EP3867584A1

EP3867584A1 - Installation and method for producing liquefied methane

Info

Publication number: EP3867584A1
Application number: EP19795280.7A
Authority: EP
Inventors: Jean-Marc Bernhardt; Mathieu Roig
Original assignee: Air Liquide SA; LAir Liquide SA pour lEtude et lExploitation des Procedes Georges Claude
Current assignee: Air Liquide SA; LAir Liquide SA pour lEtude et lExploitation des Procedes Georges Claude
Priority date: 2018-10-18
Filing date: 2019-09-26
Publication date: 2021-08-25
Also published as: CN112840168A; US20210364228A1; WO2020079337A1; FR3087526A1; FR3087526B1

Abstract

An installation and a method for producing liquefied methane comprising, disposed in series in a circuit (10), a component (2), such as a methanation reactor, for generating methane from hydrogen and carbon dioxide, a component (3) for drying the gaseous mixture produced by the methane generation component (2), a purification component (4) configured to withdraw carbon dioxide from the gas mixture dried in the drying component (3), a liquefier (5) configured to liquefy the methane contained in the gas mixture purified in the purification component (4), and a liquefied gas storage facility (7) configured to store the methane liquefied by the liquefier (5), the installation being characterised in that it comprises a hydrogen separation device (6) configured to withdraw at least some of the hydrogen from the fluid mixture produced by the liquefier (5) before it enters the storage facility.

Description

Installation and production process for

liquefied methane

The invention relates to an installation and a method for producing liquefied methane.

The invention relates more particularly to a plant for producing liquefied methane comprising, arranged in series in a circuit, a member for generating methane from hydrogen and carbon dioxide such as a methanation reactor, a drying member from the gas mixture produced by the methane generating member, a purifying member configured to remove carbon dioxide to the dried gas mixture in the drying member, a liquefier configured to liquefy the methane contained in the purified gas mixture in the purification unit, and a storage of liquefied gas configured to store the methane liquefied by the liquefier.

During methanation processes, i.e. generation of methane (CH4) from carbon dioxide (CO2) and hydrogen (H2), the methane produced generally contains carbon dioxide and hydrogen in proportions of the order of 1 to 4% each.

In order to liquefy this gas, purification is necessary upstream of the liquefier.

The purification of carbon dioxide can be carried out in the same way as on “biomethane” production units but the hydrogen practically does not condense at the temperature of liquid methane and remains in the form of gas (two-phase mixture which is pressure). Hydrogen is concentrated in the vapor phase and must be removed during the liquefaction of methane.

The hydrogen source for the methanation reaction can come from the electrolysis of water or another source of production. Its recovery during liquefaction and its recycling to the methanation reactor increases the hydrogen conversion rate and therefore the production of methane. The presence of methane in the recycled gas must be minimized because it limits the reaction (being one of the products thereof).

The purification of methane with a view to its liquefaction is a known process. In the case of biomethane from the purification of biogas (methanisation process), the final purification before liquefaction makes it possible to eliminate the compounds which can solidify, such as CO2 (1 to 3%) and water (traces). See FR2969008 concerning processes with cooling of the purification step and heat recovery for the regeneration step.

See also US6931889 which relates to the recovery of hydrogen by cryogenic process on a gas rich in hydrocarbons. This solution suggests heating the products (rich in H2 and rich in hydrocarbons) for use in gaseous form.

An object of the present invention is to overcome all or part of the drawbacks of the prior art noted above.

To this end, the installation according to the invention, moreover in accordance with the generic definition given in the preamble above, is essentially characterized in that it comprises a hydrogen separation device configured to remove at least part of the hydrogen in the fluid mixture produced by the liquefier before it enters storage.

This allows a separation of the hydrogen all by limiting the quantity of methane leaving with this separated hydrogen. Furthermore, embodiments of the invention may include one or more of the following characteristics:

the purification device comprises a pressure and temperature variation adsorber comprising an outlet for effluent gases comprising methane and hydrogen, said outlet being connected, via a return pipe, to a supply inlet of the methane generator to be recycled,

- The hydrogen separation device comprises an outlet for the separated gas mixture comprising methane and hydrogen, said outlet being connected via a recycling pipe, to an inlet of the methane generating member to be there recycled,

the recycling line comprises a member for reheating the gas mixture before it enters the methane generating member,

the repository is configured to contain liquefied methane in equilibrium with a gaseous mixture, the repository comprising a gas evacuation pipe connecting the gaseous part of the repository to an inlet of the methane generating member,

- The hydrogen separation device comprises a first phase separator container comprising an inlet connected to an outlet of the liquefier to receive the mixture of fluid produced by the liquefier, and two outlets respectively connected to a line for transferring liquid to storage and a gas transfer line to the methane generating member,

- the hydrogen separation device is connected to the outlet of the liquefier via an expansion valve, the installation being configured to cool the mixture of fluids leaving the liquefier at a temperature lower than the equilibrium temperature of pure methane,

the installation comprises, arranged in series on the gas transfer line to the methane generating member, a gas cooling member, in particular a heat exchanger cooled by a cold source and a second separator container phase comprising an inlet connected to a gas outlet of the first phase separator container and two outlets connected respectively to the liquid transfer pipe to the storage and to the gas transfer pipe to the methane generating member,

- The hydrogen separation device comprises a first phase separator container comprising an inlet connected to an outlet of the liquefier to receive the mixture of fluid produced by the liquefier, a first outlet connected, via a reheating heat exchanger, to a membrane separation device configured to separate methane and hydrogen, the membrane separation device comprising an outlet of gas enriched in methane and hydrogen connected to an inlet of the liquefier for its liquefaction, and an outlet of rich effluents in hydrogen connected to an inlet of the methane generating member, the first phase separator container comprising a second liquid outlet connected to the inlet of a second phase separator container.

The invention also relates to a method for producing liquefied methane from a production installation comprising, arranged in series in a circuit, a member for generating methane from hydrogen and carbon dioxide such as a reactor. methanation, an organ for drying the gas mixture produced by the methane generating organ, a purifying organ configured to remove carbon dioxide from the gas mixture dried in the organ drying, a liquefier configured to liquefy the methane contained in the mixture of purified gas in the purification member, and a liquefied gas storage configured to store the methane liquefied by the liquefier, the method comprising a step of hydrogen separation of the mixture of fluid produced by the liquefier before its transfer to storage.

According to other possible particularities:

- The hydrogen separation step comprises at least one of: a separation of liquid / vapor phase in at least one separator container, cooling of the fluid mixture, heating of the mixture of fluids, separation by membranes.

The invention may also relate to any alternative device or method comprising any combination of the above or below features within the scope of the claims.

Other particularities and advantages will appear on reading the description below, made with reference to the figures in which:

FIG. 1 represents a schematic and partial view illustrating an example of structure and operation of an installation according to the invention,

- Figures 2 to 4 show schematic and partial views illustrating a detail of the installation of Figure 1 respectively according to three separate embodiments.

The installation 1 for producing liquefied methane shown diagrammatically in FIG. 1 comprises, arranged in series in a circuit 10, a member 2 for generating methane from hydrogen and carbon dioxide such as a methanation reactor, a member 3 for drying the gas mixture produced by the member 2 for generating methane, a purifying organ 4 configured to remove carbon dioxide from the gas mixture dried in the organ

3 for drying, a liquefier 5 configured to liquefy the methane contained in the mixture of purified gas in the organ

4 for purification and storage 7 of liquefied gas configured to store the methane liquefied by the liquefier 5. In addition, the installation 1 comprises a hydrogen separation device 6 configured to remove at least part of the hydrogen from the mixture of fluid produced by the liquefier

5 before entering the repository 7. For example, the hydrogen separation device 6 is located between the liquefier 5 and the repository 7.

Organ 2 for generating methane from hydrogen and carbon dioxide can conventionally produce methane according to the reaction

The drying member 3 may for example be a condensation and / or adsorption system configured to dry the gas mixture, that is to say removal of water (H2O) towards an outlet as illustrated in FIG. 1 .

The purification member 4 therefore receives a gaseous mixture comprising methane (CH4), hydrogen (H2) and CO2 as input.

The purification member 4 preferably comprises a pressure and temperature variation adsorber (PTSA) configured to remove CO2 from the gas to be liquefied. This purification member 4 includes an outlet for the effluent gases comprising hydrogen (H2) and a methane residue. This outlet being connected, via a return pipe 11, to a power inlet of the methane generating member 2 to be recycled there. The CO2 withdrawn in the purification member 4 can be evacuated via another outlet. The purified mixture (majority CH4 and H2 residue) is supplied to an inlet of the liquefier 5. The liquefier 5 may for example be a liquefier of the "Turbo Brayton" type as sold by the company Air Liquide and allowing refrigeration and liquefaction from 25K to 200K in particular.

The liquefier 5 produces methane liquefied with a residue of hydrogen gas.

The impurities separated during liquefaction (hydrogen with methane residues) can be evacuated by an outlet connected via a recycle pipe 18, 8 to an inlet of the methane generating member 2 to be recycled there.

This liquefied purified mixture is supplied to an inlet of the hydrogen separation device 6. The hydrogen separation device 6 comprises an outlet for the mixture of purified fluid (liquefied methane with very small residues of hydrogen gas) which is supplied to storage 7.

The hydrogen separation device 6 is configured to allow the hydrogen to be separated at cryogenic temperature after (and / or during) the liquefaction of the methane.

As illustrated, the recycling pipe 8 preferably comprises a member 9 for heating (heat exchanger or other) of the relatively cold gas mixture which returns to the member 2 for generating methane.

Storage 7 is for example a cryogenic tank isolated under vacuum and is configured to contain liquefied methane in equilibrium with a gaseous mixture. The storage tank 7 preferably comprises a gas evacuation pipe 8 connecting the gaseous part of the storage tank 7 (upper part) to an inlet of the methane generation member 2 in order to recycle the vaporization gas (H2 and CH4 residues).

This arrangement makes it possible to concentrate the hydrogen in the recycled gas at low pressure and making it possible to return this mixture to the methanation reactor (member 2). Figures 2 to 4 illustrate several possible non-limiting examples of the hydrogen separation device 6.

In the embodiment of Figure 2, this separation can be achieved by a simple liquid / vapor separation.

The hydrogen separation device 6 comprises a single phase separator container 16 comprising an inlet connected to an outlet of the liquefier 5 for receiving the mixture of fluid produced by the liquefier, and two outlets respectively connected to a pipe 10 for transferring liquid to storage 7 and a pipe 18, 8 for transferring gas to the methane generating member 2. The hydrogen separation device 6 can be connected to the outlet of the liquefier 5 via an expansion valve 12. The installation 1 can thus be configured to cool the mixture of fluids leaving the liquefier 5 to a temperature lower than the equilibrium temperature of pure methane. That is to say that the entire flow rate of the CH4 + H2 mixture is cooled to a lower temperature (for example around 105 K) than the equilibrium temperature of CH4 alone (110K at 1 bar). At the outlet of the liquefier 5, the mixture can be at a temperature of around 100 to 105K and a pressure of 10 bar. The expansion valve 12 can be configured to achieve "flash" expansion. Methane can be in storage at a temperature between 100 and 105K and a pressure of 2 bar. The liquid methane withdrawn from storage 7 can have a temperature of 110K at a pressure slightly above atmospheric pressure.

In the embodiment of Figure 3 the hydrogen separation device comprises additional cooling of the vapors. More specifically, the hydrogen separation device 6 comprises, arranged in series at the outlet of the liquefier 5, an expansion valve 12, a first phase separator container 16 whose gas outlet is connected, via a member 13 for cooling the gas to a second phase separator container 26. The cooling member 13 is for example a heat exchanger cooled by a cold source. A gas outlet (hot side) of the second phase separator container 26 can be connected as previously to the pipe 8 for transferring gas to the methane generating member 2. The liquid outlets of the two separator containers 16, 26 can in turn be connected in parallel to the pipe 10 for transferring liquid to the storage 7 in order to transfer the liquid there.

The additional cooling of the vapors produced between the two separator containers 16, 26 can be carried out with cold from the liquefier 5 and / or from an external source of cold such as liquid nitrogen for example.

Only the vapors charged with hydrogen (H2) (at relatively low flow rate) are cooled to a lower temperature (for example to a temperature less than or equal to 92K). This makes it possible to limit the need for cold production of the liquefier 5 or the consumption of LN2 if necessary. The electrical consumption of the installation 1 is thus reduced.

This also makes it possible to increase the hydrogen concentration in the gas recycled to the member 2 when the temperature of the gas leaving the exchanger 13 decreases.

At the outlet of the liquefier 5, the mixture can for example be at a temperature of around 110 to 120K and a pressure of 10 bar. In the first separation container 16 the fluid has for example a temperature of around 110 to 120K and a pressure of 2 to 10 bar.

Downstream of the exchanger 13 the fluid has for example a temperature of approximately 92 to 105K and a pressure of approximately 2 bar.

In the embodiment of FIG. 4, the hydrogen is separated from the vapors via a separation device of the cold membrane type.

The hydrogen separation device 6 comprises a first phase separator container 16 comprising an inlet connected to an outlet of the liquefier 5 to receive the mixture of fluid produced by the liquefier. The first phase separator container 16 comprises a first vapor outlet (“hot gases”) connected, via a heating member 14 (heat exchanger for example), to a membrane separation device 15 configured to separate methane and l 'hydrogen. By membrane separation device 15 is meant in particular a separation device by membrane permeation.

The membrane separation (purification) device 15 comprises for example an outlet for gas enriched in methane and hydrogen connected to an inlet of the liquefier 5 for its liquefaction. The membrane separation device 15 includes another outlet for hydrogen-rich effluents connected to an inlet for the methane generating member 2. The first phase separator container 16 comprising a second liquid outlet connected to the inlet of a second phase separator container 26

The second phase separator container 26 comprises a gas outlet connected to the pipe 8 for transferring gas to the methane generating member 2 and a liquid outlet connected to the storage 7. Thus, after liquid / vapor separation at high pressure of the methane in the first container 16, the vapor is extracted and can then be reheated by a few degrees before entering a cold membrane 15 (to avoid condensation in the membrane 15). The low pressure part of the vapors (rich in H2) can return to recycling towards the reactor 2. The high pressure part of the vapors coming from the membrane 15 returns to the liquefier 5 (or an external cold source LN2) in order to be at again cooled, expanded and separated with the liquid coming from the first separator. The vapor (rich in H2) from the second container 26 can join that at the outlet of the membranes. The liquefier 5 may have an additional liquid outlet which is connected to the second container 26.

As before, the temperature at the outlet of the liquefier can be of the order of 110 to 120K (idem in the first container 16 or second container 26). The vapors can be reheated in the exchanger 14 between 115 and 125K.

Claims

1. Installation for producing liquefied methane comprising a circuit (10) comprising, arranged in series, a member (2) for generating methane from hydrogen and carbon dioxide such as a methanation reactor, a member ( 3) drying the gas mixture produced by the methane generating member (2), a purification member (4) configured to remove carbon dioxide from the dried gas mixture in the drying member (3), liquefier (5) configured to liquefy the methane contained in the mixture of purified gas in the purification member (4), and a storage

(7) of liquefied gas configured to store the methane liquefied by the liquefier (5), the installation being characterized in that it comprises a device (6) for hydrogen separation configured to remove at least part of the hydrogen from the fluid mixture produced by the liquefier (5) before it enters the repository (7), and in that the hydrogen separation device (6) comprises a first phase separator container (16) comprising a connected inlet to an outlet of the liquefier (5) to receive the mixture of fluid produced by the liquefier, and two outlets connected respectively to a line (10) for transferring liquid to the storage (7) and a line (18, 8) for transfer gas to the methane generating member (2).

2. Installation according to claim 1, characterized in that the purification member (4) comprises an adsorber with variation in pressure and temperature

(PTSA) comprising an outlet for effluent gases comprising methane and hydrogen, said outlet being connected, via a return pipe (11), to a power inlet of the methane generating member (2) for recycling there.

3. Installation according to claim 1 or 2, characterized in that the device (6) for hydrogen separation comprises an outlet for the separated gas mixture comprising methane and hydrogen, said outlet being connected via a pipe ( 8) recycling, at an entrance to the methane generating member (2) for recycling.

4. Installation according to claim 3, characterized in that the pipe (8) for recycling comprises a member (9) for heating the gas mixture before it enters the member (2) for generating methane.

5. Installation according to any one of claims 1 to 4, characterized in that the storage (7) is configured to contain liquefied methane in equilibrium with a gaseous mixture and in that the storage (7) comprises a pipe (8 ) gas evacuation connecting the gaseous part of the storage (7) to an inlet of the methane generating member (2).

6. Installation according to any one of claims 1 to 5, characterized in that the device (6) for hydrogen separation is connected to the outlet of the liquefier (5) via an expansion valve (12), the installation (1) being configured to cool the mixture of fluids leaving the liquefier (5) to a temperature lower than the equilibrium temperature of pure methane.

7. Installation according to any one of claims 1 to 6 or 7, characterized in that it comprises, arranged in series on the pipe (18, 8) for transferring gas to the member (2) for generating methane, a gas cooling member (13), in particular a heat exchanger cooled by a cold source and a second phase separator container (26) comprising an inlet connected to a gas outlet of the first container (16) phase separator and two outputs respectively connected to the pipe (10) for transferring liquid to the storage (7) and to the pipe (8, 18) for transferring gas to the methane generating member (2).

8. Installation according to any one of claims 1 to 6, characterized in that a first outlet from the first phase separator container (16) is connected, via a reheating heat exchanger (14) forming part of the installation, a membrane separation device (15) forming part of the installation configured to separate methane and hydrogen, the membrane separation device (15) comprising an outlet for gas enriched in methane and hydrogen connected to an inlet of the liquefier (5) for its liquefaction, and a hydrogen-rich effluent outlet connected to an inlet of the methane generating member (2), the first phase separator container (16) comprising a second liquid outlet connected to the storage (7) via a second phase separator container (26), that is to say that the second liquid outlet of the first phase separator container (6) is connected to the inlet of a second container (26) phase separator and the latter comprises an output connected to the storage (7).

9. Installation according to claim 8 characterized in that it comprises a pipe connecting a liquid outlet of the liquefier connected to an inlet of the second container (26) phase separator.

10. Method for producing liquefied methane from a production installation comprising, arranged in series in a circuit (10), a member (2) for generating methane from hydrogen and carbon dioxide such as a methanation reactor, a member (3) for drying the gas mixture produced by the methane generating member (2), a purification member (4) configured to remove carbon dioxide from the dried gas mixture in the drying member (3), a liquefier (5) configured to liquefy the methane contained in the mixture of purified gas in the purification member (4), and a storage (7) of liquefied gas configured to store the methane liquefied by the liquefier (5), the method comprising a step (6) of separation of hydrogen from the mixture of fluid produced by the liquefier before its transfer to the storage (7), the step of separation of hydrogen comprising at least one among: a separation the liquid / vapor phase is carried out in at least one separator container (16, 26), cooling of the fluid mixture (12), heating of the fluid mixture (13, 14), separation (15) by membranes.

11. The method of claim 10 or 11 characterized in that the hydrogen separation step is carried out at a cryogenic temperature after and / or during the liquefaction of methane.