DE582538C - Storage and transport container for liquefied gases - Google Patents

Description

The present invention relates to containers for storage and transportation of gases liquefied at low temperature, such as. B. Oxygen.

As is well known, it is advisable to put the heat protection compound in a container of this type to move a gas atmosphere other than atmospheric air, for example in one Atmosphere that is formed by part of the gas in which the liquefied Gas containing container evaporated. The heat protection mass is arranged in this way free of any trace of moisture; however, this would not be the case if the protective mass came into contact with atmospheric air would stand. In the latter case, when the air cools down, the Heat protection mass transfer their moisture to this when the container with liquefied Gas is filled; the heat protection compound would remove this moisture when rewarming do not give up again as soon as the container is liquefied Has released gas. So there would be a gradually increasing accumulation of moisture in the heat protection mass, whereby their insulating capacity would be greatly reduced.

The anhydrous liquefied gas that flows into the heat protection mass can through a drain can be obtained with a tap connected to the drain pipe "for the gas evaporated in the container is connected; however, this arrangement has the Disadvantage that the operating staff from time to time certain more or less time consuming Has to carry out manipulations.

This disadvantage is avoided by an automatic device that eliminates any handling makes redundant. To this end, this is done by evaporation of the liquefied Gas originating and always under a low pressure gas after a Out flap, which is designed, for example, similar to a reducing valve, as in the processing of metals with oxygen or for lighting purposes. This flap is adjusted so that it allows the gas to flow through as long as the Pressure on the underside does not have a low value, for example 5 cm water column exceeds. As soon as the pressure prevailing in the thermal insulation mass exceeds this value, the flap closes so that the gas can no longer flow through it. on the manner described is achieved that the dry vaporized gas when the container exposed to the cold, d. H. is filled with liquefied gas, gets into the flap, flows through this and penetrates from there into the heat protection mass; collects here it up until its pressure for example

5 cm water column. The flap then closes and there is no further gas leakage instead of. Here, it is guaranteed that the heat protection compound is always in a thoroughly dry atmosphere. Even if the outer jacket were not tight, the outside air would penetrate into the jacket and consequently the penetration of moisture into the ίο thermal insulation mass is not to be feared, because there is always a very slight overpressure in this.

The device ensures that it works completely automatically. Let it be B. the Consider the case where the container is emptied and the liquefied gas contained therein is discharged will. In this case, developed during rewarming - as a result of penetration of heat into the empty container - the heat protection mass which is reheating at the same time a certain amount of gas, which the atmosphere surrounding the heat protection mass forms. In order to avoid any overpressure in this atmosphere, there is a gas line through which part of the vaporized Gas is led from the flap mentioned to the heat protection mass, a valve or a reducing valve is switched on, which works in the opposite direction and the supplied gas escape to the outside lets as soon as the pressure of the gas in the line has a certain value, for example 10 g. Instead of a valve, you can also use a liquid seal, ζ. Β. use a mercury seal. By using the two above-mentioned devices is always in the Heat protection mass a completely dry atmosphere with a weight between 5 g and 10 g entertaining fluctuating pressures.

Such containers for liquefied gases can also be exposed to unexpected shocks resulting in rupture of the inner container containing the liquefied gas and from the outer jacket, which closes in a gas-tight manner, by means of heat protection mass, for example Magnesium carbonate, isolated; in this case the liquefied gas comes in contact with the heat protection mass and with the outer jacket and gassed in abundant quantities. The usual safety devices are not able to divert the gas filling the heat protection mass sufficiently quickly, so that the pressure within of the outer jacket increases. In order to avoid any danger, a part of the outer jacket is and specifically the upper part, designed as a disc, which is under the influence a certain internal pressure, thus exposing a larger opening will; this disc can only be connected to the sheet metal of the outer jacket through a thin rubber membrane be connected. The increasing pressure inside the jacket is then applied to it Transfer membrane, which is arranged so 6 = that it is, for example, under a pressure of about 1 kg tears. A large opening then arises automatically in the jacket and enables it the rapid removal of the gas formed, the heat protection mass and all possible blockages.

The drawing represents an embodiment of the invention, in particular for liquid Oxygen, schematically.

The latter is located in an inner container 1, which is airtight from the outer Outer wall 2 by a heat insulating compound 3, such as. B. magnesium carbonate, is separated. The mentioned inner container 1 is on the outer wall 2 through Suspension chains 4 and 4 'attached and provided with a drain pipe 5.

The outer wall 2 is formed at its upper part into a flat disk 8, which is so arranged that it stands out under the influence of a certain internal pressure; it stands with the sheet metal of the outer wall 3 through a thin chuk skin 9 in connection.

A channel-like pipe connection, which carries a 9 = safety valve 6 and a thin metal plate J , which yields at a certain internal pressure, conducts part of the vaporized gas into the thermal insulation compound; this pipe connection is provided with a diaphragm valve 11, which is set in such a way that it remains open as long as the gas pressure in the heat insulating compound does not reach a certain value, e.g. B. 5 cm water column, exceeds. On a branch off ^to supply ° 12 of the pipe fitting 10 is a diaphragm valve 13; this is set in such a way that it remains closed as long as the gas pressure in the heat insulating compound does not reach a value that slightly exceeds that to which the valve 11 is set, ie z. B. 10 cm water column. If the pressure exceeds this value, the valve 13 opens and the gas escapes through the opening 14. no

As a result of this arrangement, there is always between 5 and 10 g in the insulating compound lying, self-adjusting pressure.

Claims (4)

Patent claims: i. Storage and transport containers for liquefied gases of low temperature with the insulating material surrounding the container, which is in an airtight Enclosed outer jacket and with a pressure gas consisting of the gas smd is filled in the atmosphere originating in the container, characterized in that a pressure reducing valve in the gas line that is set to a constant pressure is connected between the container and the insulating material and a valve communicating with the outside air the gaseous atmosphere present in the insulating material is in communication, so that the pressure of this atmosphere automatically to a value different from the level of the pressure in the container between certain values of the pressure in the Container is kept independent limits. 2. Container according to claim i, characterized in that between the reducing valve and the container a safety valve and a metal sheet which yields to the outside at a certain pressure are provided. 3. Container according to claim 1, characterized in that in the event that the Pressure of the gas atmosphere suddenly exceeds the upper limit, the outer jacket is provided with a device which yields under the influence of a certain internal pressure and the rapid discharge of the contents of the jacket. 4. Container according to claim 3, characterized in that the resilient device consists of a disc which is designed as one part of the outer shell and with the other part of the outer shell connected by a rubber membrane. 1 sheet of drawings