DE19645488C1 - Delivery system for gases e.g. hydrogen, nitrogen or natural gas from liquid phase in cryogenic tank - Google Patents

Abstract

This system withdraws cold gas from a cryo-tank (10). This tank includes an insulated vessel (12) for very low temperature liquified gas, with an extraction line (18) taken from it. In the new system there is an evaporation volume (22) connected to this line. Liquid gas reaching the volume through the line is partially evaporated, some flowing back to the tank, some being delivered (36). Also claimed is the method of extracting from the tank. During extraction the liquid phase is partially evaporated outside the tank, and some liquid and vapour are returned to the tank.

Description

The invention relates to a system and a method for removing cold gas from a cryogenic tank that insulates an Has storage container and a sampling line.

A cryogenic tank is an insulated storage container in which liquid, cryogenic gases are usually stored under excess pressure. The low temperature of the liquefied gases can be maintained over a longer period of time by vacuum insulation. Such cryogenic tanks are used, for example, as fuel tanks in motor vehicle technology. They can contain liquefied hydrogen (LH ₂ ), liquefied natural gas (LNG), liquefied nitrogen (LN ₂ ) or the like.

When liquid gas is withdrawn from a cryogenic tank, it happens a pressure drop in the tank. For many applications, for example the above-mentioned use as a fuel tank for a motor vehicle but it is necessary to keep the pressure in the tank constant. Of the Constant internal pressure in the cryogenic tank is used, among other things continuous supply of one or more consumers with the LPG.  

To increase the pressure in the cryogenic tank have been electrical Heaters inside the cryotank or Pressure build-up evaporator (DE-OS 23 29 053) used. A Pressure build-up evaporator takes a small amount of the liquid gas, the gas is evaporated outside the cryotank and fed back to the tank. The "pressure build-up gas" due to the pressure differences between the liquid and the Circulate the gaseous phase without additional aids. That kind of Maintaining or increasing the internal pressure in a cryogenic tank using a pressure build-up evaporator is particularly suitable for large, standing liquid gas storage. The performance of the pressure build-up evaporator depends on the level in the storage tank. Can also Problems arise due to the phase change.

The above-mentioned electrical also used to build up pressure Heating devices are usually implemented as resistance heaters. These not only require electrical energy, they also require it also complex vacuum tight as well as low temperature and pressure-resistant bushings. If there is a defect, they produce high ones Repair costs. The previously known solutions for maintaining or increasing the pressure in a cryotank when withdrawing liquid Gas are therefore not entirely satisfactory.

In addition, DE 44 11 338 A1 describes a device for Suppression of gas phase pressure in storage tanks for cryogenic liquefied gases known to be the warmest liquid layers on the Pulls off the surface of the liquid level when removing liquid.

The object of the invention is therefore a system and a method for Extract cold gas from a cryogenic tank to indicate which the pressure in the tank can be kept constant or even increased and which can also be used in small, mobile cryogenic tanks, for example in  Fuel cryogenic tanks for the automotive sector. The device and the process should be as simple, easy to maintain and be inexpensive so that they can be manufactured even in large quantities Tanks can still be used economically.  

This task is accomplished by a system with the features of claim  1 and solved by a method with the features of claim 9.

The system according to the invention has an insulated storage container for liquid gas, a sampling line and one Evaporation chamber, or an evaporation volume, on. The Evaporation chamber is connected to the sampling line and can the form of an extension of the sampling line or a small one Have container. The extraction line is preferably at least of the storage container to the evaporation chamber isolated while the evaporation chamber has a non-isolated space. Depending on Use case is the piece of the sampling line which is from the Evaporation chamber leads to one or more consumers, isolated or not isolated. The sampling line points expediently a riser pipe in the storage container.

Due to the pressure differential between the cryogenic tank and one Consumers come across it when opening a valve in the isolated Extraction line to a flow of the liquid gas up to the small uninsulated vaporization chamber outside the tank. Since the Evaporation chamber, or the evaporation volume, to the environment is not isolated, there is a spontaneous evaporation of the liquid gas, which increases the pressure in the extraction line causes. The liquid (liquid gas) in the extraction line and part of the gas formed (the vaporized liquid) from the Evaporation chamber flow into the due to this pressure increase Cryotank back until the pressure in the sampling line again is balanced. Then liquid flows again (liquid gas) up through the riser. This creates a natural one Pressure vibration, or pulsation, on the container side of the Evaporation chamber.  

Since only part of the over the sampling line in the Evaporated liquid gas evaporated and evaporated in the Cryotank flows back, can on the consumer side of the Evaporation chamber with a relatively steady supply Liquefied petroleum gas can be achieved.

In the storage container of the cryogenic tank, the backflow causes the Gas proportion a pressure increase, which the by removing the Liquid gas-related pressure drop compensated. The scope of this Pressure build-up depends on the design of the sampling line and the Size of the evaporation chamber depends.

For the first time, the invention provides a system and a method for Extracting cold gases from a cryogenic tank prior to Pressure drop due to the removal of LPG without additional Tank internals, piping, electrical equipment and compensate for such. For the desired effect, only the Adjustment of the sampling line outside the cryogenic tank will. The system and method according to the invention are Particularly easy to maintain and inexpensive because there are no additional ones Installations in the tank and no additional lines in the and have to be led out of the tank and because none moving parts are necessary. Since no additional Bushings for cables, electrical cables and the like insulation of the cryogenic tank will also have to be provided not affected by the pressure build-up device. Finally there are no downtimes for pressure build-up in the Storage tank because of pressure equalization or pressure build-up takes place automatically with the withdrawal of the liquid gas.

Experiments with the system and the method according to the invention have shown that by the targeted evaporation of part of the  Amount of liquid in the sampling line using the non-isolated one Evaporation volume pressure vibration, or pulsation that is sufficient to compensate for the pressure drop in the Storage tank due to the withdrawal of liquid gas too compensate.

A bypass line can be provided to liquid gas bypassing the evaporation chamber from the storage container refer to. The bypass line then becomes in particular Use when a pressure reduction in the cryogenic tank is to take place. A switching device can also be provided in order to a sharp decrease in the liquid level in the cryotank or one excessive increase in pressure in the storage tank between removal of liquid gas and the extraction of gaseous gas switch. This measure also serves to reduce pressure in the Storage tank.

The invention is based on preferred embodiments explained with further details in relation to the drawing. In the Figures show:

Fig. 1 shows a system for taking cold gas from a cryogenic tank according to the invention and

Fig. 2 is a bypass line for the system according to the invention.

Fig. 1 shows a system for extracting cold gas from a cryogenic tank according to the invention. A cryogenic tank 10 , ie a storage tank for gases liquefied at low temperature, which in the tank under increased pressure, for. B. 5 bar are stored, includes an inner storage container 12 and a vacuum insulation jacket 14th The vacuum insulation is used to largely maintain the temperature of the liquefied gas. In a typical application in the automotive field, the cryotank 10 has the shape of a horizontal cylinder with a diameter of, for example, half a meter and a length of, for example, one meter. The ends of the tank can be rounded as shown. Usual tank volumes are in the range of 100 to 140 liters. Examples of the stored liquefied gas are liquefied hydrogen (LH ₂ ), liquefied nitrogen (LN ₂ ) or liquefied natural gas (LNG).

A riser pipe or a riser pipe 16 in the storage container 12 is part of a removal line 18 which leads out of the tank 10 and is insulated with a vacuum insulation jacket 20 outside the tank.

The extraction line 18 leads to an evaporation volume 22 which, in the embodiment shown in FIG. 1, has the form of a non-insulated extension of the extraction line 18 . However, the evaporation volume 22 can also be designed as a small, non-insulated cup connected to the extraction line 18 . In a particularly simple embodiment of the invention, the evaporation volume 22 is formed by a non-insulated and otherwise unchanged section of the extraction line 18 .

Depending on the application, the extraction line 18 leads from the evaporation volume 22 to a shut-off valve 24 , which is connected to one or more consumers (not shown). A heating device (not shown) can additionally be provided on the evaporation volume 22 .

An overpressure prevails in the storage container 12 , which is in the range of, for example, 5 bar when storing liquefied gases of the type specified. Due to the pressure gradient between the tank 10 and the consumer, which is usually at ambient pressure, there is a flow of liquid through the riser pipe 16 of the extraction line 18 to the non-insulated evaporation volume 22 , which is outside the tank 10 . The inflow of the liquid gas is designated F (liquid) in FIG. 1. In the evaporation volume or the evaporation chamber 22 there is a spontaneous evaporation of part of the liquid gas, which causes an increase in pressure in the extraction line 18 . This increased pressure pushes the liquid in the riser pipe and part of the vaporized gas back into the storage container 12 , and this backflow continues until the pressure in the extraction line 18 is balanced again. The backflow of the gas is designated G (gas) in FIG. 1. Then liquefied gas flows again through the riser pipe 16 into the extraction line 18 . The cycle of spontaneous vaporization of liquid gas in the vaporization volume and the backflow of a part of the vaporized gas is repeated continuously, so that a natural pressure oscillation or pulsation arises. This pressure oscillation or pulsation takes place automatically when the valve 24 is opened, without the need for intervention from the outside.

In the tank, the backflow of the gas portion causes an increase in pressure, which compensates for the pressure drop caused by the withdrawal. The amount of gas flowing back is sufficient at each filling level of the storage container 12 in order to compensate for the pressure loss caused by the removal of the liquid. In fact, the pressure increase by means of the pulsation pressure build-up can be so high that it must be switched over at intervals to a removal of liquid without automatic pressure build-up.

For this purpose, the bypass device shown in FIG. 2, with which the evaporation volume is bypassed, is used. The cryogenic tank is indicated at 10 in FIG. 2. This is connected to a pressure gauge 26 in order to record the internal pressure in the storage container 12 . In addition to the extraction line 18 already shown in FIG. 1, the evaporation volume 22 and the valve 24 leading to the consumer, a short pipe socket 28 is provided for connecting the evaporation volume and a valve 30 , which is preferably pressure-controlled. The valve 30 has a pressure relief function so that no unacceptable excess pressure can arise in the evaporation volume 22 . The line section 36 on the side of the valve 24 facing away from the tank 10 leads, as shown in FIG. 1, to a consumer (not shown).

The pressure measuring device 26 outputs pressure signals to the pressure-controlled valve 30 . If a certain pressure in the cryogenic tank 10 , e.g. B. 6 bar is exceeded, the valve 30 closes automatically. This prevents an inflow of liquid to the evaporation chamber 22 and the liquefied gas flows directly to the consumer without pressure build-up in the storage container 12 . The effect of the pulsation pressure build-up can thus be limited to a predetermined pressure range.

In addition, it can be provided in the system and the method according to the invention to switch from the removal of liquid to the removal of cold gas when there is an increase in pressure in the storage tank 12 due to the pulsation pressure build-up, or also when the tank contents are gradually heated, and thus an excessive increase in pressure to prevent.

The in the above description, the figures and the claims Features disclosed can be both individually and in any Combination may be of importance for the implementation of the invention.

Claims (9)

1. System for removing cold gas from a cryogenic tank ( 10 ), with an insulated storage container ( 12 ) for cryogenic, liquefied gas and a removal line ( 18 ) which leads out of the storage container ( 12 ), characterized in that an evaporation volume ( 22 ) is connected to the extraction line ( 18 ), liquid gas passing through the extraction line ( 18 ) into the evaporation volume, partially evaporating there and the vaporized gas at least partially flowing back into the storage container ( 18 ). 2. System according to claim 1, characterized in that the extraction line ( 18 ) is insulated over its length between the storage container ( 12 ) and the evaporation volume ( 22 ). 3. System according to claim 1 or 2, characterized in that the evaporation volume has a non-insulated space ( 22 ) in the form of an extension of the sampling line ( 18 ) or in the form of a small container. 4. System according to any one of the preceding claims, characterized in that the evaporation volume ( 22 ) is heated. 5. System according to any one of the preceding claims, characterized in that the extraction line ( 18 ) has a riser pipe ( 16 ) in the interior of the storage container ( 12 ). 6. System according to any one of the preceding claims, characterized by a bypass line ( 28 ) to remove liquid gas bypassing the evaporation volume ( 22 ) from the storage container ( 12 ). 7. System according to one of the preceding claims, marked by a switchover device to prevent the removal of liquid To switch gas to a withdrawal of gaseous gas. 8. System according to any one of the preceding claims, characterized in that the gas is liquefied hydrogen (LH ₂ ), liquefied nitrogen (LN ₂ ) or liquid natural gas (LNG). 9. A method for withdrawing cold gas from a cryogenic tank ( 10 ), in which the gas is withdrawn from the cryogenic tank in the liquid phase, the liquid gas is partially evaporated when removed outside the cryogenic tank ( 10 ) and part of the vaporized gas is passed into the Cryogenic tank is returned.