DE19853531A1 - Device for removing a pressurized liquid gas stream from a pressure vessel - Google Patents

Abstract

The invention relates to a device for extracting a gas flow from an insulated pressure container (1) for cryogenic liquefied gas, with a pressure generating device (2) and a sampling line (3) connected to the insulated pressure container (1), whereby the pressure generating device ( 2) liquid gas is evaporated. According to the invention, a particularly simple pressure generating device is provided in that the pressure generating device (2) has a condensation volume (4), that the condensation volume (4) is partially in heat-conducting contact with the cryogenic liquid gas (5), that the condensation volume (4) partly in heat-conducting contact with a heat reservoir that is at a higher temperature than the cryogenic liquid gas (5), that the condensation volume (4) can at least be flow-connected to the extraction line (3) and that the pressure generating device (2) operates exclusively via the condensation volume (4 ) connected to the extraction line (3), which is essentially not in heat-conducting contact with the cryogenic liquid gas (8).

Description

The invention relates to a device for removing a gas from an insulated pressure vessel for cryogenic liquefied gases, with one Pressure generating device and one with the insulated pressure vessel related sampling line, with the help of Pressure generating device is evaporated liquid gas.

Pressurized cryogenic liquefied gases are in different technical fields of application. These are before all areas of application in which the high storage density or the deep Temperature of the liquefied gas is desired. The one to promote the liquid or to reach a pressure level in one The pressure build-up required in the container is usually caused by evaporation of part of the liquid. The Pressure build-up is quick and energy-saving and the removal of cold gas or supercooled liquid (see e.g. U.S. Patent 3,648,018). To build up or keep the pressure constant in an insulated pressure vessel are in the prior art (cf. e.g. B. DE 43 26 138 C2) devices used in the pressure vessel are installed. The known devices for increasing the pressure work with an electric heater to evaporate the liquefied gas. Devices for  Pressure increase known that is outside the pressure vessel are, such as with pressure build-up evaporators Gas return line.

In a pressure generating device that with one in the Pressure vessel built-in electric heater is working problematic that high installation costs and in the event of a defect high repair costs arise and that for the operation electrical Energy is needed.

The installation of one with a pressure build-up evaporator comes for flat ones Vehicle tanks because of the low inlet height of the liquid in the Usually not considered.

Based on the problem described above, the Invention, the object of a device for removing a pressurized cryogenic liquid gas stream from a to provide insulated pressure vessels for liquid gas which the pressure generating device is very simple and moreover, only a small amount of energy is required.

According to the invention, the previously derived and shown task solved in that the pressure generating device Has condensation volume that the condensation volume partly in contact with the cryogenic liquid gas stands that the condensation volume partially with one compared to the cryogenic liquid gas of higher temperature located heat reservoir is in heat-conducting contact that the Condensation volume with the sampling line at least is flow-connectable and that the pressure generating device exclusively about the condensation volume with the  Extraction line connected, essentially with the cryogenic liquid gas not in heat-conducting contact Has vibration volume.

In the condensation volume provided according to the invention is located due to the connection via the sampling line same gas as in the insulated pressure vessel, for example Hydrogen, nitrogen or natural gas. Is in steady state in the area of the condensation volume that corresponds to the cryogenic liquid gas is in heat-conducting contact, also liquid gas. In contrast, in the area of the condensation volume, the with a higher than the cryogenic liquid gas Temperature-located heat reservoir in heat-conducting contact stands, the gas in the gaseous state. The invention Design of the pressure generating device now uses the effect from that when removing liquid gas from the isolated Pressure vessel via the sampling line pressure fluctuations between the insulated pressure vessel and the consumer due to technical reasons arise. These pressure fluctuations are over the Flow connection between the condensation volume and the Extraction line to the existing condensation volume transfer liquid gas. The transmission of these pressure fluctuations causes the liquid column to face on one side the vibration volume according to the invention and on the other Side opposite the flow connection to the sampling line in Vibrations is set. These vibrations cause the liquid gas partially present in the condensation volume Areas of the condensation volume that comes in contact a temperature above the temperature of the cryogenic liquid Gases is. This touch leads to the cryogenic liquid gas evaporates. This evaporation initially amplifies the vibration, because  the higher pressure created during evaporation corresponds to the respective Deflection counteracts the vibration. With the opposite The rash is the initially heated gas in the area of the Condensation volume, which with the cryogenic liquid gas in the heat-conducting contact is cooled again and recondensed. At this process is simultaneously heat in the insulated pressure vessel transported, whereby the desired effect occurs, namely the pressure increases inside the insulated pressure vessel. The invention works So with very simple means, does not require any complex installations in the insulated pressure vessel and is also independent of a separate electrical energy source within the isolated Pressure vessel. In addition, it is ensured that during the Do not pause the pressure inside the insulated pressure vessel is influenced, since a pressure build-up only when liquid is removed Gas is effected. To achieve these advantages, the Invention to take advantage of the fact, as mentioned, that when removing of cryogenic liquefied gas from a pressure vessel Pressure fluctuations, for example due to evaporation pulsations, arise within the sampling line.

The invention according to the invention experiences a first advantageous refinement Device in that between the condensation volume and Withdrawal line a shut-off device is provided. The Arrangement of a shut-off device in the flow connection between the condensation volume and the sampling line ensures that the operation of the pressure generating device is simple can be controlled. If the shut-off device is closed, then the pressure fluctuations in the sampling line cannot propagate the condensation volume and lead accordingly in the condensation volume also does not cause an oscillation of the Liquid column between cryogenic and warmer areas of the  Condensation volume. So the result is when closed Shut-off device no heat transport in the insulated Pressure vessel over the condensation volume instead.

This is particularly simple and advantageous Condensation volume provided according to the invention in that it than with his lower bow under the liquid level extending U-shaped line is formed. In this case it is Condensation volume with its lower arch in the thermally conductive Contact with the liquid gas while the two legs of the U- shaped line at least partially in thermally conductive contact with one compared to the cryogenic liquid gas at a higher temperature located heat reservoir. A little over or under pressure on one leg of the U-shaped line is enough to get out liquefied gas existing liquid column out of balance bring, because the warmer gas compressible in the vibration volume is. As the liquid column return to the stable position a vibration occurs. As already mentioned, amplified by cold gas and liquid gas, which in the warmer Sections of the U-shaped pipe are warmed, expanding and therefore additionally counteracts the respective rash. The U shaped line amplifies the vibration particularly strong, because the cryogenic liquefied gas the connection between the Vibration volume and the sampling line completely. Such a conclusion can, however, also by other forms of Condensation volume can be achieved and is beyond that Function of the device according to the invention is not essential necessary.

As a heat reservoir, which is opposite the cryogenic liquefied gas at a higher temperature is particularly suitable  the environment of the insulated pressure vessel. The environment of a insulated pressure vessel is inevitably on a higher one Temperature as the cryogenic liquid gas in the insulated pressure vessel. This temperature difference is determined by the device according to the invention exploited. In this embodiment of the invention The device is except a possibly provided shut-off device there is no active component.

With continuous operation of the device according to the invention, it is conceivable that the heat input from the environment of the insulated Pressure vessel subsides in that in the areas of Condensation volume with the on opposite the cryogenic liquefied gas located in higher temperature heat reservoir heat-conducting contact, water vapor precipitates and freezes. This can be prevented by a corresponding further embodiment of the device according to the invention Heat reservoir one outside of the insulated pressure vessel arranged heater. This heater can for example on one or both legs of the U-shaped line be arranged.

There are now a number of possibilities for the invention Device for removing a cryogenic pressure liquid gas flow from an insulated pressure vessel for liquid To design and develop gases. For this, for example referred on the one hand to the subordinate to claim 1 Claims on the other hand to the description of a preferred Embodiment in connection with the drawing. In the Drawing shows the only figure in an insulated pressure vessel built-in embodiment of a device according to the invention  to remove a pressurized cryogenic liquid Gas flow.

The single FIGURE shows an insulated pressure vessel 1 with a pressure generating device 2 designed according to the invention and a sampling line 3 connected to the insulated pressure vessel 1 .

According to the invention, the pressure generating device 2 has a condensation volume 4 in the form of a U-shaped line. As can be clearly seen in the single figure, the condensation volume 4 is partly in thermal contact with the cryogenic liquid gas 5 , namely with the lower bend of the U-shaped line. Another part of the condensation volume 4 , namely the upper region of the legs of the U-shaped line, is in heat-conducting contact with the surroundings of the pressure vessel 1 .

The heat-conducting contact between the surroundings and the condensation volume is partly formed directly through the wall of the U-shaped line, namely in the uppermost region, partly also via heat conduction through the vacuum insulation 7 of the pressure container 1 . Of course, this creates a temperature gradient within the respective leg of the U-shaped line with decreasing temperature from top to bottom.

A shut-off device 6 designed as a valve is provided in the flow connection between the condensation volume 4 and the removal line 3 .

At which the flow connection facing away from the withdrawal conduit 3 end of the condenser volume 4, a vibration volume 8 is provided according to the invention, which guarantees the oscillation of the fluid column in the condensation volume 4 in that the gas in the vibration volume 8 is compressible.

When the shut-off device 6 is open, pressure fluctuations from the extraction line are transferred to the condensation volume 6 . These pressure fluctuations on the right leg of the U-shaped line are sufficient to bring the liquid column 9 out of balance, since, as described above, the warmer gas in the vibration volume 8 is compressible. Since the liquid column 9 wants to return to the stable position, an oscillation occurs. This is amplified by cold gas 10 and liquid, which are warmed in the warmer sections of the U-shaped line, expand and therefore additionally counteract the respective deflection of the liquid column 9 . With the opposite deflection, the heated gas 11 is cooled again in the pressure vessel 1 and recondensed. At the same time, heat is transported into the pressure vessel, which increases the pressure as desired.

The oscillation is triggered only by opening the shut-off device 6 , as a result of which the pressure fluctuations in the extraction line between the pressure vessel 1 and the consumer (not shown) are transmitted to the liquid column 9 . As soon as the shut-off device is closed, the vibration runs out quickly, which at the same time stops the heat input.

Claims (5)

1. Device for withdrawing gas from a pressurized insulated pressure vessel ( 1 ) for cryogenic liquefied gas, with a pressure generating device ( 2 ) and with the insulated pressure vessel ( 1 ) connected to the extraction line ( 3 ), with the help of the pressure generating device ( 2 ) liquid gas is evaporated, characterized in that the pressure generating device ( 2 ) has a condensation volume ( 4 ), that the condensation volume ( 4 ) is partially in heat-conducting contact with the cryogenic liquefied gas ( 5 ), that the condensation volume ( 4 ) partly in heat-conducting contact with a heat reservoir which is at a higher temperature than the cold liquid ( 5 ), that the condensation volume ( 4 ) can be at least flow-connected to the extraction line ( 3 ) and that the pressure generating device ( 2 ) has an exclusively via the condensation volume ( 4 ) with the sampling line g ( 3 ) connected, which is essentially not in heat-conducting contact with the cryogenic liquid gas ( 8 ). 2. Device according to claim 1, characterized in that a shut-off device ( 6 ) is provided between the condensation volume ( 4 ) and the removal line ( 3 ). 3. Apparatus according to claim 1 or 2, characterized in that the condensation volume ( 4 ) is designed as a U-shaped line running with its lower arc in the liquid gas ( 5 ). 4. Device according to one of claims 1 to 3, characterized in that the heat reservoir is formed from the surroundings of the insulated pressure vessel ( 1 ). 5. Device according to one of claims 1 to 4, characterized in that the heat reservoir has a heating device arranged outside the insulated pressure vessel ( 1 ).