DE10210324A1 - Method and device for producing a highly pure product from a feed fraction - Google Patents

Abstract

The method and the device are used to produce a highly pure product (28, 36) from a feed fraction (11) which consists of a less pure air component, in particular nitrogen, oxygen or argon, of medium purity, with two operating phases. In a first operating phase, a stream of the feed fraction (11) in liquid form is introduced into a separation column (1); in the separation column (1), a liquid intermediate product is produced by means of countercurrent mass transfer, which has a higher purity than the feed fraction (11); the intermediate product (24, 26) is withdrawn from the separation column (1) and introduced into a first liquid store (3). In a second operating phase, a stream of the intermediate product from the first liquid store (3) is introduced into the separation column (1), by means of countercurrent mass transfer in the separation column (1), a highly pure product is produced which has a higher purity than the intermediate product, and that highly pure product (24, 28) withdrawn from the separation column (1).

Description

The invention relates to a method for producing a highly pure product an insert fraction consisting of a less pure air component.

With the help of such a system, for example, at the location of a consumer less pure intermediate product (e.g. nitrogen or Oxygen of technical purity or raw argon) can be transported in liquid form; out This less pure cryogenic liquid comes with a relatively straightforward Equipment the required high purity product.

"Air component" is understood here to mean any substance that is in elemental form or is contained as a chemical compound in the atmospheric air, for example Nitrogen, oxygen or argon. The invention is particularly suitable Process for the production of high-purity nitrogen, for example for the semiconductor Industry.

Under "insert fraction, which consists of a less pure air component," is a To understand intermediate product, mainly from the corresponding air component exists, but still contains various impurities that are easier and / or boil heavier than the air component. For example, it can be nitrogen act technical purity. The "insert fraction" has a purity, for example of at least 99.9 mol%, preferably at least 99.99 mol%. It still contains for example 0.1 mol% or less, preferably 0.01 mol% or less, for example 0.001 mol% of impurities. It is, for example, by the Product of an adjacent cryogenic air separation plant formed and / or taken from a liquid tank. The highly pure product contains less Impurities as the feed mixture. For example, it still points Impurities of 0.1 ppm or less, preferably 0.01 ppm or less.

Cleaning methods and devices that have a similar purpose to that Process according to the invention are in JP 02061481 A and US 5421164 described. The two known processes are operated continuously.

The invention is therefore based on the object of a method and a device find the economically particularly cheap, especially with low equipment Effort to be realized.

This object is achieved by the method according to claim 1. The The inventive method is discontinuous in two operating phases carried out.

In a first operating phase, the feed fraction is turned into a separation column Intermediate product that is purer than the input fraction, but not yet has the desired very high purity. This intermediate is in one Liquid tank temporarily stored. At the end of the first operating phase, the supply the insert fraction in the separation column is interrupted and the column is driven empty. In In a second operating phase, the intermediate product is used in the same Separation column initiated and again subjected to a countercurrent mass transfer, through which the highly pure end product is produced.

Although a two-stage distillation separation was carried out within the scope of the invention the corresponding equipment only requires a single separation column. The two-stage procedure allows a small number of trays in the separation column and one practically unlimited return ratio.

Due to the liquid feed of the feed fraction, the process becomes at least a part the required cold. Residual fractions, in addition to the products from the Separation column are removed, discharge the impurities and can be used as gaseous product of lower purity can be used.

It is advantageous if the feed fraction is taken from a second liquid store which is connected to a system for pressure build-up evaporation. Preferably is generated by means of the pressure build-up evaporation, which is sufficient to the total pressure loss of the process that occurs in the two operating phases overcome. In this way, the method according to the invention comes perfectly without complex machines such as compressors or pumps.

In the process, return liquid is preferably in a top condenser of the separation column, which is generated in the first operating phase with sump liquid Separation column and is cooled in the second operating phase with liquid feed fraction. Together with the liquid feed of the feed fraction in the first operating phase So much cold can be added to the process that internal measures for Cold generation can be omitted.

The top condenser is designed as a condenser-evaporator Condensation chamber top gas is liquefied from the separation column. The condensing Head gas is in indirect heat exchange with a liquid that in the Evaporation space of the top condenser evaporates and in the invention Bottom liquid of the separation column or through a liquid feed fraction is formed.

The input fraction is used only for delivery during the second operating phase of cold. It is vaporized in the top condenser and as a gaseous product subtracted less purity. In addition to the stake, the second can also be used Operating phase sump liquid passed from the separation column into the top condenser become.

It is advantageous if the separation column also has a bottom evaporator. In the first or the second or preferably in both operating phases Bottom liquid of the separation column evaporates in the sump evaporator and in the lower one Area of the separation column. The heat supply in the sump evaporator can by electrical heating or by indirect heat exchange with atmospheric Air or a water bath.

It is also beneficial if the intermediate and the high purity product the same intermediate point can be removed from the separation column. In this case only a corresponding line needs to be provided.

The highly pure product is preferably introduced into a third liquid store. Alternatively, it can be vaporized by indirect heat exchange where another process fraction is liquefied.

The invention also relates to a device for producing a highly pure Product according to claim 7.

The invention can be used with particularly great advantage if the Gas consumers meet their needs by vaporizing medium purity liquid (for example liquid nitrogen) from a liquid tank. The - otherwise unused - cold, which is released on evaporation, can in the inventive System used to produce a certain amount of high purity nitrogen become. In such cases, the need for a highly pure product is regularly clear less than that of evaporated less pure air components.

The system required for this is simple and inexpensive to manufacture. The complicated integration into an existing apparatus or a refrigeration cycle eliminated. Due to the uncomplicated structure, especially the complete or wide If rotating machines are not used, it is low-maintenance. In addition, the process is flexible, especially with regard to the liquid content of the product. The appliance can be cold-run in no time.

The invention and further details of the invention are described below an embodiment shown schematically in the drawing explains that to produce liquid high purity nitrogen (HLIN) from liquid Lower purity nitrogen (LIN) is used.

The apparatus comprises a separating column 1 , which is arranged inside a vacuum container 2, which is roughly indicated in the drawing. The vacuum container is preferably double-walled, the space between the two walls being evacuated. A “first liquid store” (intermediate product tank) 3 for intermediate product and a “third liquid store” (HLIN tank) 4 for highly pure product are also arranged in the interior of vacuum container 2 , each in a ring shape concentrically around separation column 1 . A "second liquid store" (LIN tank) 5 serves to store the preliminary product to be cleaned (the "less pure air component"). It has a system 6-7-8 for pressure build-up evaporation with an evaporator 7 . The intermediate product tank 3 has a similar system for pressure build-up evaporation, which is not shown in the drawing.

In the first operating phase, valve 10 is open and liquid nitrogen from LIN tank 5 flows via lines 9 and 11 into the bottom of separation column 1 . Valve 12 in line 13 is closed. Bottom liquid is drawn off via line 14 and evaporated to a first part 15 in a bottom evaporator 16 . Gas 17 formed in the process is returned to the lower section of the separation column 1 and rises in the column. The bottom evaporator is controlled depending on the liquid level in the column.

A second part 18 of the bottom liquid 14 is passed via valve 19 into the evaporation space of a top condenser 20 . There, the liquid evaporates almost completely (apart from a safety purge 21 ) against condensing head gas 22 from the separation column 1 . The liquid 23 produced in the process is fed as a return to the top of the separation column 1 . Gas produced in the evaporation space is drawn off via line 29 .

After the start of the first operating phase, the separation column is first run with total return and one waits until a predetermined purity has been established in the product line 24 , which in the example is arranged on the third floor from above. This is determined based on the hydrogen content at this point. If this is below a predetermined threshold, valve 25 is opened so that liquid intermediate product is throttled via lines 24 and 25 into the intermediate product tank 3 . The resulting flash gas further reduces the hydrogen content and is removed via line 27 .

Valve 1 is closed during the transition to the second operating phase. Instead, the intermediate product from the first liquid store 3 is fed via line 37 into the bottom evaporator of the separation column. The bottom evaporator 16 continues to run. The head condenser 20 is now mainly operated by means of liquid nitrogen from the LIN tank 5 by opening valve 12 and the liquid flowing via line 13 to its evaporation space.

Valve 25 initially continues to connect lines 24 and 26 . Line 24 is the desired one in the same position as in the first operating phase. If the desired high purity is reached in product line 24 , the transition to the second operating phase is achieved by switching valve 25 and the liquid from line 24 - now highly pure nitrogen as end product - flows via line 28 into HLIN tank 4 . The highly pure product can be fed to a larger tank and / or a consumer via a trigger 36 .

In both operating phases, the flushing rate with regard to the more volatile impurities is set by means of the valve 32 . The flash gases 27 and 30 from intermediate and HLIN tanks 3 , 4 and top gas 33 from the separation column are heated together with the steam 29 generated in the top condenser 20 in a heat exchanger 34 to about ambient temperature and can be used as a less pure nitrogen gas in a consumer , In this way, the system according to the invention also acts, so to speak, as a product evaporator for less pure nitrogen from the LIN tank 5 , but with the utilization of the cold released in the process to produce a highly pure product.

As an alternative to pressure build-up evaporation 6-7-8 on the LIN tank, the pressure required for the method according to the invention can also be generated by a pump (not shown).

In the method according to the invention according to the exemplary embodiment, high-purity nitrogen with a total contamination of up to 10 ppb and less can be achieved without problems, even with a relatively high operating pressure of the separation column of 6.5 bar. In a numerical example simulated on the computer, liquid nitrogen ("less pure air component") with 5 ppm Ar, 0.2 ppm O ₂ , 0.2 ppm CO, 0.04 ppm CH ₄ and 0.04 ppm H _{2 became more} liquid pure nitrogen ("high purity product") that contains residual impurities of 1 ppb CO and 0.01 ppb H ₂ ; Argon, oxygen and methane were completely removed. The number of dividers in the column is determined in a known manner depending on the desired operating pressure.

Claims (7)

1. A process for producing a highly pure product ( 28 , 36 ) from a feed fraction ( 11 ), which consists of a less pure air component, in particular nitrogen, oxygen or argon, of medium purity, with two operating phases, being in a first operating phase a) a stream of the feed fraction ( 11 ) is introduced in liquid form into a separation column ( 1 ), b) a liquid intermediate product which has a higher purity than the feed fraction ( 11 ) is generated in the separation column ( 1 ) by countercurrent mass transfer, c) the intermediate product ( 24 , 26 ) is withdrawn from the separation column ( 1 ) and introduced into a first liquid store ( 3 ), and being in a second operating phase a) a stream of the intermediate product from the first liquid store ( 3 ) is introduced into the separation column ( 1 ), b) by means of countercurrent mass transfer in the separation column ( 1 ), a highly pure product is produced which has a higher purity than the intermediate product, and c) the highly pure product ( 24 , 28 ) is withdrawn from the separation column ( 1 ). 2. The method according to claim 1, characterized in that the feed fraction ( 11 ) is taken from a second liquid store ( 5 ) which is connected to a system ( 6 , 7 , 8 ) for pressure build-up evaporation. 3. The method according to claim 1 or 2, characterized in that the separation column ( 1 ) has a top condenser ( 20 ) which in the first operating phase with sump liquid ( 14 , 18 ) of the separation column ( 1 ) and in the second operating phase with liquid feed fraction ( 13 ) is cooled. 4. The method according to any one of claims 1 to 3, characterized in that in the first and / or second operating phase bottom liquid ( 14 , 15 ) of the separation column ( 1 ) evaporates ( 16 ) and returned to the lower region of the separation column ( 1 ) ( 17 ) will. 5. The method according to any one of claims 1 to 4, characterized in that the intermediate product and the highly pure product are removed from the separation column ( 1 ) at the same intermediate point ( 24 ). 6. The method according to any one of claims 1 to 5, characterized in that the highly pure product ( 28 ) is introduced into a third liquid store ( 4 ). 7. Device for producing a highly pure product from a feed fraction, which consists of a less pure air component, in particular nitrogen, oxygen or argon, of medium purity, with a separation column ( 1 ) and a first liquid reservoir ( 3 ) and with a) means ( 10 , 11 ) for introducing a flow of the feed fraction in liquid form to the separation column ( 1 ) during a first operating phase, b) means for producing a liquid intermediate product which has a higher purity than the feed fraction in the separation column ( 1 ) by means of countercurrent mass transfer during the first operating phase, c) means ( 24 , 25 , 26 ) for withdrawing the intermediate product from the separation column ( 1 ) and for introducing it into the first liquid store ( 3 ) during the first operating phase, d) means for introducing a flow of the intermediate product from the first liquid store ( 3 ) into the separation column ( 1 ) during a second operating phase, e) means for producing a highly pure product, which has a higher purity than the intermediate product, by means of countercurrent mass transfer in the separation column ( 1 ) during the second operating phase and f) means ( 24 , 25 , 28 ) for withdrawing the highly pure product from the separation column ( 1 ) during the second operating phase.