DE102007021875A1 - Container system such as cryotanks for storage of low-cold hydrogen in motor vehicle, has vacuum isolation covering, which is provided between inner container and outer container surrounding inner container in spaced manner - Google Patents

Abstract

The container system has a vacuum isolation covering, which is provided between an inner container and an outer container surrounding the inner container in spaced manner. An evacuation opening such as evacuation flange (1) is assigned to the wall of the outer container. An exclusion zone of an overflow opening for evacuation flange and an overflow opening (7) closed by a regular rupture disk (8) are connected to the evacuation flange and is connected with a fluid filled testing chamber (6). The pressure of the fluid in the test space is monitored by a pressure measuring device (11).

Description

The The invention relates to a container system with a vacuum insulation cover, between an inner container and a by far enclosing this Outer container provided is, with an evacuation opening in the wall of the outer container, the a so-called evacuation flange is assigned, when ready for operation container system is closed by means of a sealing plug. Such a container system is, for example, in the form of a so-called. Kryotanks for storing tiefkaltem Hydrogen in a motor vehicle as an energy source for combustion in one Vehicle drive unit or an aggregate for generating in particular electrical Auxiliary power known and used in the vehicle "Hydrogen 7" of the applicant.

The a storage medium, for example, cryogenic hydrogen, receiving inner container across from The surrounding vacuum does not just have to be created for the first time but should be able to be renewed if necessary, which is why in the vacuum basically upright receiving outer container one evacuation opening is provided. This is usually sealed by means of a sealing plug, which is usually designed as a simple stopper is in one provided on the wall of the outer container and the evacuation opening surrounding evacuation flange is inserted and opposite this or in general to the Wall of the outer container by means of O-rings is sealed off towards the vacuum. For pumping the vacuum At the Evakuierungsflansch a suction line or as a lock acting device through which the sealing plug pulled and the evacuation opening can be exposed and over which after evacuation of the vacuum insulation sheath the evacuation opening can be closed again by the sealing plug. One Such evacuation plug also serves as overpressure protection in the case that in the vacuum insulation sleeve or in the corresponding vacuum space an overpressure occurs. Then it will be the stopper by the overpressure forced out and thus the vacuum space of the overpressure relieved.

A exam the tightness of the sealing plug is following an evacuation the vacuum insulation cover only limited possible and while the ongoing operation of the container system at all Not. But a leak on the vacuum stopper would lead to a reduction of the Vacuum and thus ultimately to the collapse of the heat insulation to lead, what a high heat input in the inner container would result so that the deep cryogenic fluid stored in it accelerates would evaporate. The associated increase in pressure would trigger a safety device, eg lead a safety valve, with the consequence that big Quantities of gaseous Storage medium would enter the environment. Is such a container system installed in a motor vehicle and would this motor vehicle in a closed room, for example a garage, so would in the case of a break in the vacuum between the outer container and inner container practically all of the inner container of the container system stored gas in this room, which is usually not is designed to safely absorb this amount of gas.

A Countermeasure for this To illustrate the problem described is the task of the present Invention.

The solution this task is for a container system according to the preamble of claim 1, characterized in that to the Evakuierungsflansch with the exception of a transfer opening to Evacuation flange and a regular by means of a rupture disc or the like. Closed overflow closed and filled with a fluid testing room connects, the pressure of the fluid in the test room can be monitored by means of a pressure measuring device. advantageous Training and further education are content of the dependent claims.

Around to prevent a collapse of the vacuum in the vacuum insulation sheath or at least take timely action against it to be able to It is proposed that the evacuation opening another barrier in the form of a rupture disk or the like. Vorzualten. This concludes to the evacuation opening pressure tight a closed space (= so-called. Test room), in the wall or walls at least one so-called overflow opening which ultimately opens in the surroundings is that in the regular Operation of a rupture disc or the like. Closed. there lies in this said enclosed space, here referred to as the test room is a significantly higher Pressure as in the vacuum insulation sheath of the container system and preferably a pressure different from the ambient pressure. This pressure in the test room can be monitored by means of a suitable sensor (= pressure measuring device) become. Preferably, this pressure is by filling the test room with made of a suitable gas or fluid in general later Move even closer will be received. Of course this room shows next to the (or the) above-mentioned overflow opening (s) one more crossing opening to the evacuation flange or to a channel within it, so that the test room ultimately connected to the closed by said vacuum stopper evacuation is.

Should said closure plug cause a slight leakage to the vacuum insulation cover or have, so flows the gas or fluid from the test room at least proportionally in the vacuum insulation sheath of the container system and it becomes the pressure in the test room significantly reduced, the rupture disc designed in such a way is that these high suppression or a near-vacuum in the test room can withstand. This pressure reduction in the test room can then by means of Sensor or said pressure measuring device are detected, whereupon a corresponding reference, for example, to the user of the container system or the motor vehicle having this, which thereupon a suitable measure - on which not closer at this point to enter is - to initiate can. When or by the pressure in the test room in the normal state of a container system according to the invention differs from the ambient pressure, so by means of the pressure measuring device advantageously also a leak of the test room towards the surroundings.

Just in the extremely unlikely and actually only theoretically possible Special case that in case of a due to a pressure change in the test room recognizable disorder Firstly, no suitable measure (see previous paragraph) and that at the same time said rupture disk in turn is not absolutely tight or the test room not absolutely close to each other the environment is complete, theoretically the Vacuum in the vacuum insulation sleeve be further reduced and thus the case described above occur that in the inner container of the container system stored fluid so far heated that the resulting increase in pressure a safety device brings to the response and then gaseous storage medium in the Environment. The probability of this case occurring but should be so low that a parking one with a such container system provided motor vehicle in a garage would have to be possible.

Preferably is the fluid with which the test chamber is filled, selected so that with an influx same in the vacuum insulation sheath only a low energy input into this vacuum takes place or that this vacuum only minimally weakened becomes. For example, fulfill Ammonia or sulfur hexafluoride these conditions. This is the effects on the vacuum insulation cover despite noticeable pressure drop in the test room minimally, so that sufficient time remains, a suitable measure (cf. above). It is also advantageous if the said fluid when exiting the test room (eg in the area of the evacuation flange or the rupture disc mentioned) is easily detectable, since an existing in each area Leakage can then be easily determined. Furthermore, a the test room including so-called subcasing in the area of the connection to the evacuation flange in the manner of a for generating the vacuum between outer container and inner container the evacuation flange to be connected suction line or lock trained and thus easily adapted to the existing flange geometry be.

The attached schematic diagram shows a preferred embodiment of the invention, wherein in this section, neither a conventional inner container nor in its basic structure as usual designed outer container is shown, but on the left side in the figure, only one connected to an evacuation opening in the wall of the outer container Evakuierungsflansch 1 in which is connected with a vacuum insulation sheath between the outer container and inner container channel-shaped central interior 2 the same vacuum as in said vacuum insulation sheath is present. Outwardly, this interior is 2 (And thus also the vacuum insulation sheath) by a in the Evakuierungsflansch 1 inserted stopper 3 which is suitable with O-rings 4 is complete.

To the free end of the evacuation flange 1 is under the interposition of a seal 13 and by means of a suitable clamping device 14 the inlet flange 5a a so-called auxiliary housing 5 connected, the interior of which or the so-called. Test room 6 forms, which is filled with a gaseous fluid. About the channel-shaped center of the inlet flange 5a is the test room 6 thus with the channel-shaped center of the Evakuierungsflansches 1 in which the stopper is 3 is connected. The auxiliary housing 5 also has an overflow opening which ultimately opens in the surroundings 7 on top of that, from a rupture disk 8th is closed. This rupture disk 8th is designed and arranged so that it withstands a vacuum (compared to ambient pressure), however, ruptures at significant pressure and thus a connection between the test room 6 and the environment allows, for which here additionally a suitable ripping device 9 in one the overflow opening 7 forming channel 10 is provided. Furthermore, in the wall of the auxiliary housing 5 a pressure measuring device 11 used, by means of which the pressure in the test room 6 can be measured and thus monitored.

The operation of this system has already been explained in detail above, namely that with little leakage of Verschlußstopfens 3 gaseous fluid from the test room 6 sneaking on the vacuum plug 3 over in the interior 2 and thus in said insulation sheath of Be container system, whereby the pressure in the test room 6 drops, which by means of the pressure measuring device 11 can be recognized. Thus, there is a leak on the vacuum stopper 3 detectable, whereupon a suitable countermeasure can be taken. Also the function of the rupture disk 8th has already been explained.

First, the arrangement proposed herein reduces the likelihood of breakage of the vacuum in the vacuum insulation sleeve due to leakage of the vacuum plug 3 entry. Second, a leak in operation can be detected by means of the pressure measuring device. Also, the rupture disk can 8th themselves to be easily checked for integrity, especially if they are - as shown here - near the end in one of the test room 6 away channel 10 is used. In particular, it is possible the rupture disk 8th apply pressure to both sides.

The gaseous fluid with which the test room 6 is filled, is preferably chosen such that only a small heat transfer in liquefaction or freezing of the same takes place on the outside of the wall of the inner container, if this gaseous fluid at the stopper having a leak 3 should pass into said vacuum insulation sheath between the inner container and the outer container of the container system. Furthermore, this gaseous fluid should have a high affinity (for binding) to getters or absorption masses provided in the vacuum insulation sheath (as usual). Finally, it is advantageous if said fluid exits the test chamber 6 easily detectable in the environment.

The proposed arrangement requires no conversion of the known and proven Concepts for Vacuum plug, vacuum lock and connection technology. With these activities will increase the safety of the container system (eg a vehicle tank for storing cryogenic hydrogen) through a supervised Redundancy at a very critical point increased significantly. In order to Is it possible, equipped accordingly Vehicles in closed spaces it should be pointed out that quite a Variety of details may differ from the above explanations, without the content of the claims to leave.

Claims (3)

Container system with a vacuum insulation sheath, which is provided between an inner container and an outer container enclosing this at a distance, wherein an evacuation opening in the wall of the outer container, a so-called. Evakuierungsflansch ( 1 ) is assigned, when the container system is ready by means of a sealing plug ( 3 ) is closed, characterized in that the evacuation flange ( 1 ) except for a transfer opening to the evacuation flange ( 1 ) and one regular by means of a rupture disc ( 8th ) or the like. Closed overflow ( 7 ) closed and filled with a fluid test room ( 6 ), whereby the pressure of the fluid in the test chamber ( 6 ) by means of a pressure measuring device ( 11 ) is monitorable. Container system according to claim 1, characterized in that a test room ( 6 ) enclosing auxiliary housing ( 5 ) in the area of the connection to the evacuation flange ( 1 ) in the manner of a for generating the vacuum between outer container and inner container to the Evakuierungsflansch ( 1 ) is designed to be connected suction line or lock. Container system according to claim 1 or 2, characterized in that in the test room ( 6 ) fluid is selected so that when it flows into the vacuum insulation casing only a small energy input takes place or the vacuum is only minimally weakened, and / or that this fluid exiting the test chamber ( 6 ) is detectable.