CRYOGENIC TANK DEVICE WITH A BOIL-OFF MANAGEMENT SYSTEM

Abstract

A cryogenic tank apparatus having a first cryogenic tank having a first medium therein; a first boil-off conduit fluidically connected to the first cryogenic tank, the first boil-off conduit having a first boil-off valve; a first nozzle fluidically connected to the first boil-off conduit; a second cryogenic tank having the first medium therein; a second boil-off conduit fluidically connected to the second cryogenic tank; and a boil-off management system (BOMS) to receive flow of the first medium from the first cryogenic tank through the first nozzle, and flow of the first medium from the second cryogenic tank. The BOMS has a mixing chamber, a catalyst downstream of the mixing chamber, an outlet of downstream of the catalyst, and an air supply conduit through which flows a second medium, the mixing chamber being operable for mixing the first medium from the first cryogenic tank and the first medium from the second cryogenic tank with the second medium from the air supply conduit.

Claims

1. A cryogenic tank apparatus, comprising: a first cryogenic tank having a first medium therein; a first boil-off conduit fluidically connected to the first cryogenic tank, the first boil-off conduit having a first boil-off valve; a first nozzle fluidically connected to the first boil-off conduit; a second cryogenic tank having the first medium therein; a second boil-off conduit fluidically connected to the second cryogenic tank; and a boil-off management system (BOMS) to receive flow of the first medium from the first cryogenic tank through the first nozzle, and flow of the first medium from the second cryogenic tank, the BOMS having a mixing chamber, a catalyst downstream of the mixing chamber, an outlet of downstream of the catalyst, and an air supply conduit through which flows a second medium, the mixing chamber being operable for mixing the first medium from the first cryogenic tank and the first medium from the second cryogenic tank with the second medium from the air supply conduit.

2. The cryogenic tank apparatus of claim 1, wherein the first boil-off conduit and the second boil-off conduit are merged upstream of the first nozzle to form a common boil-off conduit, such that the first medium flowing in through the common boil-off conduit via the first nozzle is mixed with the second medium flowing in through the air supply conduit.

3. The cryogenic tank apparatus of claim 2, wherein the second boil-off conduit has a second boil-off valve, such that the first boil-off conduit and the second boil-off conduit are merged downstream of the first boil-off valve and the second boil-off valve to form the common boil-off conduit.

4. The cryogenic tank apparatus of claim 2, wherein the first boil-off conduit and the second boil-off conduit are merged upstream of the first boil-off valve to form the common boil-off conduit, such that the first boil-off valve constitutes a common boil-off valve for the first boil-off conduit and the second boil-off conduit.

5. The cryogenic tank apparatus of claim 1, wherein the second cryogenic tank comprises a second nozzle, such that the first medium flowing in through the second boil-off conduit via the second nozzle in the mixing chamber is mixed in the mixing chamber with the second medium.

6. The cryogenic tank apparatus of claim 1, wherein the first medium comprises hydrogen, and the second medium comprises air and/or oxygen.

7. A cryogenic tank apparatus, comprising: a first cryogenic tank having a first medium therein; a first boil-off conduit fluidically connected to the first cryogenic tank, a second cryogenic tank having the first medium therein; a second boil-off conduit fluidically connected to the second cryogenic tank; a common boil-off conduit formed from a merger of the first boil-off conduit and the second boil-off conduit; a nozzle fluidically connected to the common boil-off conduit; and a boil-off management system (BOMS) fluidically connected to the nozzle to receive flow of the first medium, the BOMS having a mixing chamber and an air supply conduit through which flows a second medium, the mixing chamber being operable for mixing the first medium with the second medium.

8. The cryogenic tank apparatus of claim 7, further comprising a nozzle fluidically connected to the common boil-off conduit and the boil-off management system to facilitate transfer of the first medium to the boil-off management system.

9. The cryogenic tank apparatus of claim 7, wherein the common boil-off conduit has a boil-off valve.

10. The cryogenic tank apparatus of claim 7, wherein the first medium comprises hydrogen, and the second medium comprises air and/or oxygen.

11. A cryogenic tank apparatus, comprising: a first cryogenic tank having a first medium therein; a first boil-off conduit fluidically connected to the first cryogenic tank, a second cryogenic tank having the first medium therein; a second boil-off conduit fluidically connected to the second cryogenic tank; a first nozzle fluidically connected to the first boil-off conduit; a second nozzle fluidically connected to the second boil-off conduit; and a boil-off management system (BOMS) fluidically connected to the first nozzle and the second nozzle to receive flows of the first medium from the first cryogenic tank and the second cryogenic tank, the BOMS having a mixing chamber and an air supply conduit through which flows a second medium, the mixing chamber being operable for mixing: the first medium from the first cryogenic tank with the second medium from the air supply conduit, and the first medium from the second cryogenic tank with the second medium from the air supply conduit.

12. The cryogenic tank apparatus of claim 11, further comprising a first nozzle fluidically connected to the first boil-off conduit and the boil-off management system to facilitate transfer of the first medium from the first cryogenic tank to the boil-off management system.

13. The cryogenic tank apparatus of claim 11, further comprising a second nozzle fluidically connected to the second boil-off conduit and the boil-off management system to facilitate transfer of the first medium from the second cryogenic tank to the boil-off management system.

14. The cryogenic tank apparatus of claim 11, further comprising: a first nozzle fluidically connected to the first boil-off conduit and the boil-off management system to facilitate transfer of the first medium from the first cryogenic tank to the boil-off management system, and a second nozzle fluidically connected to the second boil-off conduit and the boil-off management system to facilitate transfer of the first medium from the second cryogenic tank to the boil-off management system.

15. The cryogenic tank apparatus of claim 11, wherein the first boil-off conduit has a first boil-off valve.

16. The cryogenic tank apparatus of claim 11, wherein the second boil-off conduit has a second boil-off valve.

17. The cryogenic tank apparatus of claim 11, wherein: the first boil-off conduit has a first boil-off valve, and the second boil-off conduit has a second boil-off valve.

18. The cryogenic tank apparatus of claim 11, wherein the first medium comprises hydrogen, and the second medium comprises air.

19. The cryogenic tank apparatus of claim 11, wherein the first medium comprises hydrogen, and the second medium comprises oxygen.

20. The cryogenic tank apparatus of claim 11, wherein the first medium comprises hydrogen, and the second medium comprises air and oxygen.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0017] One or more embodiments of this disclosure will be illustrated by way of example in the drawings and explained in the description hereinbelow.

[0018] FIG. 1 is a schematic diagram of a cryogenic tank apparatus, in accordance with a first embodiment.

[0019] FIG. 2 is a schematic diagram of a cryogenic tank apparatus, in accordance with a second embodiment.

[0020] FIG. 3 is a schematic diagram of a cryogenic tank apparatus, in accordance with a third embodiment.

DESCRIPTION

[0021] FIG. 1 shows a cryogenic tank apparatus in accordance with one or more embodiments, comprising a first cryogenic tank 2 and a first boil-off conduit 3 which has a first boil-off valve 4 and is fluidically connected to the first cryogenic tank 2. In addition, the cryogenic tank apparatus comprises a BOMS 1, comprising, in a housing, a mixing chamber 5 for mixing of the medium, especially hydrogen, flowing in through the first boil-off conduit 3 via a first nozzle 6 in the mixing chamber 5, with the medium, especially air and/or oxygen, flowing in through an air supply conduit 7, and a catalyst 8 downstream of the mixing chamber 5, and an outlet 9 of the boil-off management system 1 downstream of the catalyst 8.

[0022] The cryogenic tank apparatus additionally comprises a second cryogenic tank 10 and a second boil-off conduit 11 fluidically connected to the second cryogenic tank 10. The mixing chamber 5 which is utilized for the first boil-off conduit 3 is also set up to mix the medium flowing in through the second boil-off conduit 11 with the medium flowing in through the air supply conduit 7, such that the same BOMS 1, with the mixing chamber 5, with the catalyst 8 downstream of the mixing chamber 5, and with the outlet 9 downstream of the catalyst 8, is used for both the first boil-off conduit 3 of the first cryogenic tank 2 and the second boil-off conduit 11 of the second cryogenic tank 10.

[0023] In FIGS. 2 and 3, the first boil-off conduit 3 and the second boil-off conduit 11 are merged upstream of the first nozzle 6 to form a common boil-off conduit 12, such that the medium flowing in through the common boil-off conduit 12 via the first nozzle 6 is mixed with the medium flowing in through the air supply conduit 7.

[0024] In the embodiment of FIG. 1, the first boil-off conduit 3 and the second boil-off conduit 11 are merged upstream of the first boil-off valve 4 to form the common boil-off conduit 12, such that the first boil-off valve 4 constitutes a common boil-off valve for the first boil-off conduit 3 and the second boil-off conduit 11.

[0025] In the embodiment of FIG. 2, the second boil-off conduit 11 fluidically connected to the second cryogenic tank 10 has a second boil-off valve 13, such that the first boil-off conduit 3 and the second boil-off conduit 11 are merged only downstream of the first boil-off valve 4 and the second boil-off valve 13 to form the common boil-off conduit 12.

[0026] In the embodiment of FIG. 3, the cryogenic tank apparatus for the second boil-off conduit 11 comprises a second nozzle 14, such that the medium flowing in through the second boil-off conduit 11 via the second nozzle 14 in the mixing chamber 5 is mixed in the mixing chamber 5 with the medium flowing in through the air supply conduit 7. Thus, the first nozzle 6 and the second nozzle 14 are used for injection of the hydrogen from two different cryogenic tanks, namely the first cryogenic tank 2 and the second cryogenic tank 10, into a common BOMS 1.

LIST OF REFERENCE SYMBOLS

[0027] 1 boil-off management system [0028] 2 first cryogenic tank [0029] 3 first boil-off conduit [0030] 4 first boil-off valve [0031] 5 mixing chamber [0032] 6 first nozzle [0033] 7 air supply conduit [0034] 8 catalyst [0035] 9 outlet [0036] 10 second cryogenic tank [0037] 11 second boil-off conduit [0038] 12 common boil-off conduit [0039] 13 second boil-off valve [0040] 14 second nozzle