BE1030201B1 - Ammonia synthesis and urea synthesis with reduced carbon footprint - Google Patents

Abstract

The present invention relates to a device for synthesizing ammonia, in which the gases produced in the burner side of the primary reformer are used at least partially as educts.

Description

'BE2022/5031

Ammonia synthesis and urea synthesis with reduced carbon footprint

The invention relates to a plant network and a method for generating

Ammonia from a combination of hydrogen from natural gas and from electrolysis using renewable energy and at the same time using the carbon dioxide in the

Urea synthesis and / or nitrogen in the ammonia synthesis, which in the

generation of hydrogen from natural gas.

For the production of hydrogen, in particular, steam reforming is used, in which a hydrocarbon with water vapor to carbon monoxide and

Hydrogen and then the carbon monoxide in a water gas shift reaction

Carbon dioxide and hydrogen is converted. For this purpose, energy must be provided from the outside for this endothermic reaction, which for example by a

Combustion of hydrocarbons takes place in an adjacent combustion chamber.

Alternatively, autothermal reforming is used, in which partial oxidation takes place and thus provides the required energy.

Typically, methane is added with water and air in the primary and secondary reformers

Carbon dioxide and hydrogen implemented, usually with the

Target composition of 3:1 of hydrogen to nitrogen is set. This is usually done in steps, with methane first being reacted with water in a primary reformer, with the addition of energy, and then in one

Secondary reformer with the supply of oxygen, usually in the form of air, and a subsequent shift reaction to convert carbon monoxide with water

carbon dioxide and hydrogen takes place. Thus, after removing the carbon dioxide and usually converting any carbon monoxide present into

methane, this mixture can be converted directly into ammonia in a converter.

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 CO: for the

Known urea synthesis from flue gas and synthesis gas.

? BE2022/5031

From EP 3,390,354 B1 is a method for providing carbon dioxide for

Synthesis of urea known.

It is also known that hydrogen can be produced from renewable sources in particular by means of electrolysis

To generate 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 here no

While nitrogen is produced during the production of hydrogen, it 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 mostly directly to the

delivered to the environment.

The object of the invention is to produce on the burner side of the primary reformer

To use flue gas within the process at least partially and thus save energy

Saving the entire process and/or reducing emissions.

This problem is solved by the systems specified in claim 1

Features and by the method with the features specified in claim 18 and claim 19. Advantageous developments result from the

Subclaims, 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 produced ammonia. Such combined systems for

Production of nitrogenous fertilizers are known and common. 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

Have ammonia and nitric acid. The plant allocates a reformer

) BE2022/5031

Conversion of a hydrocarbon into hydrogen. For example, the

Reformer a primary reformer and a secondary reformer to implement a

Hydrocarbon into hydrogen, in particular steam reforming is used here, in which in a first step in particular methane is reacted with steam and in a second step with air, with usually a downstream

Water-gas shift reaction takes place, in which the carbon monoxide produced is reacted with water vapor to form carbon dioxide and hydrogen. Alternatively, the reformer can be an autothermal reformer, in which the hydrocarbon, water vapor and oxygen are brought together in such a way that the conversion to hydrogen is required

Energy is generated directly from combustion. In contrast to steam reforming, no energy has to be supplied from outside. The system also has a

Converter for converting hydrogen and nitrogen into ammonia. The

Converter has a catalyst and operates at high pressure and high temperature. Since the implementation is an equilibrium reaction that does not have almost complete conversion, the synthesis gas is in one

Out recirculation cycle to be able to feed unreacted educts back to the converter. The process is known as the Haber-Bosch process. Accordingly, the converter is integrated into a recirculation circuit. A first carbon dioxide separator is arranged between the reformer and the recirculation circuit. Here the carbon dioxide produced from the starting material, in particular methane, is separated off, for example and in particular around this

To supply 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 up to traces) for the

Ammonia synthesis provided. Between the first

Carbon dioxide separator and the recirculation circuit is usually a

Methanator, a device for converting any traces of

Carbon monoxide and carbon dioxide present in methane to intoxicate the

prevent catalyst. The recirculation cycle has a

ammonia separator. Here the product becomes ammonia from the unreacted

Educt stream separated from nitrogen and hydrogen. Furthermore, the

Recirculation cycle usually on heat exchangers, between the converter and the ammonia separator for cooling and between the ammonia separator and

* BE2022/5031 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. Thus, the hydrogen produced in this way is free of

Carbon dioxide emissions, is therefore considered so-called "green" hydrogen. the other

The hydrogen source is connected to the recirculation loop in such a way that hydrogen is fed to the recirculation loop. The hydrogen from the further

Hydrogen source is preferred for this purpose with the hydrogen from the

Steam reforming, preferably after the secondary reformer and more preferably after a water gas shift reaction. As a result, the hydrogen at low pressure with

Nitrogen mixed so that it is easier to compress. The plant has a

combustion device. The combustor is connected to the reformer. In this case, the combustion device can also be a component of the reformer, as shown in the following in embodiments. 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

Combustion devices are combined when a larger gas flow is desired. The combustion device, for example the burner side of the primary reformer, is connected to the secondary reformer. But this also causes nitrogen

Carbon dioxide and the rest oxygen fed to the gas stream to produce hydrogen. The remaining residual oxygen is converted in the secondary reformer. Since carbon dioxide is separated after the secondary reformer, it can also be on the

Carbon dioxide generated on the burner side can then be separated in the same step.

In a further embodiment of the invention, the system has a further

source of hydrogen. The further hydrogen source is preferably one

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

> BE2022/5031 is supplied. 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, it can be the

Combustion device act around the burner side of a primary reformer. Alternatively, the combustion device may be a steam generating device. One

Steam generating device is operated, for example, to operate the compressors. Likewise, the exhaust gases from two or more

Combustion devices are combined when 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 circuit in such a way that

Nitrogen is fed to the recirculation circuit. First of all, preference is given to

Hydrogen from the further hydrogen source and the nitrogen from the second

Carbon dioxide separator combined and compressed together by one or more compressors. The advantage is that due to the combustion on the burner side, nitrogen can be removed relatively easily in further process steps by separating it from the

Carbon dioxide can be provided and so without an energy consuming

Air separation the ratio of hydrogen to nitrogen can be adjusted from 3:1.

In a further embodiment of the invention, the reformer has a

Primary reformer and a secondary reformer for converting a hydrocarbon into hydrogen. The primary reformer has a hydrogen side and a burner side. On the hydrogen side, hydrocarbons are mixed with water vapor

Carbon monoxide or carbon dioxide and hydrogen implemented. The energy required for this is provided by combustion, in particular of hydrocarbons, with oxygen, in particular with air. The burner side is here

Combustor in which hydrocarbon is combusted 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 connected.

In a further embodiment of the invention, the combustion device is a

steam generating device.

° BE2022/5031

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

Reformer.

In a further embodiment of the invention, the system further has a

Urea synthesizer for synthesizing urea from ammonia and

carbon dioxide up. The first carbon dioxide separator is for the separated

Carbon dioxide connected to the urea synthesizer. Usually the

Amount of carbon dioxide separated slightly less than that from the nitrogen and

Hydrogen generated amount of ammonia, so not complete conversion of the

Ammonia to urea takes place. The ammonia separator is ammonia-leading with the

Connected urea synthesis device. Here, in the ammonia-leading

Connection also be arranged a cache.

In a further embodiment of the invention, the second carbon dioxide separator is an ammonia water scrubber. Such scrubbers are, 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 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 between the second

Carbon dioxide separator and the recirculation circuit a device for

Ordered to remove oxygen. Preferably then an additional

Compressor provided to equalize the pressure to the high level of the

to achieve recirculation cycle.

In a further embodiment of the invention, the burner side of the primary reformer with an excess of oxygen or an excess of methane

/ BE2022/5031 operated. 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 over the autothermal

Reactor is fed to the recirculation circuit. This also allows the existing

Residual oxygen can be reliably implemented.

In a further embodiment of the invention between the

Combustion device, preferably the burner side of the primary reformer, and the second carbon dioxide separator arranged a dedusting device. 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 further hydrogen source and the second carbon dioxide separator are connected to the recirculation circuit in such a way that the hydrogen stream from the further \hydrogen source is initially connected to the

Nitrogen stream of the second carbon dioxide separator is combined, is then passed through a first compressor and then passed 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, between the burner side of the

Primary reformer and the secondary reformer arranged a dedusting device.

Preference can additionally after the dedusting device

Desulfurization device and / or a denitrification device can be arranged.

In a further embodiment of the invention between the

Combustion device, preferably the burner side of the primary reformer, and the

Reformer, preferably the secondary reformer, arranged a compressor.

° BE2022/5031

In a further embodiment of the invention, the plant is used for the further synthesis of urea from the ammonia produced. Such combined systems for

Production of nitrogenous fertilizers are known and common. 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

Have ammonia and nitric acid. The system also has a

Urea synthesizer for synthesizing urea from ammonia and

carbon dioxide up. Between the reformer and the recirculation loop is a first

Carbon dioxide separator arranged. 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 the urea synthesis device. Thus, after the first carbon dioxide separator, a gas stream containing nitrogen and hydrogen is im

Ratio 1:3 and without further components (possibly up to traces) for the

Ammonia synthesis provided. 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

Combustion device, for example connected to the burner side of the primary reformer with a second carbon dioxide separator. The second carbon dioxide separator is connected to the urea synthesizer in such a way that the carbon dioxide

Urea synthesis device is supplied.

In another embodiment of the invention, the first carbon dioxide separator for the separated carbon dioxide is connected to the urea synthesizer.

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.

In a further embodiment of the invention, the system has a further

source of hydrogen. The other source of hydrogen is such with the

Connected recirculation circuit that hydrogen is fed to the recirculation circuit. The burner side of the primary reformer is connected to a second

Carbon dioxide separator connected. The second carbon dioxide separator is connected to the recirculation circuit in such a way that nitrogen is added to the recirculation circuit

) BE2022/5031 is supplied. The burner side of the primary reformer is connected to the secondary reformer.

In a further embodiment of the invention, the system has a further

source of hydrogen. The further \hydrogen source is such with the

Connected recirculation circuit that hydrogen is fed to the recirculation circuit. The burner side of the primary reformer is connected to a second

Carbon dioxide separator connected. The second carbon dioxide separator is connected to the recirculation loop in such a way that nitrogen is supplied to the recirculation loop. Next, the second carbon dioxide separator is such with the

Urea synthesizer connected that carbon dioxide of

Urea synthesis device is supplied. This allows optimal use of all

gas flows can be achieved. Through the additional, especially "green" produced

Hydrogen, a ratio of nitrogen to hydrogen to carbon dioxide of, for example, 2:6:1 can be achieved.

In a further embodiment of the invention, the system has a further

source of hydrogen. The other source of hydrogen is such with the

Connected recirculation circuit that hydrogen is fed 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 with a second

Carbon dioxide separator connected and the second carbon dioxide separator is connected to the urea synthesizer in such a way that the carbon dioxide

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 also

Partial streams, in particular the exhaust gas from the burner side, the stream of nitrogen or the

Carbon dioxide stream of the second carbon dioxide separator is separated and discarded or otherwise used.

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. Thus, the hydrogen produced in this way is free of

Carbon dioxide emissions, is therefore considered so-called "green" hydrogen. the other

The hydrogen source is connected to the recirculation circuit in such a way that

Hydrogen is fed to the recirculation circuit. This allows the capacity of

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 together with the im

Reformer resulting carbon dioxide deposited 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 another method for

Capacity expansion of an existing plant according to the state of the art. The

The plant will be expanded to include another hydrogen source and a second

Carbon dioxide separator extended. Water electrolysis is preferably operated using renewable energies. Thus, the hydrogen produced in this way is free of

Carbon dioxide emissions, is therefore considered so-called "green" hydrogen. the other

Hydrogen source is connected to the recirculation circuit in such a way that

Hydrogen 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. Next will be the second

Carbon dioxide separator connected to the recirculation circuit in such a way that

Nitrogen is fed 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.

As a result, the increased production of ammonia caused by the increased amount of ammonia

Urea guaranteed.

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 third exemplary embodiment

3 fifth exemplary embodiment

4 sixth exemplary embodiment

5 eighth exemplary embodiment

6 ninth 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, can

Compressors K can also be multi-stage. Next is usually a so-called metanator present, which is arranged in front of the feed to the recirculation circuit 100 and residual components of carbon dioxide and carbon monoxide, which

Catalyst poisons are converted into methane. Such usual for the ammonia synthesis

Variants are not shown here for the sake of simplicity. Likewise, both of them can

Compressors, which after the first carbon dioxide separator 40 and the

Ammonia separator 70 are arranged to be identical. Such variants and

Gas routing arrangements are known to those skilled in the art and have no direct impact on the invention.

The system according to the prior art shown in FIG. 1 is used for the synthesis of ammonia with further conversion to urea, the hydrogen by means

Steam reforming and ammonia is produced via the Haber-Bosch process.

In a primary reformer 10, 12 is used on the hydrogen side as a hydrogen source 16

Methane and water vapor supplied. The energy required for the conversion is generated and made available by combustion on the burner side 14 . About the

Combustion gas supply 18 is provided, for example, a mixture of methane and air. A gas mixture of nitrogen and nitrogen is therefore ideal on the burner side 14

carbon dioxide generated. Really, around 2% by volume of oxygen can be present as an additional component. The gas mixture generated on the hydrogen side 12 is in one

Secondary reformer 20 out, where air is usually added. Here the

Implementation of, for example, methane with oxygen to carbon monoxide and

Hydrogen. In a subsequent shift reactor 30, which usually consists of two separate reactors at different temperatures, carbon monoxide is with

Water converted to carbon dioxide and hydrogen. Subsequently, in a first

Carbon dioxide separator 40 separated the carbon dioxide. The gas, which should then only contain nitrogen and hydrogen, is fed into the via a compressor K

Recirculation circuit 100 out. In the recirculation circuit 100 the gas is first heated in a heat exchanger W and then fed to the converter 50 .

Then, in a cooler 60, the water released during the reaction

Heat of reaction dissipated. Subsequently, the gas flow in a heat exchanger

W further cooled, so that in the ammonia separator 70 ammonia is separated.

Unreacted hydrogen and unreacted nitrogen remain in the gas stream.

These gases are recirculated by a compressor so that the

Recirculation circuit 100 is created. The separated in the ammonia separator 70

Ammonia and the carbon dioxide separated in the first carbon dioxide separator are converted into urea and water in the urea synthesis device 80 .

This is usually followed by granulation, with or without anything else

Additives to sell the urea as fertilizer.

The exemplary embodiments are now shown below using the additional components and connections.

A third exemplary embodiment is shown in FIG. At this one is another

Hydrogen source available. This consists only as an example of a solar and

Wind farm 110. Electricity is generated here 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

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 from the

Exhaust gas from the burner side 14 of the primary reformer 10 is obtained. 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. Then it will

Gas is 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 in the first

Carbon dioxide separator 40 deposited and the urea synthesis device 80 is supplied. As a result, the total quantity produced can be calculated in a very simple manner

Urea can be increased and the CO2 footprint reduced at the same time.

3 shows a fifth exemplary embodiment. At this one is another

Hydrogen source available. This consists only as an example of a solar and

Wind farm 110. Electricity is generated here 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

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 comparison purposes. 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 from the

Exhaust gas from the burner side 14 of the primary reformer 10 is obtained. 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. Then it will

Out gas in the second carbon dioxide separator 130, which as an ammonia-water

Washer is performed, such as WO 2019 / 110 443 A1 or the

EP 3 390 354 B1 can be found. 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 sent to the

delivered environment. But it can also be stored or converted to CO-z-

to avoid 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

Laundry 136 up. As a result, a pure stream of nitrogen is obtained, which is then dem

Recirculation circuit 100 supplied gas stream is supplied. Here he can

Nitrogen gas flow can also be partially fed 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. The advantage of this fifth exemplary embodiment is the flexible guidance in order to

Supply carbon dioxide from the burner side 14 of the urea synthesizer 80 and deliver another portion through the CO2 discharge 140, so as to correct the

Easy to adjust stoichiometry. Here, the order of

Compressor K and heat exchanger can also be reversed.

Fig. 4 showed a sixth exemplary embodiment, which differs from the fifth

Embodiment differs in that the carbon dioxide from the second

Carbon dioxide separator 130 is used in the urea synthesizer 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.

5 shows an eighth 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. Then the gas in the second

Carbon dioxide separator 130 out, which is designed as an ammonia-water scrubber, such as WO 2019/110 443 A1 or the

EP 3 390 354 B1 can be found. 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 is then fed to the urea synthesis device 80, the high pressure of the CO2

Dispenser 134 provides the carbon dioxide at the correct pressure level. The ammonia water is from the COz-discharge device 134 on the

Heat exchanger W back into the CO2 release device 132 out. In addition, the second carbon dioxide separator 130 has an ammonia retention wash 136, whereby no ammonia is released into the nitrogen outlet 150 with the nitrogen

Environment is released or is introduced with the nitrogen as an inert gas in further syntheses. Here, the required for the regeneratively generated hydrogen

Nitrogen are provided by the gas stream supplied to the secondary reformer 20 . At the same time, more carbon dioxide is released over the second

Carbon dioxide separator 130 of the urea synthesizer 80 is provided.

6 shows a ninth exemplary embodiment. As a result, during the

When operating the plant, all options are open to enable different modes of operation, for example to be able to adapt to fluctuating amounts of regenerative energy.

Reference numeral 10 primary reformer 12 hydrogen side 14 burner side 16 hydrogen source 18 fuel gas supply 20 secondary reformer

Shift reactor first carbon dioxide separator 30 50 converter 60 cooler 70 ammonia separator 80 urea synthesis device 90 dedusting device

92 Deflection device 100 Recirculation cycle 110 Solar and wind farm 120 Water Electrolysis 130 Second carbon dioxide separator 132 CO: Power device 134 CO2 levy device 136 Ammonia retention underwear 140 CO2 removal 150 nitrogen removal

K compressor

P pump

W heat exchanger

Claims (19)

patent claims 1. A plant for the synthesis of ammonia, the plant having a reformer for converting a hydrocarbon into hydrogen, the plant having a converter (50) for converting hydrogen and nitrogen into ammonia, the converter (50) in a recirculation circuit (100 ) is integrated, 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 hydrogen is fed to the recirculation circuit (100), the system having a combustion device, the combustion device being connected to the reformer. 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). wherein the burner side is the combustion device, wherein in the burner side (14) of the primary reformer (10) hydrocarbon is combusted with air, the burner side (14) of the primary reformer (10) being 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 plant 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 is connected to the urea synthesis device (80), the ammonia separator (70) being ammonia-carrying connected to the urea synthesis device (80). 6. 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). 7. 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 reactor. 8. Installation according to one of the preceding claims, characterized in that a dedusting device (90) is arranged between the combustion device and the reformer. 9. Installation according to one of the preceding claims, characterized in that a compressor (K) is arranged between the combustion device and the reformer. 10. Plant according to one of the preceding claims, characterized in that the combustion device is connected to a second carbon dioxide separator (130), the second carbon dioxide separator (130) being connected to the recirculation circuit (100) in such a way that nitrogen is fed to the recirculation circuit (100). becomes. 11.An installation according to claim 10, characterized in that the second carbon dioxide separator (130) is an ammonia-water wash. 12. Installation according to one of claims 10 to 11, characterized in that a dedusting device (90) is arranged between the combustion device and the second carbon dioxide separator (130). 13. Plant according to one of the preceding claims 10 to 12, 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 initially mixed with the nitrogen stream from the second carbon dioxide separator ( 130) is combined, then passed through a first compressor (K) and then passed through a methanator and then fed to the recirculation circuit (100). 14. 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) carrying ammonia with the urea synthesis device (80) connected, characterized in that the plant has a combustion device, the combustion device being connected to a second carbon dioxide separator (130), the second carbon dioxide separator (130) being connected to the urea synthesizer (80) in such a way that carbon dioxide is fed to the urea synthesizer (80). becomes. 15.Installation according to claim 14, characterized in that the first carbon dioxide separator (40) for the separated carbon dioxide is connected to the urea synthesis device (80). 16. Plant according to one of claims 14 to 15, characterized in that the second carbon dioxide separator (130) is an ammonia water scrubber. 17.An installation according to one of claims 14 to 16, characterized in that a dedusting device (90) is arranged between the combustion device and the second carbon dioxide separator (130). 18. A 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 in such a way to the recirculation circuit (100) that hydrogen is the Recirculation circuit (100) is supplied, wherein the burner side (14) of the primary reformer (10) is connected to the secondary reformer (20). 19. 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 carbon dioxide separator (130) being connected to the recirculation circuit (100) in such a way that nitrogen is fed to the recirculation circuit (100) is supplied, wherein the second carbon dioxide separator (130) is connected to the urea synthesizing device (80) in such a way that carbon dioxide is supplied to the urea synthesizing device (80).