DE19835285C1 - Cryogenic liquid supply circuit - Google Patents

Abstract

the cryogenic liquid supply circuit has a storage tank (1) connected to the user (3) by a pipeline (2',2''). An intermediate tank (4) is provided, the feed line to it from the main tank having a length twice of that from the auxiliary tank to the user. The pipeline has no special insulation.

Description

The invention relates to a device for providing a cryogenic liquid according to the preamble of claim 1, with a storage tank and a feed line, by means of which the cryogenic liquid is passed to a consumer.

Such devices are used regularly where there is a large amount a cryogenic liquid is needed. This is particularly the case with a cryogenic Liquid-consuming processes such as tumblers and cutters Treatment of meat or cooling and freezing systems.

The cryogenic liquid, such as liquid nitrogen (LN ₂ ), is made available in a special large-volume storage tank, which is regularly replenished by a company supplying the cryogenic liquid if required. Typically, such a storage tank holds about 2000 to 50,000 liters of this cryogenic liquid.

Because of the size of the storage tank or because of the delivery of the Cryogenic liquid with special vehicles almost always has to be in the storage tanks  be placed further away from the consumer. The length of the supply line from the storage tank to the consumer can therefore be up to 200 meters.

Depending on the consumer, the amount of cryogenic liquid required per time is not very big. Often the cryogenic liquid is also in the consumer Intervals supplied. The cryogenic liquid supplied to the consumer is located therefore often in the supply line for a long time.

So that the cryogenic liquid in the supply line does not become too hot and in passes the gaseous state, it is necessary to heat the supply line to provide me insulation. It is known to lead the supply line in a pipe which has a high vacuum. With such high vacuum insulation costs can amount to approximately DM 800.00 to DM 1,000.00 per meter. A cheaper variant of the insulation is to supply the lead with highly effective To wrap insulating materials. In addition, the supply line can also be made of rock wool to be encased. With such insulation, however, the costs can always still be about DM 500.00 per meter.  

From DE 197 04 362 C1 and DE 194 04 361 C1 is a refueling unit Direction for cryogenic fuels for refueling vehicles of all types with under cooled liquid known from such a refueling device, in which a Fuel tank for refueling by means of a line for cryogenic media with a Storage container is connected. The storage container is within a larger one Storage container arranged with which he by means of a line for cryogenic media connected is. The storage container arranged in the larger storage container can be isolated from the larger storage container.

Furthermore, a microtome with a cooling is known from DE 40 12 600 C2 chamber, with a cooling chamber room accessible and observable from above, in which an object holder for holding an object to be processed and a Editing tool for the object are arranged. Object holder and processing are tools for setting a desired temperature using Heizwi controlled temperature controlled. Furthermore, a storage tank is provided for Intake of a liquid cryogen that flows into the cooling chamber space End supply line for vaporized, gaseous cryogen with the cooling chamber space is connected. There is also a heatable element in the flow path of the gaseous cryogen for setting a predetermined temperature of the gasate atmosphere provided in the cooling chamber space. The heated element is as one the supply line forming radiator formed in his to the cooling chamber side wall a plurality of coins arranged one above the other has openings for the gaseous cryogen, the radiator at the Storage tank connected via a poorly heat-conducting connecting line is.

It is an object of the invention to train a device mentioned in the introduction the fact that the supply line manages essentially without expensive insulation.

The solution to this problem results from the characteristics of the characteristic Part of claim 1. Advantageous further developments of the invention result from the subclaims.

According to the invention, a buffer is provided, which he Most line part is connected to the storage tank and a second Lei tion part is connected to the consumer. The cache is similar Way insulated as the storage tank.

The cache, the capacity of which is regularly only a fraction corresponds to the capacity of the storage tank, because of its small Arrange easily in the vicinity of the consumer. This allows the  second mostly heat-insulated line part, by means of which the consumer with the buffer is connected to be kept very short. The first lei tion part, by means of which the intermediate storage is connected to the storage tank accordingly very long. The length of the second line is regular sometimes less than half the length of the first line section. Often it is only a quarter or an eighth. However, it can also be less than a tenth.

The arrangement according to the invention advantageously makes it possible to use it not to isolate the first part of the line. The first line part needs thus no longer have any special insulation. The heat loss of the first The line section can be greater than 20 watts per meter. For example, he can be 30 Watts per meter or even greater than 35 watts per meter, for example 40 Watts per meter. As a rule, the first line section is at most with a Protective insulation must be provided. So he can with insulation against corrosion or mechanical damage or protection against contact cold line. You only need the second, very short lei to be isolated. Because the cryogenic flows supplied to the consumer liquid is only in the second line section before the supply. The warmth Conductivity of the insulation of the second line part can, for example, 1 to 2 watts per Meters.

So that the cryogenic liquid in the second line section does not become warms and changes to the gaseous state, the second line part should insulation. The isolation depends on how much liquid is supplied to the consumer per unit of time. If the amount supplied is small, very good insulation must be selected, is that supplied to the consumer Large amount of liquid, insulation requirements are not as high put. Because of the shortness of the second line section, this can happen in special cases there is even no need to isolate the second line section.

Since the first line part does not have to have thermal insulation, it can be stan dardleitung be used. This results in a very high cost advantage. Because, due to the lack of thermal insulation, the first line section is not only  easier to manufacture, but can also be significantly easier handle, so that the line installation is significantly simplified. In practice this results in a cost saving of approx. 90%.

A cryogenic liquid only flows through the first line section if the buffer is refilled after it has almost been emptied. When filling up, a large amount of liquid per unit of time can pass through the first Line part are sent so that the liquid is only briefly in the first Line part is located and therefore has no time to warm up.

To increase the amount of liquid per unit of time and thus the dwell time to reduce the liquid in the first line part, the cross section of the first Line part expediently chosen to be very large. So it is advantageous for the ver a pipe with a diameter of about 20 millimeters turn. But also with a pipe with a diameter of 15 millimeters the cryogenic liquid without substantial heating through the first line part sent.

An embodiment of the invention has proven particularly useful provides, in which the first part of the line facing the buffer End has a branch, by means of which during a first filling phase gas located in the first line part can be derived. Because, although there is also the cryogenic liquid in the first line section not warmed up significantly during the filling of the intermediate storage, so goes initially a very small part of the cryogen located in the first line part liquid into the gaseous state.

Because the time between two filling processes of the buffer can be between a few hours and several days. To prevent that in the first line part initially generated gas reaches the buffer, it becomes over the branch past the cache, for example into the open headed. It is particularly useful here that the first line part in its the end facing the buffer has a valve by means of which the  Guided tour to the buffer during the phase during which the first Lei Part of the resulting gas bypassed the temporary storage is closable.

After the branch opens and the feeder to the intermediate storage ge is closed, cryogenic liquid is transferred from the storage tank to the first line section headed. As a result, the one located in the first line part escapes Gas from the first line section. Through the from the storage tank in the first lei the cryogenic liquid conducted part cools down very quickly, the first line part whereby the subsequent cryogenic liquid no longer heats up significantly, and remains in its liquid state.

It is particularly advantageous if a temperature sensor is provided by means of wel chem the temperature of the end of the first line part of the medium located in the line is detectable. By means of the Sensor can thus be determined whether there is still gas in the first line part finds or the first line part already completely with a cryogenic liquid is filled. There is already only cryogenic liquid in the first line section speed, the feed to the buffer is opened by means of the valve and the junction closed. As a result, it passes through the first line part flowing cryogenic liquid very quickly into the buffer.

Further advantages of the present invention result from the following Description of a particular embodiment with reference to the Drawing.

The only figure shows an arrangement according to the invention.

As can be seen from the drawing, a storage tank 1 'is connected via a first conduit part 2 with a latch. 4 The first line part 2 'is connected via a main solenoid valve 10 to an outlet 11 of the storage tank 1 . Liquid nitrogen (LN ₂ ) is in the storage tank 1 . The liquid nitrogen is fed into the storage tank 1 via an inlet 12 . The liquid nitrogen is regularly delivered by tank trucks. The storage tank 1 has a capacity of about 30,000 liters. To avoid heating the liquid nitrogen, the storage tank 1 is thermally insulated by means of a high vacuum. The pressure in the storage tank 1 is about 1 to 15 bar, preferably 6 to 7 bar.

The first line part 2 'can have a length of 50 to 200 meters. A usual length of the first line part 2 'is 70 meters. The cross section of the first line part 2 'is about 200 square millimeters. The first line part consists of a non-heat insulated pipe.

A temperature sensor 6 is provided at the end of the first line part 2 ′ facing the intermediate store 4 , by means of which the temperature of the medium located on the slope in the first line part 2 ′ can be determined. The temperature can be between minus 147 ° C and minus 196 ° C. The first line part 2 'is divided into two branches at its end facing the buffer store. Both branches are connected to the intermediate store 4 . The first branch is with one. Inlet 17 , the second branch connected to a second outlet 16 . A first solenoid valve 7 is arranged in the first branch. A second solenoid valve 8 and a third solenoid valve 9 are arranged in the second branch. A first branch 5 is located between the second solenoid valve 8 and the third solenoid valve 9 .

The intermediate storage 4 has a capacity of approximately 600 liters. It is thermally insulated in a similar manner to the storage tank 1 by means of a high vacuum. At a first outlet 15 of the latch 4, a second line part is "closed been. The second line part 2" 2 is about 5 m long, and thermally insulated. A consumer 3 is connected to the intermediate store 4 by means of the second line part 2 ". The consumer 3 can be, for example, a tumbler or a cooling and freezing system. The amount of cryogenic liquid required by the consumer 3 can be approximately 5 to 10 liters per minute It can be supplied at intervals of approximately 5 minutes and a break of 5 minutes. A fourth solenoid valve 14 is arranged in the second line part 2 ″ for the controlled supply of cryogenic liquid to the consumer 3 . At its end facing the consumer 3 , the second line part 2 "has a second branch 18 in which a fifth magnetic valve 13 is arranged.

The cryogenic liquid supplied to the consumer 3 is removed via the second line part 2 ″ from the intermediate store 4. The pressure in the intermediate store 4 is approximately 2 to 5 bar. In the event that the second line part 2 ″ is already too long because of a length of time Has formed gas, first the fifth solenoid valve 13 is opened and the gas located in the second line part 2 "is passed outside via the second branch 18. After the gas has been removed from the second line part 2 " and the second line part 2 "has been completely removed cryogenic fluid is filled, the fifth solenoid valve 13 is closed and the fourth solenoid valve is opened, so that the consumer 3 cryogenic liquid speed can be supplied from the beginning.

If the buffer 4 is almost empty, the main solenoid valve 10 is opened ge. Since gas has formed in the first line part 2 'because of the long dwell time, the second solenoid valve 8 is first opened and the first solenoid valve 7 and the third solenoid valve 9 are closed. It is hereby achieved that the gas located in the first line part 2 'flows into the open via the first branch 5 during a first filling phase. By the first from the storage tank 1 into the conduit member 2 is very 'directed cryogenic liquid, the first conduit part 2 cools' off quickly, so that the liquid after a very short time no longer enters the state gasförmi gen. If it is determined by means of the temperature sensor 6 that there is cryogenic liquid in the first line part 2 'at the end facing the intermediate storage 4 , the second solenoid valve 8 is closed and the first magnetic valve 7 is opened. As a result, cryogenic liquid reaches the temporary storage 4 via the inlet 17 of the temporary storage 4 .

As in the buffer memory 4 may have formed during the time the gas, the third solenoid valve 9 is initially opened so that the escaping of the displaced into the intermediate storage 4 led liquid gas through the second outlet 16 of the first turn and 5. FIG. After the intermediate storage 4 is sufficiently filled with cryogenic liquid, the first solenoid valve 7 and the third solenoid valve 9 are closed again.

Claims (4)

1. Device for providing a cryogenic liquid with a storage tank ( 1 ) and a feed line ( 2 ', 2 "), by means of which the cryogenic liquid is passed to a consumer ( 3 ), characterized in that an intermediate store ( 4 ) is provided , Which is connected via a first line part ( 2 ') of the supply line, which has no special cold insulation, to the pre-storage tank ( 1 ) and via a second line part ( 2 ") of the supply line, the length of which is less than half the length of the first Line part is connected to the consumer ( 3 ). 2. Device according to claim 1, characterized in that the first line part ( 2 ') at its end facing the buffer ( 4 ) has a first branch ( 5 ) by means of which during a first phase in the first line part ( 2 ' ) located gas is discharged. 3. Apparatus according to claim 1 or 2, characterized in that a temperature sensor ( 6 ) is provided, by means of which the temperature of the end of the first line part ( 2 ') in the line facing the intermediate store ( 4 ) can be determined. 4. Device according to one of claims 1 to 3, characterized in that a first valve ( 7 ) is provided, by means of which the first line part ( 2 ') can be closed at its end facing the intermediate store ( 4 ) during the first phase.