EP1283401A1 - Multistoreyed bath condensor - Google Patents

Abstract

Recirculating condenser comprises a condenser block with liquefying passages for nitrogen and at least one recirculating section with two sets of evaporation passages (1) for oxygen. The entry (2) and exit (3) for each evaporation passage is on opposite sides of the block and the entry is at a lower level than the exit. Recirculating condenser comprises a condenser block with liquefying passages for nitrogen and at least one recirculating section with two sets of evaporation passages (1) for oxygen. The entry (2) and exit (3) for each evaporation passage is on opposite sides of the block and the entry is at a lower level than the exit. The entry openings into the first set of evaporation passages are on the same side of the condenser block as the exit openings from the second set of evaporation passages. All the evaporation passages of the first set and/or the second set are of the same length, and both sets have the same number of passages with the same cross section.

Description

The invention relates to a circulating capacitor with a capacitor block, the Liquefaction passages for a heating medium and at least one circulation section with evaporation passages for a liquid, the Inlet opening and the outlet opening of each evaporation passage opposite sides of the capacitor block and where the Inlet openings of all evaporation passages of the circulation section below the Outlet openings of the evaporation passages of the circulation section are arranged are.

In a low-temperature air separation plant with one pressure column and one Low pressure column is opposed to liquid oxygen from the low pressure column gaseous nitrogen from the pressure column in indirect heat exchange in one Heat exchanger evaporates, the nitrogen condensing. Such a thing Condenser-evaporator system is usually referred to as the main condenser.

The main condenser is manufactured almost exclusively as a plate heat exchanger and designed as a falling film evaporator or as a circulation condenser. At a Circulating condenser stands the condenser block in the liquid bath from which Liquid should be evaporated. The liquid enters from below Evaporation passages of the condenser block and is partially against that heating medium flowing through the liquefaction passages evaporates. The density of the medium evaporating in the evaporation passages is less than the density of the surrounding liquid bath, which creates a siphon effect, so that Liquid flows from the liquid bath into the evaporation passages.

Liquid oxygen is evaporated in the main condenser of an air separation plant. It is important to ensure that the evaporation passages of the Condenser blocks flowing in liquid oxygen evaporates only to a fraction becomes. This prevents possible liquid oxygen existing interfering impurities are enriched. So be for example, only about 10% of those flowing into the evaporation passages Amount of liquid oxygen evaporates and 90% as liquid from the Outlet openings of the evaporation passages back to the inlet openings of the Evaporation passages promoted. The part of the capacitor block in which such Circulation of liquid is achieved, hereinafter referred to as the circulation section designated.

The greater the immersion depth of the capacitor block of a circulation capacitor in the Is liquid bath, the higher the mean hydrostatic pressure in the Evaporation passages and the worse the liquid evaporates because the The boiling point of the liquid increases according to the vapor pressure curve. The Efficiency of a circulation condenser can, however, by dividing the Capacitor blocks increased in several circulation sections arranged one above the other become. The advantage of such an arrangement is that the immersion depth of the individual circulation sections is in each case less than a single high one Capacitor bank. The hydrostatic pressure in the Evaporation passages are reduced and the liquid can evaporate more easily.

From DE 199 39 294 a multi-storey circulation condenser is known, in which the inlet openings and the outlet openings of the evaporation passages a circulation section on opposite sides of the heat exchanger block are located. In this way you can achieve the same length in all evaporation passages Flow paths for the liquid oxygen to be evaporated. This has the advantage that the pressure losses and thus the circulation rates in all evaporation passages are the same. On the other hand, this arrangement has the disadvantage that the rotating liquid oxygen quantity always on the opposite of the inlet openings Side of the condenser block emerges and over structurally complex pipes or channels must be returned to the entry openings.

The object of the present invention is therefore to provide a circulation condenser develop in which the evaporation passages are as uniform as possible Evaporation of the liquid is achieved and with as little as possible constructive effort.

This task is performed by a circulation capacitor of the type mentioned solved, are provided in the first and second evaporation passages and themselves the inlet openings of the first evaporation passages and the outlet openings the second evaporation passages on the same side of the condenser block are located.

According to the invention, the liquid enters the first evaporation passages from below , flows upwards in the evaporation passages, partially evaporates and leaves the first evaporation passages on the opposite side of the Capacitor block. The liquid portion of the from the first evaporation passages escaping liquid-gas mixture flows to those on the same side as that Outlet openings of the first evaporation passages arranged inlet openings the second evaporation passages. The liquid then flows through the second Evaporation passages back to the side of the condenser block where the Entry openings are located in the first evaporation passages. During the Flow through the second evaporation passages again becomes part of the Liquid evaporates.

According to the invention, the liquid is by means of the first and second Evaporation passages between two opposite sides of the Condenser blocks back and forth conveyed and increasingly evaporated. Elaborate constructions such as return pipes or return channels for the liquid are therefore no longer necessary.

The evaporation passages are designed so that there are all inlet openings a circulation section below the outlet openings of this circulation section are located. In this way, one can in front of the inlet openings Liquid level should be chosen so that the liquid can flow in through the inlet openings all evaporation passages occur, but the outlet openings end in the gas space. This has the advantage that the ascending in the evaporation passages Liquid-gas mixture in all evaporation passages the same back pressure experiences, which in turn different circulation rates in the individual Evaporation passages are avoided.

If the liquid level in front of the inlet openings is chosen to be high enough that the static pressure at the individual inlet openings decreases by less than 20%, preferably less than 10%, particularly preferably less than 5%, so circulation rates are almost the same through all evaporation passages.

All of the first and / or all of the second evaporation passages are preferably one Orbital section of the same length. Most preferably all Evaporation passages of a circulation section of the same length. In this way the circulation rate is the same in all evaporation passages, i.e. in every Evaporation passage presents the same ratio of non-evaporated liquid amount of gas evaporated. As a result, the liquid to be evaporated is always well mixed and any impurities do not accumulate in the liquid on.

In a preferred embodiment, a circulation section has the same number of first ones like second evaporation passages. It is also beneficial if everyone Evaporation passages have the same cross section. By this measure it ensures that just as much fluid flows through the first Evaporation passages as promoted by the second evaporation passages.

The circulation condenser according to the invention is particularly suitable as Main condenser of a cryogenic air separation plant.

Figur 1

die Verdampfungspassagen eines erfindungsgemäßen Umlaufabschnittes,

Figur 2

die Ansicht A von Figur 1,

Figur 3

die Ansicht A einer alternativen Ausführungsform von Figur 1,

Figur 4

einen Umlaufkondensator mit vier übereinander angeordneten Umlaufabschnitten,

Figur 5

die Draufsicht auf Figur 4,

Figur 6

ein Kondensatorverdampfersystem mit vier parallel angeordneten Kondensatorblöcken, die jeweils aus vier übereinander angeordneten Umlaufabschnitten bestehen,

Figur 7

ein Schnitt entlang der Linie A-A in Figur 6,

Figur 8

die Draufsicht auf die Kondensatorblöcke gemäß Figur 6,

Figur 9

ein Schnitt entlang der Linie A-A in Figur 6 mit einer alternativen Anordnung der Verdampfungspassagen und

Figur 10

die Draufsicht auf die Anordnung der Verdampfungspassagen gemäß Figur 9.

The invention and further details of the invention are explained in more detail below with reference to the exemplary embodiments shown schematically in the drawings. Here show:

Figure 1

the evaporation passages of a circulation section according to the invention,

Figure 2

the view A of Figure 1,

Figure 3

the view A of an alternative embodiment of Figure 1,

Figure 4

a circulation condenser with four circulation sections arranged one above the other,

Figure 5

the top view of Figure 4,

Figure 6

a condenser-evaporator system with four condenser blocks arranged in parallel, each consisting of four circulation sections arranged one above the other,

Figure 7

6 shows a section along the line AA in FIG. 6,

Figure 8

the top view of the capacitor blocks according to Figure 6,

Figure 9

a section along the line AA in Figure 6 with an alternative arrangement of the evaporation passages and

Figure 10

the top view of the arrangement of the evaporation passages according to FIG. 9.

In Figure 1, a circulation section of a circulation condenser is shown schematically, the main capacitor of a double column in one Cryogenic air separation plant is used to evaporate oxygen. The circulation condenser has a multiplicity of arranged in parallel Heat exchange passages in which gaseous nitrogen in the indirect Heat exchange with liquid oxygen is condensed, the oxygen evaporated.

The liquefaction passages for the nitrogen, not shown in FIG. 1, extend from top to bottom over the entire height of the circulation condenser. to Conduction of oxygen are two different types of evaporation passages 1, 11 provided. In the drawing, the limitations are the first Evaporation passages 1 with solid lines that the second Evaporation passages 11 shown with dashed lines.

In the illustration according to FIG. 1, the first evaporation passages 1 have at the lower left end of the circulation section their entry openings 2 and on the right upper end of their outlet openings 3. The second evaporation passages 11 run opposite from bottom right to top left. The single ones Evaporation passages 1, 11 run from the respective inlet opening 2, 12 first horizontally, then vertically upwards and finally horizontally the outlet openings 3, 13. This design ensures that all Evaporation passages each have the same length.

Figure 2 shows the view of the side labeled "A" in Figure 1 Circulation section. The liquefaction passages 4 for the nitrogen and the Evaporation passages 1, 11 for the oxygen alternate to one if possible to achieve good heat exchange between the nitrogen and the oxygen. The first evaporation passages 1 are located in one half of the Circulation section, the second evaporation passages 11 in the other half. Correspondingly, the inlet openings 2 of the first are in the right half of FIG Evaporation passages 1 and in the left half of FIG. 2 the outlet openings 13 of the second evaporation passages 11.

An alternative arrangement of the evaporation passages 1, 11 is shown in FIG. The evaporation passages 1, 11 alternate with the Liquefaction passages 4 from. In contrast to the arrangement according to FIG. 2 but now also the first evaporation passages 1 and the second Evaporation passages 11 arranged alternately, with one first evaporation passage 1 and a second evaporation passage 11 each a liquefaction passage 4 is located. In other words: according to the representation Figure 1 repeats the following in a direction perpendicular to the sheet plane Passage arrangement multiple: one level with nitrogen passages 4, followed by bottom left to top right first evaporation passages 1 followed from a further level with nitrogen passages, to which finally from the right Connect the second evaporation passages 11 running down to the top left.

Figure 4 shows a section through a circulation condenser according to the invention, the as the main condenser of a double column in a cryogenic air separation plant is used. The circulation condenser consists of four superimposed ones Circulation sections 100, 200, 300, 400. At those with inlet and outlet openings, e.g. 402, 403, 412, 413, provided sides of each circulation section 100, 200, 300, 400 liquid containers 120, 220, 320, 420 are respectively attached.

On one side of the condenser block are the liquid containers 120, 220, 320, 420 connected to each other by means of an overflow line 21. The overflow line 21 has an entry opening at the level of each circulation section 100, 200, 300, 400 122, 222, 322, 422, so that at a certain level in the respective Liquid container 120, 220, 320, 420 liquid enters the overflow pipe 21 and in the liquid container 120, 220, 320 of the underlying circulation section 100, 200, 300 is passed.

The inlet openings 122, 222, 322, 422 in the overflow line 21 are on one provided that the maximum fill level in the Liquid containers 120, 220, 320, 420 between 50 and 90%, preferably between 60 and 80% of the height of the respective circulation section 100, 200, 300, 400 lies. The inlet openings 122, 222, 322, 422 are particularly preferred Overflow line 21 attached so that the maximum liquid level in the Liquid containers 120, 220, 320, 420 below the outlet openings 3, 13 located.

The inventive arrangement of all inlet openings 2, 12 below the Outlet openings 3, 13 of the respective circulation section can be a liquid level can be selected in the liquid containers 120, 220, 320, 420, which is between the top inlet opening 2, 12 and the bottom outlet opening 3, 13. So will ensures that all evaporation passages 1, 11 at their entrance 2, 12 in Liquid and at their outlet 3, 13 are in the gas space. The back pressure on Outlet end 3, 13 is therefore the same for all evaporation passages 1, 11, so that in an approximately the same circulation rate is achieved in all evaporation passages 1, 11.

The liquid containers 120, 220, 320, 420 are also two Gas collecting lines 23 penetrates, so that the evaporation in the Evaporation passages 1, 11 emerging and into the liquid containers 120, 220, 320, 420 flowing oxygen gas from the liquid containers 120, 220, 320, 420 can be withdrawn via the gas manifold 23.

In Figure 5, the arrangement of the gas manifolds 23 and the overflow pipe 22 in the top view. The first and second evaporation passages 1, 11 are in each circulation section 100, 200, 300, 400 as explained above with reference to FIG. 2, arranged. The first are in the illustration according to FIG Evaporation passages 1 in the lower half of the drawing, the second Evaporation passages 11 in the upper half of the drawing. Accordingly, by the first evaporation passages 1 liquid from left to right and through the second evaporation passages 11 transported from right to left.

The gas manifolds 23 are arranged so that they are not in front of the Exit openings of the evaporation passages 1, 11 are located. Through the side Displacement of the gas manifolds 23 with respect to the outlet openings 3, 13 of the Evaporation passages 1, 11 becomes the evaporation passages 1, 11 escaping gas-liquid mixture is first deflected, the Flow rate of the gaseous oxygen reduced and more gaseous is separated from liquid oxygen. An entrainment of liquid oxygen in the Gas manifold 23 is largely avoided.

The entire liquid is always in a circulation section 100, 200, 300, 400 one side to the other side of the circulation section 100, 200, 300, 400 and again promoted back and mixed optimally. It is therefore only on one side of the Condenser blocks a liquid overflow 21 necessary. This overflow 21 will preferably arranged on the side of the capacitor block on which the Liquid oxygen 25 is supplied.

The nitrogen passages, not shown, extend over the entire height of the Capacitor blocks, that is, over all circulation sections 100, 200, 300, 400. The Gaseous nitrogen is supplied to the nitrogen passages via the feed line 26 and withdrawn as liquid at the lower end of the block via line 27. The distribution of the gaseous nitrogen on the nitrogen passages takes place via a with the Capacitor block connected manifold 28.

Another variant of the invention is shown in FIGS Circulating capacitor shown. This consists of four capacitor blocks 61, 62, 63, 64, which in turn each have four circulation sections 100, 200, 300, 400. Two capacitor blocks 61, 62 and 63, 64 are arranged directly next to each other, so that the respective evaporation passages 1, 11 run parallel to one another. The double blocks 61, 62 and 63, 64 which are formed in this way are Outlet openings 2, 3, 12, 13 opposite (see Figure 8). The arrangement of the first and second evaporation passages 1, 11 again correspond to Figure 2. Die Capacitor blocks 61 and 62 or 63 and 64 are arranged side by side so that their block halves provided with the first evaporation passages 1 contiguous.

The two double blocks 61, 62 and 63, 64 each have a common one Liquid container 20. In the middle between the capacitor blocks 61, 62, 63, 64 there is a common to all blocks for each circulation section 200, 300, 400 Liquid containers 30. The outer liquid containers 20 collect only those circulating liquid that through the second evaporation passages 11 in the Liquid container 20 is passed and promote it over the first Evaporation passages 1 back into the central liquid container 30.

Due to the described arrangement of the evaporation passages 1, 11, the Supply of the gas-liquid mixture emerging from the first evaporation passages 1 essentially in the middle of the liquid container 30. The Gas manifolds 23 are therefore in the outer region of the liquid container 30 near the entry openings into the second evaporation passages 11 arranged. In these zones, the flow rate from the first evaporation passages 1 escaping gas-liquid mixture so far soothes that practically no liquid is entrained in the gas manifolds 23 becomes.

FIGS. 9 and 10 show an alternative arrangement of the evaporation passages 1, 11 with an arrangement of the capacitor blocks 61, 62, 63, 64 according to FIG. 6. Just as with the system according to FIGS. 6 to 8, this is where it starts Orbital section from the corresponding sections 100, 200, 300, 400 of the four Capacitor blocks 61, 62, 63, 64 together. In this case, however, not everyone owns of blocks 61, 62, 63, 64 first evaporation passages 1 and second Evaporation passages 11.

The flow according to the invention through first evaporation passages 1 and Backflow through second evaporation passages 11 will not occur in each one Block 61, 62, 63, 64 realized, but in that the two neighboring Capacitor blocks 61, 62 and 63, 64, each rotated by 180 °, joined together become. The evaporation passages of the condenser block 61 and 63 correspond the second evaporation passages 11 and the evaporation passages in the Condenser blocks 62 and 64 correspond to the first evaporation passages 1.

Claims (7)

Circulation condenser with a condenser block, which has liquefaction passages for a heating medium and at least one circulation section with evaporation passages for a liquid, the inlet opening and the outlet opening of each evaporation passage being on opposite sides of the condenser block and the inlet openings of all evaporation passages of the circulation section below the outlet openings of the evaporation passages Circulation section are arranged, characterized in that first and second evaporation passages (1, 11) are provided and the inlet openings (2) of the first evaporation passages (1) and the outlet openings (13) of the second evaporation passages (11) are on the same side of the condenser block are located. Circulation condenser according to claim 1, characterized in that all first evaporation passages (1) and / or all second evaporation passages (11) are of the same length. Circulation condenser according to one of claims 1 or 2, characterized in that the circulation section (100, 200, 300, 400) has as many first as second evaporation passages (1, 11). Circulating condenser according to one of claims 1 to 3, characterized in that all first and / or all second evaporation passages (1, 11) have the same cross section. Circulation condenser according to one of claims 1 to 4, characterized in that no second evaporation passage (11) is arranged between two first evaporation passages (1) Circulating condenser according to one of claims 1 to 5, characterized in that exactly a second evaporation passage (11) is arranged between two first evaporation passages (1). Use of a circulation condenser according to one of claims 1 to 6 as Main condenser of a cryogenic air separation plant.

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