The present application claims priority under 35 U.S.C. § 119 to European Patent Publication No. EP 22173969.1 (filed on May 18, 2022), which is hereby incorporated by reference in its entirety.
Embodiments relate to a cryogenic tank comprising an inner container for holding a cryogenic medium, in particular hydrogen, and an outer container surrounding the inner container.
Cryogenic tanks are known per se and are used for storing cryogenic liquids, in particular liquid hydrogen. In particular, the medium can be used as a fuel for a driven or flying means of transport, for example for a motor vehicle, an aircraft or a space rocket. Cryogenic tanks usually have an inner container, in which the medium stored in the tank, that is to say in particular the hydrogen, is held, and an outer container surrounding the inner container. A vacuum is usually set up between the inner container and the outer container in order to reduce heat transfer from the outside to the inside. Such cryogenic tanks can be cylindrical.
Necessary functional components of such a cryogenic tank, such as valves, control components and tubes, are arranged, for example, on the end of the cryogenic tank, outside the outer container or in the vacuum space between the outer container and the inner container. When the functional components are arranged on the end, it is usually necessary to shorten the axial length of the cryogenic tank, at least of the inner container, and therefore less volume is available for the storage of the medium.
It is an object of the disclosure to specify a cryogenic tank which, despite the installation of functional components, has an inner container volume which is as large as possible, given a predetermined installation space.
The object is achieved by a cryogenic tank comprising an inner container for holding a cryogenic medium, in particular hydrogen, and an outer container surrounding the inner container, wherein a vacuum space is set up between the inner container and the outer container, wherein a pocket extends at least from the vacuum space into the interior space of the inner container, wherein one or more functional components are arranged in the pocket, such as one or more heat exchangers, valves, control components and/or tubes.
According to the disclosure, a cryogenic tank thus has at least one pocket, that is to say a pocket-like depression or hollow, with a bottom at the end of the pocket, that is to say within the usual volume of the inner container. The pocket therefore extends from outside the inner container, i.e., at least from the vacuum space, optionally also from the outer container or from outside the outer container, into the usual geometry of the inner container, in order to delimit a volume which usually belongs to the interior space of the inner container and, as part of the interior space of the pocket, to make it topologically an outer space of the inner container. Here, the interior space of the pocket is accessible from outside the inner container, preferably from the vacuum space. In this case, the diameter of the pocket is smaller than the diameter of the inner container at the point at which the pocket extends into the inner container. As a result, less volume of the inner container is lost than if the entire inner container, over its entire diameter, were shortened.
Functional components are arranged in the pocket. The functional components can be, in particular, auxiliary system components. The functional components can thus also be arranged within the usual interior space of the inner container and are separated and protected there from the medium in the inner container by the boundary wall of the pocket.
The displaced volume of a pocket extending into the inner container for accommodating the required components is smaller than in the case of a reduction in the length of the entire cylinder of the inner container.
Further developments of the disclosure are specified in the dependent claims, the description and the attached drawings.
The pocket is preferably formed at least in some section or sections by a jacket tube which extends into the interior space of the inner container. The pocket is preferably cylindrical at least in some section or sections. The pocket is closed at its end, i.e. it preferably has a bottom at the end of the cylinder.
The pocket is preferably closed by a cover, in particular with respect to the vacuum space or with respect to the outside of the outer container. The cover is preferably a separate component.
Preferably, at least one pipe leads from outside the pocket to a functional component arranged in the pocket, preferably at least two or at least four pipes. The pipe can be set up to carry the medium stored in the cryogenic tank or a temperature control fluid or coolant to the functional component or away from it. Preferably, at least four pipes lead from outside the pocket to a functional component arranged in the pocket, in particular to a heat exchanger arranged in the pocket. In this case, at least one pipe can be set up for the supply and one pipe can be set up for the discharge of the cryogenic medium held in the inner container, and at least one pipe can be set up for the supply and one pipe can be set up for the discharge of a temperature control fluid. The heat exchanger thus serves to control the temperature of the cryogenic medium, in particular hydrogen, held in the inner container, this medium being guided from a region outside the pocket and preferably from a region outside the inner container into the pocket for temperature control there.
The cryogenic medium, in particular hydrogen, held in the inner container is preferably supplied to a functional component in the pocket through a pipe from the outside of the inner container, from the vacuum space or from the space outside the outer container, particularly preferably through the cover of the pocket.
At least one pipe, preferably all the pipes, which leads/lead from outside the pocket to a functional component arranged in the pocket, is/are preferably passed through an opening in the cover of the pocket, preferably being passed through an opening, assigned to the respective pipe, in the cover of the pocket.
The pocket is preferably aligned parallel to the longitudinal central axis of the cryogenic tank or is aligned so as to be normal to the longitudinal central axis of the cryogenic tank.
The pocket preferably extends inwards from an end cap at the end of the inner container, or from a lateral surface of the inner container, preferably in the direction of a central point of the inner container.
As a particular preference, the pocket is arranged coaxially with the longitudinal central axis of the cryogenic tank.
As a particular preference, the pocket extends as far as the outer container. The pocket can be designed for suspension of the inner container on the outer container. The pocket can form a polar suspension of the inner container on the outer container.
At least one functional component is preferably arranged in the pocket in such a way that the functional component extends substantially parallel to a side wall of the pocket. In particular, at least one, preferably cylindrical or rod-shaped, heat exchanger and/or at least one tube can run parallel to the pocket or parallel to the side walls of the pocket.
The pocket preferably has thermal insulation for protecting the functional components arranged in the pocket, in particular multi-layer insulation (MLI).
Embodiments will be illustrated by way of example in the drawings and explained in the description hereinbelow.
The cryogenic tank comprises an inner container 1 for holding a cryogenic medium, in particular hydrogen, and an outer container 2 surrounding the inner container 1, wherein a vacuum space 3 is set up between the inner container 1 and the outer container 2. In addition, container insulation 11 is applied to the outside of the inner container 1 (illustrated in
The inner container 1 comprises a lateral surface 1.1 of the inner container 1 and an end cap 1.2 on the end of the inner container 1.
A pocket 4 extends from the vacuum space 3 into the interior space of the inner container 1, thus forming a hollow in the volume normally enclosed by the inner container 1, which in the example shown essentially forms a cylinder with convex ends.
At least one functional component 5, namely a heat exchanger 6, is arranged in the pocket 4. The heat exchanger 6 is arranged within a spatial region which is usually located in the interior space of the inner container but which is separated by the pocket 4 from the medium in the interior space. The pocket 4 is substantially cylindrical. The diameter of the pocket 4 is smaller than the diameter of the inner container 1, preferably smaller than half the diameter of the inner container 1.
The pocket 4 is formed in some section or sections by a cylindrical sleeve, namely a jacket tube 8, which extends into the interior space of the inner container 1. The jacket tube 8 has a bottom, which can be formed as a separate component or integrally with the jacket tube 8.
The pocket 4 is closed by a cover 9 with respect to the vacuum space 3.
The pocket 4 is aligned parallel to the longitudinal central axis of the cryogenic tank, namely coaxially with the longitudinal central axis of the cryogenic tank. The pocket 4 extends inwards from an end cap 1.2 at the end of the inner container 1 in the direction of a central point of the inner container 1.
The cryogenic medium, in particular hydrogen, held in the inner container 1 is supplied to the heat exchanger 6 in the pocket 4 through a pipe 10 from the outside of the inner container 1, namely through the pipe 10 in the vacuum space 3 and through an opening in the cover 9 of the pocket 4.
A further pipe 10 serves for discharge of the cryogenic medium held in the inner container 1. In addition, two pipes 10 from outside the pocket 4 are set up for supplying and discharging a temperature control fluid or cooling medium.
All the pipes 10 are passed through openings in the cover 9 of the pocket 4 which are assigned to the respective pipe 10.
The pocket 4, in particular the jacket tube 8, has thermal insulation for protecting the functional components 5 arranged in the pocket 4, in particular the heat exchanger 6, in particular, multi-layer insulation (MLI).
The terms “coupled,” “attached,” or “connected” may be used herein to refer to any type of relationship, direct or indirect, between the components in question, and may apply to electrical, mechanical, fluid, optical, electromagnetic, electromechanical or other connections. In addition, the terms “first,” “second,” etc. are used herein only to facilitate discussion, and carry no particular temporal or chronological significance unless otherwise indicated.
Those skilled in the art will appreciate from the foregoing description that the broad techniques of the embodiments can be implemented in a variety of forms. Therefore, while the embodiments have been described in connection with particular examples thereof, the true scope of the embodiments should not be so limited since other modifications will become apparent to the skilled practitioner upon a study of the drawings, specification, and following claims.
Number | Date | Country | Kind |
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22173969.1 | May 2022 | EP | regional |