EP3719433A1 - Adjustable liquid distributor of a coiled heat exchanger for implementing different liquid loads - Google Patents

Abstract

The invention relates to a heat exchanger (1), comprising: a jacket (2) which surrounds a jacket space (3) of the heat exchanger (1), the jacket space (3) being designed to accommodate a fluid first medium (M), an im Shell (3) extending core tube (4), a tube bundle (5) having a plurality of tubes (50) which are wound around the core tube (4), the tube bundle (5) designed to accommodate at least one fluid second medium (M ') is, so that heat can be transferred indirectly between the first medium (M) and the at least one second medium (M '), and a liquid distributor (6) arranged above the tube bundle (5) in the jacket space (3) for pressurizing the tube bundle (5) ) with a liquid phase (F) of the first medium (M), the liquid distributor (6) having distribution arms (60) projecting from the core tube (3) in the radial direction (R), one above the distribution arms (60) in a circumferential direction ( U) of the jacket (2) extending annular channel (61) and one collecting container (62) formed by the core tube (4), the annular channel (61) and the collecting container (62) each being designed to collect the first medium (M). According to the invention it is provided that the distribution arms (60) for applying the liquid phase (F) of the first medium (M) to the tube bundle (5) have at least one first container (60a) and at least one second container (60a) separate from the first container (60a). 60b).

Description

The invention relates to a heat exchanger and a method for operating such a heat exchanger.

Coiled heat exchangers are e.g. used in natural gas liquefaction plants. A first fluid medium is applied as a refrigerant to the shell side and evaporates by means of a falling film. This evaporation can lead to a so-called maldistribution over the tube bundle, so that some tubes receive too much refrigerant, other tubes too little. To counteract this effect, e.g. the tube side, i.e. the media carried in the tube bundle, are regulated in order to achieve a distribution of the media there which counteracts a maldistribution of the first medium or the refrigerant on the shell side. Alternatively, the first medium or the refrigerant on the shell side can also be regulated in order to compensate for a maldistribution.

When implementing a controllable liquid distributor, it is necessary to be able to apply different amounts of refrigerant to different areas of the tube bundle.

In this regard, it has been found that valves arranged in the jacket space or on the tube bundle, as well as moving parts inside the heat exchanger, can only be implemented with comparatively great effort.

The present invention is therefore based on the object of specifying a heat exchanger and a corresponding method for indirect heat transfer, which enables a particularly continuous shift of the area-related task of the first medium in a radial direction of the tube bundle and so low the cost of additional instrumentation as possible.

This object is achieved by a heat exchanger having the features of claim 1 and by a method having the features of claim 14.

Advantageous configurations of these aspects of the invention are specified in the corresponding subclaims and are described below.

• einem Mantel, der einen Mantelraum des Wärmeübertragers umgibt, wobei der Mantelraum zur Aufnahme eines fluiden ersten Mediums ausgebildet ist,
• einem im Mantelraum erstreckten Kernrohr,
• einem Rohrbündel aufweisend mehrere Rohre, die um das Kernrohr gewickelt sind, wobei das Rohrbündel zur Aufnahme zumindest eines fluiden zweiten Mediums ausgebildet ist, so dass zwischen dem ersten Medium und dem mindestens einem zweiten Medium indirekt Wärme übertragbar ist, und
• einem oberhalb des Rohrbündels im Mantelraum angeordneten Flüssigkeitsverteiler zum Beaufschlagen des Rohrbündels mit einer flüssigen Phase des ersten Mediums, wobei der Flüssigkeitsverteiler vom Kernrohr in radialer Richtung abstehende Verteilarme aufweist, einen oberhalb der Verteilarme in einer Umfangsrichtung des Mantels erstreckten Ringkanal sowie einen durch das Kernrohr gebildeten Sammelbehälter, wobei der Ringkanal und der Sammelbehälter jeweils zum Sammeln des ersten Mediums ausgebildet sind.

According to claim 1, a heat exchanger is disclosed with:

• a jacket which surrounds a jacket space of the heat exchanger, the jacket space being designed to accommodate a fluid first medium,
• a core tube extending in the shell space,
• a tube bundle having a plurality of tubes which are wound around the core tube, the tube bundle being designed to receive at least one fluid second medium, so that heat can be transferred indirectly between the first medium and the at least one second medium, and
• a liquid distributor arranged above the tube bundle in the jacket space for charging the tube bundle with a liquid phase of the first medium, the liquid distributor having distribution arms protruding from the core tube in the radial direction, an annular channel extending above the distribution arms in a circumferential direction of the jacket, and a collecting container formed by the core tube , wherein the annular channel and the collecting container are each designed to collect the first medium.

According to the invention it is provided that the distribution arms for applying the tube bundle with the liquid phase of the first medium have at least one first container and at least one second container separate from the first container, the first container being in flow connection with the annular channel so that the liquid phase of the first medium can be introduced from the annular channel into the at least one first container and can be distributed from there via outlet openings of the first container to a first region of the tube bundle, and the at least one second container is in flow connection with the collecting container, so that the liquid phase of the first medium can be introduced from the collecting container into the at least one second container and can be distributed from there to a second region of the tube bundle via outlet openings of the second container.

The distribution arms can each be designed in the shape of a sector of a circle. Furthermore, between two adjacent distribution arms in the circumferential direction of the jacket or the core tube can be separated by a gap through which the tubes of the tube bundle can be passed (e.g. towards the connection pieces provided on the jacket).

According to one embodiment of the invention, it is provided that the heat exchanger has at least one first controllable valve, via which the ring channel can be charged with the first medium, and / or that the heat exchanger has at least one second controllable valve via which the collecting container of the core tube with the first medium can be loaded.

Furthermore, according to one embodiment of the invention, it is provided that the ring channel is in flow connection with a first inlet arranged on the jacket, so that the first medium can be introduced into the ring channel via the first inlet, the first valve in particular being arranged upstream of the first inlet.

Furthermore, according to one embodiment it is provided that the collecting container of the core tube is in flow connection with a second inlet arranged on the jacket, so that the first medium can be introduced into the collecting container via the second inlet, the second valve in particular being arranged upstream of the second inlet.

Furthermore, according to one embodiment of the invention it is provided that the first container and the second container can be charged simultaneously with variable mass flows of the first medium by appropriately setting the valves.

According to a preferred embodiment of the invention it is further provided that the first container and the second container are arranged above the tube bundle that by setting the two valves the amount of liquid phase applied to the tube bundle per area and time in a radial direction of the Tube bundle is changeable or adjustable.

In this way, a particularly continuous shift in the area-related task of the liquid phase of the first medium (e.g. Refrigerant) can be achieved in the radial direction of the tube bundle, with the expense of additional instrumentation advantageously being comparatively low.

In order to efficiently adjust the distribution of the liquid phase in the radial direction by means of the container, one embodiment of the invention provides that the arrangement of the outlet openings of the first and the second container is designed so that radially different amounts of liquid can be adjusted. E.g. the second container can have outlet openings which are located further inward in the radial direction than the outlet openings of the first container. E.g. the second container only have outlet openings for an inner half of the tube bundle, while the first container only has outlet openings for the outer half of the tube bundle.

In particular, due to the arrangement of the containers above the tube bundle and by appropriately positioning the valves, the said amount can be changed or adjusted in the radial direction of the tube bundle so that the said amount increases monotonically towards the outside in a radial direction of the tube bundle or outwards decreases monotonously.

Furthermore, one embodiment of the invention provides that the at least one first container is formed by a first distribution arm of the liquid distributor, and that the at least one second container is formed by a second distribution arm of the liquid distributor.

Furthermore, according to an alternative embodiment of the invention, it is provided that the at least one first container is formed by a first area of a distribution arm, and that the at least one second container is formed by a second area of the distribution arm that is separate from the first area.

According to one embodiment it is provided in this regard that the two regions run next to one another in the radial direction along which the distributor arm extends. Here, according to one embodiment, it can furthermore be provided that the two areas are fluidically separated from one another by a partition wall of the distributor arm that extends in the radial direction.

According to an alternative embodiment, it can also be provided that the two areas are opposite one another in the radial direction along which the distributor arm extends. In this regard, it can furthermore be provided according to one embodiment that the two areas are separated from one another by a partition wall extending in a circumferential direction of the core tube.

Another aspect of the present invention relates to a method for performing an indirect heat transfer between at least a first fluid medium and a second fluid medium using a heat exchanger according to the invention, wherein the second medium is introduced into the tube bundle, and wherein a first mass flow of the first medium over the ring channel is introduced into the at least one first container, and wherein (in particular at the same time) a second mass flow of the first medium is introduced into the at least one second container via the collecting container, the two mass flows being set (e.g. using the said valves), in order to change the amount of the liquid phase of the first medium applied to the tube bundle per area and time via the outlet openings of the at least one first container and the outlet openings of the at least one second container in the radial direction of the tube bundle put.

Here, according to one embodiment of the method, it is provided that the two mass flows of the first medium are set such that the said amount of the liquid phase of the first medium increases monotonically towards the outside in a radial direction of the tube bundle or decreases monotonously towards the outside.

Fig. 1

eine schematische Schnittdarstellung einer Ausführungsform eines erfindungsgemäßen Wärmeübertragers;

Fig. 2

eine schematische Schnittdarstellung entlang der Ebene A-A der Fig. 1;

Fig. 3

eine schematische Schnittdarstellung einer weiteren Ausführungsform der Erfindung; und

Fig. 4

eine schematische Schnittdarstellung einer weiteren Ausführungsform der Erfindung.

Embodiments of the invention and further features and advantages of the invention are to be explained below with reference to the figures. Show it:

Fig. 1

a schematic sectional view of an embodiment of a heat exchanger according to the invention;

Fig. 2

a schematic sectional view along the plane AA of FIG Fig. 1 ;

Fig. 3

a schematic sectional view of a further embodiment of the invention; and

Fig. 4

a schematic sectional view of a further embodiment of the invention.

The Figure 1 shows in connection with the Figure 2 an embodiment of a heat exchanger 1 according to the invention, which makes it possible to counteract a maldistribution of a first medium M (eg a refrigerant) guided in a jacket space 3 onto a tube bundle 5 of the heat exchanger 1.

For this purpose, the heat exchanger 1 has in detail a jacket 2 which surrounds the jacket space 3, a core tube 4 which extends in the jacket space 3 and on which the tubes 50 of the tube bundle 5 are wound, the tube bundle 5 for receiving at least one fluid second medium M ' is designed so that heat can be transferred indirectly between the first medium M and the at least one second medium M '. In the manufacture of the heat exchanger 1, the core tube 4 serves in particular as the core or carrier of the tube bundle, the individual tubes 50 being wound onto the horizontally arranged core tube 4 with spacers in between. During the operation of the heat exchanger 1, the core tube 4 extends along the vertical and preferably carries at least part of the load on the tubes 50 of the tube bundle 5. The individual tubes 50 are preferably wound on or around the core tube 4, at least in sections, in a helical manner. Such a heat exchanger is therefore also referred to as a wound heat exchanger 1.

Furthermore, the heat exchanger 1 has a - in relation to the vertical or longitudinal axis z of the core tube 4 - arranged above the tube bundle 5 in the jacket space 3 liquid distributor 6 for subjecting the tube bundle 5 with a liquid phase F of the first medium M, the liquid distributor 6 from Core tube 3 has distribution arms 60 protruding in the radial direction R, which can be configured in the shape of a sector of a circle, for example in the plan view along the longitudinal axis z (see also FIG Figures 2 to 4 ). The distributor arms 60 each have a base 60g and side walls 60d extending from the respective base 60g, which, starting from the core tube 4, extend outward to the annular channel 61.

Furthermore, the liquid distributor 6 preferably has an annular channel 61 extending or encircling above the distributing arms 60 in a circumferential direction U of the casing 2 and also a collecting container 62 formed by the core tube 4, the annular channel 61 and the collecting container 62 each for collecting the first medium M, which is in particular a two-phase mixture, are formed. The first medium M can be calmed and degassed in the collecting container 62 and in the annular channel 61 or later in the containers 60a, 60b or areas 60a, 60b, so that ultimately a liquid phase F of the first medium or refrigerant M via the distribution arms 60 can be distributed over the tube bundle 5.

As from the Figures 1 and 2 As can be seen, it is provided that the distribution arms 60 form at least one first container 60a and at least one second container 60b separate from the first container 60a, the at least one first container 60a being in flow connection with the annular channel 61 so that the liquid phase F des first medium M can be introduced from the annular channel 61 into the at least one first container 60a and from there can be distributed via outlet openings 600 of a bottom 60g of the at least one first container 60a to a first area 5a of the tube bundle 5, and the at least one second container 60b is in flow connection with the collecting container 62 so that the liquid phase F of the first medium M can be introduced from the collecting container 62 into the at least one second container 60b and from there via outlet openings 601 of a bottom 60g of the at least one second container 60b to a second area 5b of the tube bundle 5 is distributable.

How particularly with the Figure 2 As can be seen, it can be provided that the liquid distributor 6 has several (here for example four) distribution arms 60, two distribution arms 60 opposite one another in the radial direction R each forming a first container 60a, which is fluidically separated from the collecting container 62 or from the core tube 4 (for example through a wall section 60f of the core tube 4) and is fed with the liquid phase F of the first medium M only from the outside via the ring channel 61, for example through an opening 61a of an inner wall 61c of the ring channel 61 Figure 2 As can be seen, the inner wall 61c lies opposite an outer circumferential wall 61b of the annular channel 61, both walls extending from a base 61d of the annular channel 61. The ring channel 61 can also be attached to the jacket 2 so that, for example, the outer wall 61b can be formed by the jacket 2.

Furthermore, two further distribution arms 60 opposite one another in the radial direction R each form a second container 60b, the respective second container 60b, in contrast to the respective first container 60a, being fluidically separated from the annular channel 61 (e.g. by a section 60e of the inner wall 61c of the annular channel 61) and is only fed with the liquid phase of the F of the first medium M from the inside via the collecting container 62 or the core tube 4. For this purpose, a wall of the core tube 4 can each have a corresponding opening 4a. The containers 60a, 60b are each assigned to an area 5a or 5b of the upper side of the tube bundle 5 (cf. Fig. 1 ), so that the distribution of the liquid phase F on the tube bundle 5 can be influenced by different liquid delivery to the areas 5a, 5b.

In order to influence the distribution of the liquid phase F, e.g. it can be provided that the first and second containers 60a, 60b allow different liquid levels and thus also different volume flows. Furthermore, the arrangement of the outlet openings 600, 601 of the first and second containers 60a, 60b can be designed such that radially different amounts of liquid can be set. E.g. The second containers 60b connected to the core tube 4 can have outlet openings 601 which are located further inward in the radial direction R than the outlet openings 600 of the first container 60a. E.g. the second containers 60b only have outlet openings 601 for an inner half of the tube bundle 5 and the first containers 60a connected to the annular channel 61 can only have outlet openings 600 for the outer half of the tube bundle 5. The outlet openings 600, 601 can here also be varied in size or an overlap of the outlet openings 600 of the first container 60a with the outlet openings 601 of the second container 60b with respect to the radial direction can be provided.

How Figure 1 also shows, it is preferably provided that the ring channel 61 can be charged with the first medium M via a first valve 7 and via the subsequent first inlet or connector 9, so that a corresponding mass flow of the first medium M into the ring channel 61 and the first Container or distribution arms 60a can be regulated accordingly. It is also provided that the collecting container 62 can be charged with the first medium M via a second valve 8 and via the subsequent second inlet or connection 10, which is provided centrally above the collecting container 62 on the jacket 2, so that a corresponding mass flow of the first medium M in the collecting container 62 or the second container or distribution arms 60b can also be regulated accordingly.

By appropriately setting the valves 7, 8 or regulating the two mass flows of the first medium M, the amount of liquid phase F that is applied along the radial direction R of the tube bundle 5 to the tube bundle 5 or the areas 5a, 5b can be varied in order to counteract a maldistribution of the liquid phase F in the jacket space 3.

In the embodiment according to Figure 2 the distribution arms 60 are therefore fed from the outside via the annular channel 61 (first container 60a) or from the inside via the collecting container 62 provided in the core tube 4 (second container 60b) in order to vary the liquid discharge to the tube bundle 5 in the radial direction R if necessary . to adjust.

Figure 3 shows an alternative embodiment of the liquid distributor 6, wherein the at least one first container 60a is formed by a first area 60a of a distribution arm 60, and wherein the at least one second container 60b is formed by a second area 60b of the same distribution arm 60 which is fluidically separated from the first area 60a is. Here is according to Figure 3 preferably provided that the two areas 60a, 60b in the radial direction R, along which the distribution arm 60 extends, run next to one another from the core tube 4 to the jacket 2, the two areas 60a, 60b preferably extending through one in the radial direction R. Partition 60c of the distributor arm 60 are fluidically separated from one another. In this case, the first area 60a is again supplied with the liquid phase F of the first medium M from the outside via the ring channel 61, in particular via an opening 61a in the inner wall 61c of the ring channel 61 Wall section 60f of core tube 4 is fluidically separated from core tube 4 or collecting container 62.

The at least one second region 60b, on the other hand, is supplied with the liquid phase F of the first medium M from the collecting container 62 via an opening 4a of the core tube 4 and is e.g. Fluidically separated from the annular channel 61 by a section 60e of the inner wall 61c of the annular channel 61.

In particular, according to Figure 3 all (eg four) distribution arms 60 are divided in this way into separate first and second areas 60a, 60b.

Also with the Figure 3 the annular channel 61 is variably supplied with the liquid phase F via the first valve 7, whereas the collecting container 62 is variably supplied with the liquid phase F of the first medium M via the second valve 8.

By appropriately setting the valves 7, 8 or regulating the two mass flows of the first medium M in the annular channel 61 or in the collecting container, the amount of liquid phase F, which along the radial direction R of the tube bundle 5 on the tube bundle 5 or The areas 5a, 5b given up are varied in order to counteract a maldistribution of the liquid phase F in the jacket space 3.

Here again, according to one embodiment, it is provided that the outlet openings 600, 601 of the first and second containers 60a, 60b are designed such that radially different amounts of liquid can be set. E.g. The second containers 60b connected to the core tube 4 can have outlet openings 601 which are located further inward in the radial direction R than the outlet openings 600 of the first container 60a. E.g. the second containers 60b only have outlet openings 601 for an inner half of the tube bundle 5 and the first containers 60a connected to the annular channel 61 can only have outlet openings 600 for the outer half of the tube bundle 5 (see above).

Fig. 4 shows a further variant of a heat exchanger 1 according to the invention, the at least one first and the at least one second area 60a, 60b again being formed by a distributor arm, in which case, in contrast to FIG Figure 3 the partition wall 60c, which separates the two areas 60a, 60b from one another in terms of flow, extends in the circumferential direction U of the jacket 2 or of the core tube 4, so that the two areas 60a, 60c extend in the radial direction R, along which the distribution arm extends from the core tube to the jacket 2, are opposite one another. The first area is supplied with the liquid phase F via an opening 61a in the inner wall 61c of the annular channel, whereas the second area 60b is supplied with the liquid phase F from the collecting container 62 via an opening 4a in the core tube 4. In this case, the outlet openings 600 of the first container 60a lie further outside in the radial direction R than the outlet openings 601 of the second container 60b.

In particular, according to Figure 4 in turn, all (for example four) distribution arms 60 are divided in this way into separate first and second areas 60a, 60b.

As before, the ring channel 61 is according to FIG Figure 4 variably supplied with the liquid phase F via the first valve 7, whereas the collecting container 62 is variably supplied with the liquid phase F of the first medium M via the second valve 8.

By appropriately setting the valves 7, 8 or regulating the two mass flows of the first medium M in the annular channel 61 or in the collecting container 62, the amount of liquid phase F that is flowing along the radial direction R of the tube bundle 5 onto the tube bundle 5 or the areas 5a, 5b abandoned are varied in order to counteract a maldistribution of the liquid phase F in the shell space 3. If e.g. If the mass flow of the first medium M in the collecting container 62 is increased or decreased in the annular channel 61, more liquid F is applied to the tube bundle 5 via the inner second areas 60b than via the outer first areas 60a.

Because of the liquid distributor according to the invention, it is possible to react optimally to any influence on the part of the process and to counteract a maldistribution on the shell side, so that the overall performance of the heat exchanger is improved.

The two areas 60a, 60b can also be implemented via a divided ring channel 61 (e.g. two semicircular ring channels or two concentric ring channels) or a divided core tube 4 (e.g. concentric core tube plugged into one another or core tube divided in diameter). The distribution arms 60 can also have any other spatial separation. Furthermore, more than two valves or containers can be used to adjust the liquid distribution in the radial direction of the tube bundle.

Claims (14)

Heat exchanger (1), with: - A jacket (2) which surrounds a jacket space (3) of the heat exchanger (1), the jacket space (3) being designed to receive a first fluid medium (M), - a core tube (4) extending in the shell space (3), - A tube bundle (5) having a plurality of tubes (50) which are wound around the core tube (4), the tube bundle (5) being designed to receive at least one fluid second medium (M '), so that between the first medium ( M) and the at least one second medium (M ') heat can be transferred indirectly, - A liquid distributor (6) arranged above the tube bundle (5) in the jacket space (3) for subjecting the tube bundle (5) to a liquid phase (F) of the first medium (M), the liquid distributor (6) from the core tube (3) has distribution arms (60) protruding in the radial direction (R), an annular channel (61) extending above the distribution arms (60) in a circumferential direction (U) of the casing (2) and a collecting container (62) formed by the core tube (4), wherein the annular channel (61) and the collecting container (62) are each designed to collect the first medium (M), characterized,
that the distribution arms (60) for applying the tube bundle (5) with the liquid phase (F) of the first medium (M) form at least one first container (60a) and at least one second container (60b) separated from the first container (60a), wherein the at least one first container (60a) is in flow connection with the annular channel (61) so that the liquid phase (F) of the first medium (M) can be introduced from the annular channel (61) into the at least one first container (60a) and can be distributed from there via outlet openings (600) of the at least one first container (60a) to a first area (5a) of the tube bundle (5), and the at least one second container (60b) is in flow connection with the collecting container (62) so that the liquid phase (F) of the first medium (M) can be introduced from the collecting container (62) into the at least one second container (60b) and from there via outlet openings (601) of the at least one second container (60b) can be distributed over a second region (5b) of the tube bundle (5). Heat exchanger according to one of the preceding claims, characterized in that the heat exchanger (1) has a first valve (7) via which the annular channel (61) can be charged with the first medium (M), and / or that the heat exchanger (1) has a second valve (8) through which the collecting container (62) of the core tube (4) can be charged with the first medium (M). Heat exchanger according to one of the preceding claims, characterized in that the annular channel (61) is in flow connection with a first inlet (9) arranged on the jacket (2), so that the first medium (M) into the first inlet (9) Annular channel (61) can be introduced, in particular the first valve (7) being arranged upstream of the first inlet (9). Heat exchanger according to one of the preceding claims, characterized in that the collecting container (62) of the core tube (4) is in flow connection with a second inlet (10) arranged on the jacket (2), so that the first medium (M) via the second inlet (10) can be introduced into the collecting container (62), the second valve (8) in particular being arranged upstream of the second inlet (10). Heat exchanger according to one of the preceding claims, characterized in that the at least one first container (60a) and the at least one second container (60b) are arranged above the tube bundle (5) that by setting the two valves (7, 8) the amount of liquid phase (F) of the first medium (M) applied to the tube bundle (5) per area and time can be changed in a radial direction (R) of the tube bundle (5). Heat exchanger according to one of the preceding claims, characterized in that the at least one first container (60a) and the at least one second container (60b) by appropriately setting the valves (7, 8) can be charged with variable mass flows of the first medium (M) at the same time. Heat exchanger according to one of the preceding claims, characterized in that the at least one first container (60a) is formed by a first distribution arm (60) of the liquid distributor (6), and that the at least one second container (60b) is formed by a second distribution arm (60 ) of the liquid distributor (6) is formed. Heat exchanger according to one of claims 1 to 6, characterized in that the at least one first container (60a) is formed by a first region (60a) of a distribution arm (60), and that the at least one second container (60b) is formed by one of the first Area (60a) separate second area (60b) of the distribution arm (60) is formed. Heat exchanger according to Claim 8, characterized in that the two regions (60a, 60b) run next to one another in the radial direction (R) along which the distributor arm (60) extends. Heat exchanger according to Claim 8 or 9, characterized in that the two areas (60a, 60b) are separated from one another by a partition (60c) of the distributor arm (60) extending in the radial direction (R). Heat exchanger according to Claim 8, characterized in that the two regions (60a, 60b) lie opposite one another in the radial direction (R) along which the distributor arm (60) extends. Heat exchanger according to Claim 8 or 11, characterized in that the two areas (60a, 60b) are separated from one another by a partition (60c) extending in a circumferential direction (U) of the core tube (4). Heat exchanger according to one of the preceding claims, characterized in that one or more of the outlet openings (600) of the at least one first container (60a) lie further outward in the radial direction of the tube bundle (R) than the outlet openings (601) of the at least one second Container (60b), or that one or more of the outlet openings (601) of the at least one second container (60b) lie further outward in the radial direction of the tube bundle (R) than the outlet openings (600) of the at least one first container (60a). Method for carrying out an indirect heat transfer between at least one first fluid medium (M) and a second fluid medium (M ') using a heat exchanger (1) according to one of the preceding claims, wherein the second medium (M') into the tube bundle (5 ) is initiated, and wherein a first mass flow of the first medium (M) is introduced via the annular channel (61) into the at least one first container (60a), and wherein a second mass flow of the first medium (M) via the collecting container (62) is introduced into the at least one second container (60b), the two mass flows being adjusted to reduce the per area and time via the outlet openings (600, 601) of the at least one first container (60a) and the at least one second container (60b) to change the amount of liquid phase (F) of the first medium (M) applied to the tube bundle (5) in a radial direction (R) of the tube bundle (5).

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