide with water to form carbon dioxide and hydrogen. Thus, after the carbon dioxide has been removed and any carbon monoxide present has usually been converted into methane, this mixture can be converted directly in a converter into ammonia.

After synthesis, the ammonia is often reacted directly with carbon dioxide to form urea. The carbon dioxide from the reformer, i.e. from the process for producing the hydrogen, is often used for this. WO 2019/110 443 A1 discloses a method for providing CO2 for urea synthesis from flue gas and synthesis gas.

A process for providing carbon dioxide for the synthesis of urea is known from EP 3 390 354 B1.

It is also known to generate hydrogen by means of electrolysis from, in particular, renewable energy sources and thus CO2-free. There is therefore of course an interest in using this so-called "green" hydrogen for the synthesis of ammonia, in order to obtain so-called "green" ammonia. Since no nitrogen is produced in the production of hydrogen, this is usually obtained from air separation, which is an energy-intensive process.

In order to operate the process within the primary reformer, a primary reformer has a burner side in which a fuel gas, usually natural gas, is burned with air and thus provides the necessary thermal energy. The flue gas exiting the burner side consists mainly of nitrogen and carbon dioxide, two substances that can actually be used within the system, but are usually released directly into the environment.

The object of the invention is to at least partially use the flue gas generated on the burner side of the primary reformer within the process and thus save energy in the overall process and/or reduce emissions.

This object is achieved by the systems with the features specified in claim 1 and by the method with the features specified in claim 15 and claim 16 . Advantageous developments result from the dependent claims, the following description and the drawings.

The plant is used for the synthesis of ammonia and optionally for the further synthesis of urea from the ammonia produced. Such combined plants for the production of nitrogenous fertilizer are known and customary. These plants can also have other components, for example a nitric acid plant Production of nitric acid from ammonia and in particular a subsequent device for the production of ammonium nitrate as a fertilizer from ammonia and nitric acid. The plant has at least one reformer for converting a hydrocarbon into hydrogen. The plant usually has a reformer. For example, the reformer has a primary reformer and a secondary reformer for converting a hydrocarbon into hydrogen, in particular steam reforming is used here, in which methane in particular is converted with steam in a first step and with air in a second step, with a downstream water-gas shift reaction usually taking place in which carbon monoxide produced is converted with steam to form carbon dioxide and hydrogen. Alternatively, the reformer can be an autothermal reformer in which hydrocarbon, water vapor and oxygen are brought together in such a way that the energy required for conversion to hydrogen is produced directly from the combustion. In contrast to steam reforming, no energy has to be supplied from outside. The plant also has a converter for converting hydrogen and nitrogen into ammonia. The converter has a catalyst and is operated at high pressure and high temperature. Since the conversion is an equilibrium reaction, which does not show almost complete conversion, the synthesis gas is fed into a recirculation circuit in order to be able to feed unreacted educts back into the converter. The process is known as the Haber-Bosch process. The converter is accordingly in a

integrated recirculation cycle. Between the reformer and the

A first carbon dioxide separator is arranged in the recirculation circuit. Here the carbon dioxide produced from the starting material, in particular methane, is separated off, for example and in particular in order to then feed this to a urea synthesis device. Thus, after the first carbon dioxide separator, a gas stream with nitrogen and hydrogen in a ratio of 1:3 and without other components (possibly apart from traces) is made available for the ammonia synthesis. A methanator, a device for converting any traces of carbon monoxide and carbon dioxide that may be present into methane, is usually present between the first carbon dioxide separator and the recirculation circuit in order to prevent poisoning of the catalyst. The recirculation circuit has an ammonia separator. Here the product becomes ammonia from the unreacted Educt stream separated from nitrogen and hydrogen. Furthermore, the recirculation circuit usually has heat exchangers between the converter and the ammonia separator for cooling and between the ammonia separator and the converter for heating. Furthermore, the recirculation circuit usually has a compressor.

According to the invention, the plant has a further hydrogen source. The further hydrogen source is preferably water electrolysis. Water electrolysis is preferably operated using renewable energies. The hydrogen produced in this way is therefore free of carbon dioxide emissions and is therefore considered so-called “green” hydrogen. The further hydrogen source is connected to the recirculation circuit in such a way that hydrogen is supplied to the recirculation circuit. For this purpose, the hydrogen is preferably first mixed with nitrogen and then compressed by one or more compressors. The plant has a combustion device. For example, the combustor may be the burner side of a primary reformer. Alternatively, the combustion device may be a steam generating device. A steam generating device is operated, for example, to operate the compressors. Likewise, the exhaust gases from two or more combustors can also be combined if a larger gas flow is desired. The combustion device, for example the burner side of the primary reformer, is connected to a second carbon dioxide separator. The second carbon dioxide separator is connected to the recirculation loop in such a way that nitrogen is supplied to the recirculation loop. The hydrogen from the further hydrogen source and the nitrogen from the second carbon dioxide separator are preferably first combined and compressed together using one or more compressors. The advantage is that through combustion on the burner side, nitrogen can be provided comparatively easily in further process steps by separating carbon dioxide, and the ratio of hydrogen to nitrogen can be adjusted to 3:1 without energy-intensive air separation.

In a further embodiment of the invention, the reformer has a primary reformer and a secondary reformer for converting a hydrocarbon in hydrogen. The primary reformer has a hydrogen side and a burner side. On the hydrogen side, hydrocarbons are reacted with water vapor to form carbon monoxide or carbon dioxide and hydrogen. The energy required for this is provided by combustion, in particular of hydrocarbons, with oxygen, in particular with air. The burner side is the combustion device in which hydrocarbon is burned with air in the burner side of the primary reformer. The burner side of the primary reformer is connected to a second carbon dioxide separator.

In another embodiment of the invention, the combustion device is a steam generating device.

In a further embodiment of the invention, the reformer is an autothermal reformer.

In a further embodiment of the invention, the plant also has a urea synthesis device for synthesizing urea from ammonia and carbon dioxide. The first carbon dioxide separator is connected to the urea synthesizer for the separated carbon dioxide. Usually, the amount of carbon dioxide separated is slightly less than the amount of ammonia generated from the nitrogen and hydrogen, so that the ammonia is not completely converted into urea. The ammonia trap leading to ammonia is connected to the urea synthesizer. In this case, an intermediate store can also be arranged in the ammonia-carrying connection.

In a further embodiment of the invention, the second carbon dioxide separator is an ammonia water scrubber. Such scrubbers are known, for example, from WO 2019/110 443 A1 or EP 3 390 354 B1.

In a further embodiment of the invention, the nitrogen from the second carbon dioxide separator is fed to the recirculation circuit in that the nitrogen from the second carbon dioxide separator is introduced into the secondary reformer. As a result, any residual oxygen that is still present is converted in the secondary reformer. In this case, not all of the nitrogen stream has to be transferred to the secondary reformer. Rather, this flow can be adjusted to the amount of additional hydrogen.

In a further embodiment of the invention, a device for removing oxygen is arranged between the second carbon dioxide separator and the recirculation circuit. An additional compressor is then preferably provided in order to achieve an adjustment of the pressure to the high level of the recirculation circuit.

In a further embodiment of the invention, the burner side of the primary reformer is operated with an excess of oxygen or an excess of methane. This is unusual for actual operation as a burner side, but this ensures that the oxygen is fully consumed.

In a further embodiment of the invention, the second carbon dioxide separator is connected to the recirculation circuit in such a way that nitrogen is fed to the recirculation circuit via the autothermal reformer. This also allows the existing residual oxygen to be reliably converted.

In a further embodiment of the invention, a dedusting device is arranged between the burner side of the primary reformer and the second carbon dioxide separator. A desulfurization device and/or a denitrification device can preferably also be arranged downstream of the dedusting device.

In a further embodiment of the invention, the additional hydrogen source and the second carbon dioxide separator are connected to the recirculation circuit in such a way that the hydrogen stream from the additional hydrogen source is first combined with the nitrogen stream from the second carbon dioxide separator, then passed through a first compressor and then through a methanator and then fed to the recirculation circuit. This allows in particular a simplified increase in capacity of the ammonia synthesis, since the existing Synthesis gas production in the reformer remains unchanged and is thus increased by the additional gas flow directly before the converter.

In a further embodiment of the invention, the combustion device, for example the burner side of the primary reformer, is connected to the secondary reformer. As a result, nitrogen but also carbon dioxide and the rest of the oxygen are supplied to the gas stream for the production of hydrogen. The remaining residual oxygen is converted in the secondary reformer. Since carbon dioxide is separated after the secondary reformer, the carbon dioxide generated on the burner side can then also be separated in the same step.

In a further embodiment of the invention, a dedusting device is arranged between the combustion device, for example and preferably the burner side of the primary reformer, and the reformer, for example and preferably the secondary reformer. A desulfurization device and/or a denitrification device can preferably also be arranged downstream of the dedusting device.

In a further embodiment of the invention, a compressor is arranged between the combustion device, preferably the burner side of the primary reformer, and the reformer, preferably the secondary reformer.

In a further embodiment of the invention, the plant is used for the further synthesis of urea from the ammonia produced. Such combined plants for the production of nitrogenous fertilizer are known and customary. These plants can also have other components, for example a nitric acid plant for the production of nitric acid from ammonia and in particular a subsequent device for the production of ammonium nitrate as a fertilizer from ammonia and nitric acid. The plant also has a urea synthesis device for synthesizing urea from ammonia and carbon dioxide. The ammonia trap leading to ammonia is connected to the urea synthesizer. In this case, an intermediate store can also be arranged in the ammonia-carrying connection. The second Carbon dioxide separator is connected to the urea synthesizer such that carbon dioxide is supplied to the urea synthesizer.

In a further embodiment of the invention, the plant has a further hydrogen source. The further hydrogen source is connected to the recirculation circuit in such a way that hydrogen is supplied to the recirculation circuit. The burner side of the primary reformer is connected to a second carbon dioxide separator. The second carbon dioxide separator is connected to the recirculation loop in such a way that nitrogen is supplied to the recirculation loop. The burner side of the primary reformer is connected to the secondary reformer.

In a further embodiment of the invention, the plant has a further hydrogen source. The further hydrogen source is connected to the recirculation circuit in such a way that hydrogen is supplied to the recirculation circuit. The burner side of the primary reformer is connected to a second carbon dioxide separator. The second carbon dioxide separator is connected to the recirculation loop in such a way that nitrogen is supplied to the recirculation loop. Further, the second carbon dioxide separator is connected to the urea synthesizing device such that carbon dioxide is supplied to the urea synthesizing device. In this way, an optimal use of all gas flows can be achieved. A ratio of nitrogen to hydrogen to carbon dioxide of, for example, 2:6:1 can be achieved by the additional, in particular “green” hydrogen produced.

In a further embodiment of the invention, the plant has a further hydrogen source. The further hydrogen source is connected to the recirculation circuit in such a way that hydrogen is supplied to the recirculation circuit. The burner side of the primary reformer is connected to the secondary reformer. The burner side of the primary reformer is further connected to a second carbon dioxide separator, and the second carbon dioxide separator is connected to the urea synthesizer such that carbon dioxide of the

Urea synthesis device is supplied. In this case, all gas flows must always be routed completely according to the wiring. For example, in the various embodiments, partial streams, in particular the exhaust gas on the burner side, the nitrogen stream or the carbon dioxide stream of the second carbon dioxide separator, can also be separated and discarded or used in some other way.

In a further aspect, the invention relates to a method for expanding the capacity of an existing plant according to the prior art. The plant will be expanded to include a further hydrogen source. Water electrolysis is preferably operated using renewable energies. The hydrogen produced in this way is therefore free of carbon dioxide emissions and is therefore considered so-called “green” hydrogen. In this case, the further hydrogen source is connected to the recirculation circuit in such a way that hydrogen is fed to the recirculation circuit. As a result, the capacity of the ammonia synthesis can be increased. The burner side of the primary reformer is connected to the secondary reformer. As a result, the synthesis is supplied with nitrogen on the one hand and carbon dioxide on the other. The carbon dioxide is separated together with the carbon dioxide produced in the reformer and fed to the urea synthesis. On the one hand, this allows the overall capacity to be expanded and, on the other hand, the carbon footprint is reduced.

In a further aspect, the invention relates to a further method for expanding the capacity of an existing plant according to the prior art. The plant will be expanded to include a further hydrogen source and a second carbon dioxide separator. Water electrolysis is preferably operated using renewable energies. The hydrogen produced in this way is therefore free of carbon dioxide emissions and is therefore considered so-called “green” hydrogen. The further hydrogen source is connected to the recirculation circuit in such a way that hydrogen is fed to the recirculation circuit. This increases the amount of hydrogen fed to the converter. The burner side of the primary reformer is connected to the second carbon dioxide separator. Furthermore, the second carbon dioxide separator is connected to the recirculation circuit in such a way that nitrogen is supplied to the recirculation circuit. Thus, in addition to additional Hydrogen is also supplied with nitrogen, thus increasing the overall capacity. Further, the second carbon dioxide trap is connected to the urea synthesizing device such that carbon dioxide is supplied to the urea synthesizing device. This ensures the increased production of urea due to the increased amount of ammonia.

The system according to the invention is explained in more detail below with reference to exemplary embodiments illustrated in the drawings.

1 prior art

2 first exemplary embodiment

3 second exemplary embodiment

4 fifth exemplary embodiment

5 sixth exemplary embodiment

6 seventh exemplary embodiment

7 ninth exemplary embodiment

8 tenth exemplary embodiment

First of all, the components that are common to all the exemplary embodiments will be discussed, shown by the prior art in FIG. 1 , and then only the additional components in each case

The representations are simplified and only schematic. For example, compressors K can also be multi-stage. A so-called metanator is also usually present, which is arranged upstream of the feed to the recirculation circuit 100 and converts residual components of carbon dioxide and carbon monoxide, which are catalyst poisons, into methane. Such variants that are customary for ammonia synthesis are not shown here for the sake of simplicity. Likewise, the two compressors, which are arranged after the first carbon dioxide separator 40 and the ammonia separator 70, can be identical. Such variants and arrangements for gas routing are known to those skilled in the art and have no direct effect on the invention. The system according to the prior art according to FIG. 1 serves to synthesize ammonia with further conversion to urea, the hydrogen being produced by means of steam reforming and ammonia via the Haber-Bosch process.

In a primary reformer 10, 16 methane and steam are supplied on the hydrogen side 12 as a hydrogen source. The energy required for the conversion is generated and made available by combustion on the burner side 14 . A mixture of methane and air, for example, is made available via the fuel gas supply 18 . A gas mixture of nitrogen and carbon dioxide is thus ideally generated on the burner side 14 . Really, around 2% by volume of oxygen can be present as an additional component. The gas mixture generated on the hydrogen side 12 is fed into a secondary reformer 20, where air is usually added. This is where methane, for example, is reacted with oxygen to form carbon monoxide and hydrogen. In a subsequent shift reactor 30, which usually consists of two separate reactors at different temperatures, carbon monoxide is reacted with water to form carbon dioxide and hydrogen. The carbon dioxide is then separated off in a first carbon dioxide separator 40 . The gas, which should then only contain nitrogen and hydrogen, is fed into the recirculation circuit 100 via a compressor K. In the recirculation circuit 100 the gas is first heated in a heat exchanger W and then fed to the converter 50 . The heat of reaction released during the reaction is then dissipated in a cooler 60 . The gas flow is then further cooled in a heat exchanger W, so that ammonia is separated off in the ammonia separator 70 . Unreacted hydrogen and unreacted nitrogen remain in the gas stream. These gases are recirculated by a compressor to form the recirculation circuit 100 . The ammonia separated in the ammonia separator 70 and the carbon dioxide separated in the first carbon dioxide separator are converted into urea and water in the urea synthesizing device 80 . This is usually followed by granulation, with or without other additives, in order to sell the urea as fertilizer.

The exemplary embodiments are now shown below using the additional components and connections. A first exemplary embodiment is shown in FIG. This is another source of hydrogen. This consists only of a solar and wind park 110, for example. Here, electricity is generated from renewable energies, sun and wind. This electricity is used to generate hydrogen in the water electrolysis 120. The hydrogen can be temporarily stored in a storage facility to compensate for fluctuations in solar radiation and wind. Likewise, a battery can be present between the solar and wind park 110 and the water electrolysis 120 for equalization. The (“green”) hydrogen produced in this way is combined with the gas stream coming from the reformer and fed to the recirculation circuit 100 . As a result, however, nitrogen is substoichiometrically present. In order not to have to operate an energy-intensive air separation, the nitrogen is obtained from the exhaust gas on the burner side 14 of the primary reformer 10 . For this purpose, the gas is first dedusted in a dedusting device 90 . Optionally, the gas can then be passed through a desulfurization device 92, particularly in regions where natural gas containing sulfur is used. The gas is then fed into the second carbon dioxide separator 130, which is designed as an ammonia-water scrubber, as can be found in WO 2019/110 443 A1 or EP 3 390 354 B1, for example. The second carbon dioxide separator 130 has a CO2 dissolving device 132 in which the carbon dioxide is dissolved in ammonia water. The solution is then compressed via a pump P, for example to 150 bar, and fed via a heat exchanger W into the CO2 delivery device 134 . There, the carbon dioxide is released again at elevated temperatures and can be released via the CO2 discharge 140 . In the simplest case, it is released to the environment. However, it can also be stored or converted in order to avoid CO2 emissions. The ammonia water is returned to the CO2 dissolving device 132 from the CO2 discharging device 134 via the heat exchanger W. In addition, the second carbon dioxide separator 130 has an ammonia retention wash 136 . In this way, a pure nitrogen stream is obtained, which is then fed to the gas stream supplied to the recirculation circuit 100 . In this case, the nitrogen gas flow can also only be partially supplied in order to obtain the correct stoichiometry. For example, excess nitrogen can simply be released to the environment or used as an inert gas in further syntheses. That I Oxygen and nitrogen are similar than nitrogen and carbon dioxide, separation from this burner side 14 gas stream is more efficient than air separation.

A second exemplary embodiment is shown in FIG. 3 . This differs from the first exemplary embodiment in that the stream of nitrogen is conducted from the second carbon dioxide separator 130 into the secondary reformer 20 in order to burn off residual oxygen there.

4 shows a fifth exemplary embodiment. This is another source of hydrogen. This consists only of a solar and wind park 110, for example. Here, electricity is generated from renewable energies, sun and wind. This electricity is used to generate hydrogen in the water electrolysis 120. The hydrogen can be temporarily stored in a storage facility to compensate for fluctuations in solar radiation and wind. Likewise, a battery can be present between the solar and wind park 110 and the water electrolysis 120 for equalization. The (“green”) hydrogen produced in this way is combined with the gas stream coming from the reformer and fed to the recirculation circuit 100 . As a result, however, nitrogen is substoichiometrically present. In order not to have to operate an energy-intensive air separation, the nitrogen is obtained from the exhaust gas on the burner side 14 of the primary reformer 10 . For this purpose, the gas is first dedusted in a dedusting device 90 . Optionally, the gas can then be passed through a desulfurization device 92, particularly in regions where natural gas containing sulfur is used. The gas is then fed to the secondary reformer 20 via a compressor K and a heat exchanger W. Here, the order of compressor K and heat exchanger can also be reversed. On the one hand, this balances out the ratio of hydrogen to nitrogen. In addition, more carbon dioxide is introduced, which is separated in the first carbon dioxide separator 40 and fed to the urea synthesizer 80 . This makes it very easy to increase the total amount of urea produced and at the same time reduce the CO2 footprint. Advantage of this fifth exemplary embodiment is the flexible guidance to supply a part of the carbon dioxide from the burner side 14 of the urea synthesizer 80 and deliver another part via the CO2 discharge 140, so as to provide the correct Easy to adjust stoichiometry. Here, the order of compressor K and heat exchanger can also be reversed.

FIG. 5 shows a sixth exemplary embodiment, which differs from the fifth embodiment in that the carbon dioxide from the second carbon dioxide separator 130 is used in the urea synthesizing device 80 . For this purpose, the carbon dioxide that accumulates in the first carbon dioxide separator 40 is discarded since it is at a lower pressure level.

6 shows a seventh exemplary embodiment. In many plants, less carbon dioxide is provided from the first carbon dioxide separator 40 than would be necessary for the complete conversion of the ammonia into urea. In order to increase production, another source of carbon dioxide must be found. This is found in the exhaust gas on the burner side 14 of the primary reformer 10. For this purpose, the gas is first dedusted in a dedusting device 90. Optionally, the gas can then be passed through a desulfurization device 92, particularly in regions where natural gas containing sulfur is used. The gas is then fed into the second carbon dioxide separator 130, which is designed as an ammonia-water scrubber, as can be found in WO 2019/110 443 A1 or EP 3 390 354 B1, for example. The second carbon dioxide separator 130 has a CO2 dissolving device 132 in which the carbon dioxide is dissolved in ammonia water. The solution is then compressed by a pump P, for example to 150 bar, and fed via a heat exchanger W into the CO2 delivery device 134 . There, the carbon dioxide is released again at elevated temperatures and is then fed to the urea synthesis device 80, with the high pressure of the CO2 release device 134 making the carbon dioxide available at the correct pressure level. The ammonia water is returned to the O 2 dissolving device 132 from the CO 2 discharging device 134 via the heat exchanger W. In addition, the second carbon dioxide separator 130 has an ammonia retention scrubber 136, as a result of which no ammonia is released into the environment with the nitrogen via the nitrogen discharge 150 or is introduced with the nitrogen as an inert gas in further syntheses. Advantage of this seventh exemplary embodiment is that both the nitrogen stream to the recirculation circuit 100 and thus the Ammonia synthesis and the carbon dioxide stream of the urea synthesis device 80 is supplied. This fifth embodiment is particularly preferred in the case of retrofitting, since only the second carbon dioxide separator 130 and a further hydrogen source are provided, and in this way an increase in sales in the production quantity can take place while at the same time reducing the CCh footprint.

7 shows a ninth exemplary embodiment, which is a combination of the first exemplary embodiment, the third exemplary embodiment, and the fourth exemplary embodiment. As a result, all options are open during the operation of the plant to enable different modes of operation, for example to be able to adapt to fluctuating amounts of regeneratively generated energy.

The tenth exemplary embodiment shown in FIG. 8 differs from the second exemplary embodiment shown in FIG. 3 in that it does not have a urea synthesizing device 80 . This embodiment is particularly suitable for expanding the capacity of an existing plant for the synthesis of ammonia.

Reference sign

10 Primary Reformers

12 hydrogen side

14 burner side

16 hydrogen source

18 fuel gas supply

20 Secondary Reformers

30 shift reactor

40 first carbon dioxide separator

50 converters

60 cooler

70 ammonia separator

80 urea synthesizer

90 dedusting device

92 desulfurization device 100 recirculation circuit

110 solar and wind park

120 water electrolysis

130 second carbon dioxide separator 132 CO2 dissolving device

134 CCh dispenser

136 Ammonia retention scrubbing

140 CO2 discharge

150 nitrogen discharge K compressor

P pump

W heat exchanger

Claims

patent claims 1. Plant for the synthesis of ammonia, the plant having at least one Has a reformer for converting a hydrocarbon into hydrogen, the plant having a converter (50) for converting hydrogen and nitrogen into ammonia, the converter (50) being integrated into a recirculation circuit (100), a first carbon dioxide separator (40) being arranged between the reformer and the recirculation circuit (100), the recirculation circuit (100) having an ammonia separator (70), characterized in that the plant has a further hydrogen source, the further hydrogen source is connected to the recirculation circuit (100) in such a way that the hydrogen Recirculation circuit (100) is supplied, the system having a Combustion device having, wherein the combustion device is connected to a second carbon dioxide separator (130), wherein the second carbon dioxide separator (130) is connected to the recirculation circuit (100) in such a way that nitrogen is fed to the recirculation circuit (100). 2. Plant according to Claim 1, characterized in that the reformer has a primary reformer (10) and a secondary reformer (20) for converting a hydrocarbon into hydrogen, the primary reformer (10) having a hydrogen side (12) and a burner side (14), the burner side being the combustion device, the burner side (14) of the primary reformer (10) combusting hydrocarbon with air, the burner side (14) of the primary reformer (1 0) is connected to a second carbon dioxide separator (130). 3. Plant according to claim 1, characterized in that the combustion device is a steam generating device. 4. Plant according to claim 1, characterized in that the reformer is an autothermal reformer. 5. Plant according to one of the preceding claims, characterized in that the second carbon dioxide separator (130) is an ammonia water wash. 6. Plant according to one of the preceding claims, characterized in that the plant is used for the synthesis of ammonia and for the further synthesis of urea from the ammonia produced, the plant having a urea synthesis device (80) for the synthesis of urea from ammonia and carbon dioxide, the first carbon dioxide separator (40) for the separated carbon dioxide being connected to the urea synthesis device (80), the ammonia separator (70) being connected to the urea synthesis device (80) to carry ammonia. 7. Plant according to one of the preceding claims in conjunction with claim 2, characterized in that the second carbon dioxide separator (130) is connected to the recirculation circuit (100) in such a way that nitrogen is fed to the recirculation circuit (100) via the secondary reformer (20). 8. Plant according to one of the preceding claims in conjunction with claim 3, characterized in that the second carbon dioxide separator (130) is connected to the recirculation circuit (100) in such a way that nitrogen is fed to the recirculation circuit (100) via the autothermal reformer. 9. Installation according to one of the preceding claims, characterized in that a dedusting device (90) is arranged between the combustion device and the second carbon dioxide separator (130). 10. Plant according to one of the preceding claims, characterized in that the further hydrogen source and the second carbon dioxide separator (130) are connected to the recirculation circuit (100) in such a way that the hydrogen stream from the further hydrogen source is first combined with the nitrogen stream from the second carbon dioxide separator (130), the mixture is then passed through a first compressor (K) and then passed through a methanator and then fed to the recirculation circuit (100). 19 Plant according to one of the preceding claims, characterized in that the combustion device is connected to the reformer. Plant according to one of the preceding claims, characterized in that a dedusting device (90) is arranged between the combustion device and the reformer. Plant according to one of the preceding claims, characterized in that a compressor (K) is arranged between the combustion device and the reformer. Plant according to one of the preceding claims and for the further synthesis of urea from the ammonia produced, the plant having a urea synthesis device (80) for the synthesis of urea from ammonia and carbon dioxide, the ammonia separator (70) being ammonia-carrying connected to the urea synthesis device (80), characterized in that the second carbon dioxide separator (130) is connected to the urea synthesis device (80) in such a way that carbon dioxide is fed to the urea synthesis device (80). Method for expanding the capacity of an existing plant according to the prior art, characterized in that the plant is expanded to include a further hydrogen source, the further hydrogen source being connected to the recirculation circuit (100) in such a way that hydrogen is fed to the recirculation circuit (100), the burner side (14) of the primary reformer (10) being connected to the secondary reformer (20). Method for expanding the capacity of an existing plant according to the prior art, characterized in that the plant is expanded to include a further hydrogen source and a second carbon dioxide separator (130), the further hydrogen source being connected to the recirculation circuit (100) in such a way that hydrogen is fed to the recirculation circuit (100), the burner side (14) of the primary reformer (10) being connected to the second carbon dioxide separator (130), the second 20 Carbon dioxide separator (130) is connected to the recirculation circuit (100) in such a way that nitrogen is supplied to the recirculation circuit (100), the second carbon dioxide separator (130) being connected to the urea synthesizer (80) in such a way that carbon dioxide is supplied to the urea synthesizer (80).