WO2024256034A1 - Storage vessel assembly and method - Google Patents

Abstract

A storage vessel assembly (1) for supplying hydrogen at constant pressure to a fuel cell (32), the storage vessel assembly having: a storage vessel (2) for accommodating cryogenic hydrogen (H2), wherein the storage vessel (2) has a gas zone (7) and a liquid zone (8); an evaporator (24) for converting a liquid phase (LH2) of the hydrogen (H2) into a gaseous phase (GH2) of the hydrogen (H2); a liquid pump (15) for conveying the liquid phase (LH2) from the liquid zone (8) to the evaporator (24); a feed device (11) for feeding a mixture, which comprises a proportion of the liquid phase (LH2) conveyed by the liquid pump (15) and a proportion of the gaseous phase (GH2) converted by the evaporator (24), to the liquid zone (8) of the storage vessel (6); and a gas line (31) via which the evaporator (24) is fluidically connected to the feed device and to the fuel cell (32).

Description

Description

storage tank arrangement and method

The invention relates to a storage container arrangement for supplying a fuel cell with hydrogen at constant pressure and a method for operating such a storage container arrangement.

Storage tanks for liquid hydrogen have a liquid zone with liquid hydrogen and a gas zone with gaseous hydrogen arranged above the liquid zone. According to internal company knowledge, such a storage tank can have a pressure build-up circuit. Using such a pressure build-up circuit can cause a thermodynamic imbalance between the liquid hydrogen and the gaseous hydrogen due to superheated steam in the gas zone. Due to movements of the storage tank, particularly when it is used mobile, a mixture of the liquid hydrogen and the gaseous hydrogen within the storage tank can lead to a drop in pressure within the storage tank. However, a consumer such as a fuel cell requires an almost constant supply pressure, which cannot be guaranteed by such a pressure build-up circuit. This needs to be improved.

Against this background, it is an object of the present invention to provide an improved storage container arrangement.

Accordingly, a storage container arrangement for supplying a fuel cell with hydrogen at a constant pressure is proposed. The storage container arrangement comprises a storage container for holding a cryogenic hydrogen, the storage container having a gas zone and a liquid zone, an evaporator arranged outside the storage container for converting a liquid phase of the hydrogen into a gaseous phase of the hydrogen, a liquid pump for conveying the liquid phase from the liquid zone to the evaporator and a feed device for feeding a mixture which comprises a part of the liquid phase conveyed by the liquid pump and a part of the gaseous phase converted by the evaporator to the liquid zone. the storage container, and a gas line via which the evaporator is in fluid communication with the supply device and which establishes a fluid connection between the evaporator and the fuel cell.

By feeding the mixture comprising the liquid phase and the gaseous phase to the liquid zone with the aid of the feed device, it is possible to maintain a thermodynamic equilibrium within the storage container, even if the storage container is used for mobile applications in which the liquid phase can mix with the gaseous phase within the storage container. This prevents a drop in pressure within the storage container when the liquid phase mixes with the gaseous phase.

The storage container arrangement can also be referred to as a hydrogen storage container arrangement. Accordingly, the storage container can also be referred to as a hydrogen storage container. A phase boundary is preferably provided in the storage container between the gas zone and the liquid zone. The gas zone is characterized in particular by the fact that it can absorb the gaseous phase. The liquid zone is characterized in particular by the fact that it can absorb the liquid phase.

The liquid phase of the hydrogen is therefore located in the liquid zone within the storage container. The gaseous phase of the hydrogen is therefore located in the gas zone. The phase boundary separates the gaseous phase from the liquid phase. The gaseous phase is arranged above the liquid phase when viewed along a direction of gravity. The liquid phase is liquid hydrogen. Accordingly, the term "liquid phase" can be replaced with the term "liquid hydrogen" and vice versa. The gaseous phase is gaseous hydrogen. Accordingly, the term "gaseous phase" can be replaced with the term "gaseous hydrogen" and vice versa.

The evaporator is designed to evaporate the liquid phase fed to the evaporator with the help of the liquid pump. The liquid phase is converted into the gaseous phase. The evaporator can, for example, be operated electrically. The evaporator can be a heat exchanger or comprise a heat exchanger. The evaporator is arranged downstream of the liquid pump. The terms "downstream" and "upstream" are to be understood here with reference to a flow direction of the liquid phase from the liquid zone to the evaporator. The same applies to a flow direction of the gaseous phase from the evaporator to the liquid zone of the storage container.

A valve can be provided upstream of the liquid pump. The liquid pump can be in fluid communication with the liquid zone of the storage tank by means of a line. The aforementioned valve is provided in or on the line. The liquid pump is in particular a submersible pump. The liquid pump is immersed in the liquid phase. The liquid pump is in particular a cryopump or can be referred to as a cryopump. The liquid pump is in particular assigned a pump sump that can accommodate the liquid pump. Viewed along the direction of gravity, the liquid pump is preferably placed below the storage tank.

The aforementioned feed device is in particular a lower feed device or a first feed device. Accordingly, the storage container arrangement can also have an upper feed device or second feed device. Only the first feed device will be discussed below, which will be referred to below only as the feed device. The feed device is in particular tubular. The feed device is arranged inside the storage container. In particular, the feed device is immersed in the liquid phase. The feed device is thus placed in the liquid zone of the storage container.

The part of the liquid phase conveyed by the liquid pump is fed to the feed device downstream of the liquid pump and upstream of the evaporator. The part of the gaseous phase converted by the evaporator is fed to the feed device downstream of the evaporator. The liquid phase and the gaseous phase are mixed with one another before being fed to the storage container using the feed device. A mixing section or any mixer can be provided for this purpose. The gaseous phase converted by the evaporator is in particular superheated hydrogen vapor. In this case, "superheated vapor" is to be understood as vapor with a temperature above the boiling point. With the aid of the feed device, superheated hydrogen vapor is returned to the storage container downstream of the evaporator, in particular to the liquid zone of the storage container. The liquid phase is branched off into this return stream of superheated vapor downstream of the liquid pump and fed to the feed device. The liquid phase and the gaseous phase are mixed. This cools the gaseous phase. The pre-cooled mixture is then introduced into the liquid phase arranged inside the storage container via the feed device. The mixture is preferably gaseous. The mixture can also be a two-phase mixture and can therefore also be referred to as such. The mixture rises in the liquid phase in particular in the form of gas bubbles and then reaches the gas zone.

According to one embodiment, the storage container arrangement has a mixing section arranged upstream of the feed device for mixing the gaseous phase and the liquid phase to form the mixture.

The mixing section can have so-called vortex generators. Within the mixing section, the liquid phase is mixed with the gaseous phase. This cools the gaseous phase, which is preferably present as superheated steam.

According to a further embodiment, the mixing section is arranged outside the storage container.

This means in particular that the mixing section is placed outside both the gas zone and the liquid zone.

According to the invention, the storage container arrangement has a liquid line by means of which the liquid pump is in fluid connection with the evaporator. The mixing section is preferably in fluid communication with the liquid line. The liquid line connects the liquid pump to the evaporator. A line flows out of the liquid line, which preferably fluidically connects the liquid line to the mixing section.

According to a further embodiment, the storage container arrangement has a liquid valve for releasing and interrupting the fluid connection between the liquid line and the mixing section.

The liquid valve is placed in or on the line provided between the liquid line and the mixing section. The line can be shut off or opened using the liquid valve. The liquid valve can be controlled, for example, by a regulating and control unit of the storage tank arrangement. The liquid valve can be controlled, for example, based on sensor signals from a sensor system. The sensor system can have different temperature and/or pressure sensors. For example, pressure sensors of the sensor system are placed inside the storage tank. The liquid valve can be used to influence a volume flow of the liquid phase from the liquid line to the mixing section. Accordingly, any amount of the liquid phase can be mixed into the gaseous phase returned to the storage tank using the liquid valve.

According to the invention, the storage container arrangement has a gas line for establishing a fluid connection between the evaporator and the fuel cell. The mixing section is preferably in fluid connection with this gas line.

The gas line establishes a fluid connection between the evaporator and the fuel cell. The fuel cell can be part of the storage container arrangement. However, this is not absolutely necessary. For example, the gaseous phase of the fuel cell can be supplied at a temperature of, for example, 0 °C to 20 °C or from 5 °C to 50 °C at a pressure of 3.5 bar to 11 bar. A "fuel cell" is understood here to mean a galvanic cell which converts the chemical reaction energy of a continuously supplied hydrogen and an oxidizing agent, in this case oxygen, into electrical energy. With the help of the electrical energy obtained, an electric motor can be driven, for example. A line flows out of the gas line, which fluidically connects the gas line with the mixing section. The line flows out of the gas line downstream of the evaporator. The gas line can have a valve which is arranged upstream of the consumer. The valve can be controlled using the regulating and control unit.

According to a further embodiment, the storage container arrangement has a gas valve for releasing and interrupting the fluid connection between the gas line and the mixing section.

The gas valve is provided in particular in or on the previously mentioned line, which flows out of the gas line arranged between the evaporator and the consumer. The gas valve can be controlled using the regulating and control unit. The amount of gaseous phase fed to the mixing section can be controlled using the gas valve.

According to a further embodiment, the liquid pump is arranged outside the storage container.

In particular, this means that the liquid pump is placed outside both the gas zone and the liquid zone of the storage vessel.

According to a further embodiment, the feed device has a plurality of outlet nozzles opening into the liquid zone.

The number of outlet nozzles is arbitrary. With the help of the outlet nozzles, the mixture of the liquid phase and the gaseous phase can be injected into the liquid zone of the storage tank. The outlet nozzles are in particular gas outlet nozzles.

According to a further embodiment, the storage container arrangement has a pump sump in which the liquid pump is accommodated, wherein the pump sump is in fluid communication with the gas zone. A gas zone with the gaseous phase and a liquid zone with the liquid phase are preferably provided in the pump sump. A phase boundary is provided between the gas zone and the liquid zone within the pump sump. The liquid pump is immersed in the liquid phase. The gas zone of the pump sump is in fluid communication with the gas zone of the storage tank by means of a line. This allows vaporized hydrogen from the pump sump to be returned to the gas zone of the storage tank.

According to a further embodiment, the storage container arrangement has a further feed device for feeding a part of the liquid phase conveyed by the liquid pump to the gas zone.

The gas zone can be cooled using this feed device. The additional feed device can also be referred to as a second feed device or upper feed device. The additional feed device has a large number of outlet nozzles that open into the gas zone. The additional feed device is in fluid communication with the liquid line arranged between the liquid pump and the evaporator via a line. A valve for opening and shutting off the line and thus for activating and deactivating the additional feed device can be provided in or on the aforementioned line. The valve can be controlled using the regulating and control unit.

According to a further embodiment, the storage container arrangement has thermal conducting plates arranged within the storage container for heat transfer between the gas zone and the liquid zone and vice versa.

The thermal conducting plates are preferably made of a metal that conducts heat well. For example, the thermal conducting plates can be made of an aluminum alloy. The number of thermal conducting plates is arbitrary. The thermal conducting plates divide both the gas zone and the liquid zone into several sections. However, the thermal conducting plates are fluid-permeable. The thermal conducting plates can have openings or holes for this purpose. Both the gaseous phase and the liquid phase can pass through the thermal conducting plates. Optionally, the storage tank arrangement may include a buffer tank for gaseous hydrogen downstream of the evaporator in order to reduce pressure fluctuations that may arise, for example, from pulsations of the liquid pump.

Furthermore, a method for operating such a storage container arrangement is proposed. The storage container arrangement has a storage container for holding the cryogenic hydrogen, the storage container having a gas zone and a liquid zone. The method has the following steps: a) conveying a liquid phase of the cryogen from the liquid zone to an evaporator arranged outside the storage container, b) converting the liquid phase to a gaseous phase of the hydrogen with the aid of the evaporator and c) supplying a mixture which comprises a portion of the conveyed liquid phase and a portion of the converted gaseous phase to the liquid zone, and d) supplying the gaseous phase of the hydrogen to the fuel cell.

Step a) is preferably carried out with the aid of the aforementioned liquid pump. The liquid pump conveys the liquid phase from the liquid zone of the storage vessel to the evaporator. During step b), the liquid phase is evaporated to the gaseous phase with the aid of the evaporator. The gaseous phase is in particular superheated steam. During step c), the mixture of the liquid phase and the gaseous phase is produced and fed to the liquid zone of the storage vessel. Step c) is carried out with the aid of the lower feed device or first feed device.

According to one embodiment, the mixture is produced by mixing the liquid phase and the gaseous phase by means of a mixing section arranged outside the storage container.

With the help of the mixing section, the gaseous phase, which is in particular superheated steam, is cooled down with the help of the added liquid phase.

According to a further embodiment, a part of the extracted liquid phase is fed to the gas zone. For this purpose, the previously mentioned upper feed device or second feed device is used, which can feed a part of the liquid phase conveyed by the liquid pump to the gas zone of the storage container. This allows the gas zone to be cooled down.

In this case, "one" is not necessarily to be understood as being limited to just one element. Rather, several elements, such as two, three or more, can also be provided. Any other counting word used here is also not to be understood as meaning that a precise limitation to exactly the corresponding number of elements must be implemented. Rather, numerical deviations upwards and downwards are possible.

The embodiments and features described for the proposed storage container arrangement apply accordingly to the proposed method and vice versa.

Further possible implementations of the storage container arrangement and/or the method also include combinations of features or embodiments described above or below with regard to the exemplary embodiments that are not explicitly mentioned. The person skilled in the art will also add individual aspects as improvements or additions to the respective basic form of the storage container arrangement and/or the method.

Further advantageous embodiments of the storage container arrangement and/or the method are the subject of the subclaims and the exemplary embodiments of the storage container arrangement and/or the method described below. The storage container arrangement and/or the method are explained in more detail below using preferred embodiments with reference to the attached figures.

Fig. 1 shows a schematic sectional view of an embodiment of a

storage tank arrangement 1 ; and Fig. 2 shows a schematic block diagram of an embodiment of a method for operating the storage container arrangement according to Fig. 1 .

In the figures, identical or functionally equivalent elements have been given the same reference symbols unless otherwise stated.

Fig. 1 shows a schematic sectional view of an embodiment of a storage container arrangement 1.

The storage container arrangement 1 comprises a storage tank or storage container 2. The storage container 2 is suitable for holding hydrogen H2 (boiling point: 1 bara: 20.268 K = -252.882 °C). Therefore, the storage container 2 can also be referred to as a hydrogen storage container or a hydrogen storage tank.

The storage container 2 can be a transport container. For example, liquid hydrogen LH2 can be transported with the storage container 2. The storage container 2 can be part of a vehicle, in particular a watercraft. In this case, the storage container 2 is suitable for mobile applications. However, the storage container 2 can also be used stationary, for example in building technology.

The storage container 2 is constructed rotationally symmetrically to a symmetry or central axis 3. The central axis 3 is oriented perpendicular to a direction of gravity g. The storage container 2 is double-walled and comprises a first container or inner container, which is also constructed rotationally symmetrically to the central axis 3. The inner container is arranged completely within a second container or outer container. The outer container is also constructed rotationally symmetrically to the central axis 3. The inner container and the outer container are made of stainless steel.

Between the inner container and the outer container, a gap is provided that completely surrounds or envelops the inner container. The gap is subjected to a vacuum. In the present case, a "vacuum" is understood to mean in particular a pressure of less than 300 mbar, preferably less than 10 ^-3 mbar, more preferably less than 10 ^-7 mbar. The storage tank 2 is thus vacuum-insulated or vacuum-insulated.

The storage container 2 comprises a tubular or cylindrical base section 4, which is also constructed rotationally symmetrically to the central axis 3. The base section 4 can have a circular or almost circular geometry in cross section. The base section 4 is double-walled. The base section 4 is closed on both sides at the front with the aid of a cover section 5, 6. The cover sections 5, 6 are curved. A first cover section 5 and a second cover section 6 are curved in opposite directions, so that the cover sections 5, 6 are curved outwards with respect to the base section 4.

The liquid hydrogen LH2 is accommodated in the storage container 2, in particular in the inner container. As long as the hydrogen H2 is in the two-phase region, a gas zone 7 with vaporized hydrogen GH2 and a liquid zone 8 with liquid hydrogen LH2 can be provided in the storage container 2. After being filled into the storage container 2, the hydrogen H2 therefore has two phases with different states of aggregation, namely liquid and gaseous. This means that in the storage container 2 there is a phase boundary 9 between the liquid hydrogen LH2 and the gaseous hydrogen GH2.

Several thermal conducting plates 10 are arranged inside the storage container 2, only one of which is provided with a reference symbol. The number of thermal conducting plates 10 is arbitrary. For example, seven thermal conducting plates 10 are provided. Viewed along the central axis 3, the thermal conducting plates 10 are positioned at a distance from one another. The thermal conducting plates 10 run perpendicular to the central axis 3. The thermal conducting plates 10 divide both the gas zone 7 and the liquid zone 8 into several sections. However, the thermal conducting plates 10 are fluid-permeable, so that both the gaseous hydrogen GH2 and the liquid hydrogen LH2 can flow through the thermal conducting plates 10. For this purpose, the thermal conducting plates 10 can have breakthroughs or openings through which the gaseous hydrogen GH2 and the liquid hydrogen LH2 can pass. The storage container 2 has a plurality of distributor pipes or feed devices 11, 12. A lower feed device 11, which is arranged below the phase boundary 9 in the liquid hydrogen LH2, and an upper feed device 12, which is arranged above the phase boundary 9 in the gaseous hydrogen GH2, can be provided. The lower feed device 11 has outlet nozzles 13, with the aid of which gaseous hydrogen GH2 and/or liquid hydrogen LH2 can be fed to the storage container 2 below the phase boundary 9. The upper feed device 12 has outlet nozzles 14, with the aid of which liquid hydrogen LH2 can be fed to the storage container 2 above the phase boundary 9.

The storage container arrangement 1 further comprises a liquid pump 15, which is in fluid communication with the storage container 2 by means of a line 16. The line 16 flows out of the storage container 2 below the phase boundary 9. Liquid hydrogen LH2 can be supplied to the liquid pump 15 via the line 16. A valve 17 is provided in or on the line 16. The line 16 can be closed or opened using the valve 17.

The liquid pump 15 is assigned a pump sump 18. The liquid pump 15 is placed inside the pump sump 18. The pump sump 18 is filled with hydrogen H2. A gas zone 19 with gaseous hydrogen GH2 and a liquid zone 20 with liquid hydrogen LH2 are provided inside the pump sump 18. The liquid pump 15 is immersed in the liquid hydrogen LH2. A phase boundary 21 is provided between the gas zone 19 and the liquid zone 20.

Above the phase boundary 21, i.e. from the gas zone 19 of the pump sump 18, a line 22 emerges from the pump sump 18, which leads to the storage tank 2 and opens into the gas zone 7 of the storage tank 2. With the help of the line 22, gaseous hydrogen GH2 from the gas zone 19 of the pump sump 18 can be supplied to the gas zone 7 of the storage tank 2.

With the help of a liquid line 23, the liquid pump 15 can supply liquid hydrogen LH2 to an evaporator 24. Between the liquid pump 15 and the evaporator 24, a line 25 branches off from the liquid line 23. The line 25 leads to a line 26. In or on the line 25, a liquid valve is 21 is provided, with the aid of which the line 25 can be opened and closed. The line 26 is connected to the lower feed device 11 by means of a mixing section 28, which can have vortex generators. Downstream of the line 25, a further line 29 flows out of the liquid line 23. The line 29 is connected to the upper feed device 12. A valve 30 for opening and closing the line 29 is provided in or on the line 29.

The evaporator 24 can evaporate the liquid hydrogen LH2 to gaseous hydrogen GH2. The gaseous hydrogen GH2 is supplied to a fuel cell 32 with the aid of a gas line 31. For example, the gaseous hydrogen GH2 can be supplied to the fuel cell 32 at a temperature of, for example, 0 °C to 20 °C or from 5 °C to 50 °C at a pressure of 3.5 bar to 11 bar.

A "fuel cell" is understood here to mean a galvanic cell which converts the chemical reaction energy of a continuously supplied fuel, in this case hydrogen H2, and an oxidizing agent, in this case oxygen, into electrical energy. The electrical energy obtained can be used, for example, to drive an electric motor (not shown).

A valve 33 is provided on or in the gas line 31, with the aid of which the gas line 31 can be opened and closed. A line 34 emerges from the gas line 31 in front of the valve 33. The line 34 is connected to the line 26. A gas valve 35 is provided in or on the line 34, with the aid of which the line 34 can be opened and closed.

The storage container arrangement 1 further comprises a control unit 36 for controlling the liquid pump 15, the valves 17, 27, 30, 33, 35 and the evaporator 24. For this purpose, an operative connection can be provided between the control unit 36 and the liquid pump 15, the valves 17, 27, 30, 33, 35 and the evaporator 24. The operative connection can be wired or wireless. For example, the control unit 36 can switch the liquid pump 15 and the evaporator 24 on and off. Furthermore, the control unit 36 can open and close the valves 17, 27, 30, 33, 35. The control unit 36 can comprise a computer. In the A program for operating the storage container arrangement 1 can be stored in the control unit 36.

The regulating and control unit 36 can control the liquid pump 15, the valves 17, 27, 30, 33, 35 and the evaporator 24 based on sensor signals from a sensor system 37. The sensor system 37 can comprise several sensors, for example pressure sensors, temperature sensors or the like. The sensor system 37 or at least part of the sensor system 37 can be placed inside the storage container 2.

According to internal company knowledge, hydrogen storage containers used to date can have a pressure build-up circuit. By using such a pressure build-up circuit, a thermodynamic imbalance between the liquid hydrogen LH2 and the gaseous hydrogen GH2 can arise due to superheated steam in the gas zone. Due to movements of the storage container, in particular when it is used mobile, a mixture of the liquid hydrogen LH2 and the gaseous hydrogen GH2 within the storage container can lead to a drop in pressure within the storage container. However, the previously mentioned fuel cell 32 requires an almost constant supply pressure, which cannot be guaranteed by such a pressure build-up circuit. This disadvantage is remedied by the storage container arrangement 1 explained above.

In the storage tank arrangement 1, the pressure build-up for the consumer 32 takes place with the aid of the liquid pump 15 and the evaporator 24. With the aid of the liquid pump 15, liquid hydrogen LH2 is taken from the storage tank 2, fed to the evaporator 24 and then converted into gaseous hydrogen GH2 in the consumer 32.

During operation of the liquid pump 15, the gas valve 35 can be opened. This feeds superheated gaseous hydrogen GH2 to the mixing section 28. Pressurized liquid hydrogen LH2 is added to this gaseous hydrogen GH2 by opening the liquid valve 27. A mixture comprising gaseous hydrogen GH2 and liquid hydrogen LH2 is produced in the mixing section 28. The mixture can be a two-phase mixture and can therefore also be referred to as such. This pre-cooled mixture is fed to the Liquid zone 8 of the storage tank 2 with the aid of the lower feed device 11. This allows the thermal equilibrium to be maintained during a pressure build-up process in the storage tank 2.

In particular, superheated hydrogen vapor is returned to the liquid zone 8 of the storage tank 2 by means of the lower feed device 11, the lines 26, 34 and the gas valve 35 downstream of the evaporator 24. As previously mentioned, liquid hydrogen LH2, which comes from the liquid pump 15, is mixed into this return stream via the line 25 and the liquid valve 27.

In the mixing section 28, the gaseous hydrogen GH2 and the liquid hydrogen LH2 are thoroughly mixed, for example with the aid of a vortex generator as mentioned above. The hydrogen H2 leaves the mixing section 28 as a mixture, in particular as a two-phase mixture, comprising gaseous hydrogen GH2 and liquid hydrogen LH2. The pre-cooled mixture is fed to the liquid zone 8 via the lower feed device 11.

In support of this, by opening the valve 30, pressurized and liquid hydrogen LH2 can be dispersed via the upper feed device 12 into the gas zone 7 of the storage container 2 in order to additionally stabilize the thermodynamic equilibrium within the storage container 2.

The additional introduction of the thermal conducting plates 10 prevents the heating of the gaseous hydrogen GH2 in the gas zone 7 above the saturation temperature. A submersible pump can be used as the liquid pump 15, which is completely surrounded by the liquid hydrogen LH2 to be pumped in the separate pump sump 18. When the liquid pump 15 is in operation, liquid hydrogen LH2 evaporates in the pump sump 18. The resulting gaseous hydrogen GH2 is introduced into the gas zone 7 of the storage tank 2 via the line 22.

Optionally, a buffer tank for gaseous hydrogen GH2 can be integrated downstream of the evaporator 24 in order to further minimize pressure fluctuations that can arise, for example, due to pulsations of the liquid pump 15. With the help of the storage container arrangement 1, reliable operation of the consumer 32 is thus possible. This results in a constant state of equilibrium and thus controllable conditions within the storage container 2, even when the storage container 2 moves, for example in a mobile application of the storage container arrangement 1.

Fig. 2 shows a schematic block diagram of an embodiment of a method for operating the storage container arrangement 1.

In the method, in a step S1, the liquid hydrogen LH2 is conveyed from the liquid zone 8 of the storage container 2 to the evaporator 24. In a step S2, the liquid hydrogen LH2 is converted, in particular evaporated, into gaseous hydrogen GH2 with the aid of the evaporator 24. In a step S3, the mixture, which comprises a portion of the conveyed liquid hydrogen LH2 and a portion of the converted gaseous hydrogen GH2, is fed to the liquid zone 8. Gaseous hydrogen GH2 is fed to the fuel cell 32 at a nearly constant pressure via the gas line 31.

In particular, the mixture is produced by mixing the liquid hydrogen LH2 and the gaseous hydrogen GH2 with the aid of the mixing section 28 arranged outside the storage container 2. In addition, a portion of the liquid hydrogen LH2 conveyed can be fed to the gas zone 7 of the storage container 2.

Although the present invention has been described using exemplary embodiments, it can be modified in many ways.

Reference symbols used

1 storage tank arrangement

2 storage tanks

3 central axis

4 base section

5 lid section

6 lid section

7 Gaszone

8 liquid zone

9 phase boundary

10 thermal conducting plate

11 feeding device

12 feeding device

13 outlet nozzle

14 outlet nozzle

15 fluid pump

16 lines

17 valve

18 pump sump

19 Gaszone

20 liquid zone

21 phase boundary

22 lines

23 liquid line

24 evaporators

25 lines

26 lines

27 liquid valve

28 mixing sections

29 lines

30 valve

31 gas pipeline

32 consumers

33 valve 34 lines

35 gas valve

36 control unit

37 Sensors g Gravity direction

GH2 hydrogen

H2 hydrogen

LH2 Hydrogen S1 Step

52 steps

53 steps

Claims

patent claims 1. Storage container arrangement (1) for supplying a fuel cell (32) with hydrogen at constant pressure, comprising: a storage container (2) for receiving a cryogenic hydrogen (H2), the storage container (2) having a gas zone (7) and a liquid zone (8), - an evaporator (24) arranged outside the storage tank (2) for converting a liquid phase (LH2) of the hydrogen (H2) into a gaseous phase (GH2) of the hydrogen (H2), a liquid pump (15) for conveying the liquid phase (LH2) from the liquid zone (8) of the storage tank (2) via a liquid line (23) to the evaporator (24), a feed device (11) for feeding a mixture which comprises a part of the liquid phase (LH2) conveyed by the liquid pump (15) and a part of the gaseous phase (GH2) converted by the evaporator (24) to the liquid zone (8) of the storage tank (2), and - a gas line (31) via which the evaporator (24) is in fluid communication with the supply device (11) and which establishes a fluid connection between the evaporator (24) and the fuel cell (32). 2. Storage container arrangement according to claim 1, further comprising a mixing section (28) arranged upstream of the feed device (11) for mixing the gaseous phase (GH2) and the liquid phase (LH2) to form the mixture. 3. Storage container arrangement according to claim 2, wherein the mixing section (28) is arranged outside the storage container (2). 4. Storage container arrangement according to claim 2 or 3, wherein the mixing section (28) is in fluid communication with the liquid line (23). 5. Storage container arrangement according to claim 4, further comprising a liquid valve (27) for releasing and interrupting the fluid connection between the liquid line (23) and the mixing section (28). 6. Storage container arrangement according to claim 4 or 5, wherein the mixing section (28) is in fluid communication with the gas line (31). 7. Storage container arrangement according to claim 6, further comprising a gas valve (35) for releasing and interrupting the fluid connection between the gas line (31) and the mixing section (28). 8. Storage tank arrangement according to one of claims 1 - 7, wherein the liquid pump (15) is arranged outside the storage tank (2). 9. Storage container arrangement according to one of claims 1 - 8, wherein the feed device (11) has a plurality of outlet nozzles (13) opening into the liquid zone (8). 10. Storage tank arrangement according to one of claims 1 - 9, further comprising a pump sump (18) in which the liquid pump (15) is accommodated, the pump sump (18) being in fluid communication with the gas zone (7). 11. Storage container arrangement according to one of claims 1 - 10, further comprising a further feed device (12) for feeding a part of the liquid phase (LH2) conveyed by the liquid pump (15) to the gas zone (7). 12. Storage container arrangement according to one of claims 1 - 11, further comprising thermally conductive plates (10) arranged within the storage container (2) for heat transfer between the gas zone (7) and the liquid zone (8) and vice versa. 13. A method for operating a storage container arrangement (1) for supplying a fuel cell (32) with hydrogen at a constant pressure, wherein the storage container arrangement (1) has a storage container (2) for receiving a cryogenic hydrogen (H2), wherein the storage container (2) has a gas zone (7) and a liquid zone (8), and wherein the method comprises the following steps: a) conveying (S1) a liquid phase (LH2) of the hydrogen (H2) from the liquid zone (8) to an evaporator (24) arranged outside the storage vessel (2), b) converting (S2) the liquid phase (LH2) of the hydrogen to a gaseous phase (GH2) of the hydrogen (H2) with the aid of the evaporator (24), and c) supplying (S3) a mixture comprising a part of the conveyed liquid phase (LH2) and a part of the converted gaseous phase (GH2) to the liquid zone (8) of the storage vessel (2), and d) supplying the gaseous phase (GH2) of the hydrogen to the fuel cell (32). 14. The method according to claim 13, wherein the mixture is produced by mixing the liquid phase (LH2) and the gaseous phase (GH2) by means of a mixing section (28) arranged outside the storage container (2). 15. The method according to claim 13 or 14, wherein the gaseous phase converted by the evaporator (24) is superheated hydrogen vapor.