EP2944909A1 - Heat exchanger with channels for damping movements of liquids - Google Patents

Abstract

The invention relates to a heat exchanger (1) for indirect heat transfer between a first medium (M1) and a second medium (M2), comprising: a jacket (2) having a jacket space (3) for receiving a liquid phase (F1) of the first Medium (M1), and at least one heat exchanger block (4), the first heat transfer passages for receiving the first medium (M1) and second heat transfer passages for receiving the second medium (M2), so that between the two media (M1, M2) indirectly Heat is transferable, wherein the at least one heat exchanger block (4, 5) is arranged in the jacket space (3), that it with a in the shell space (3) located liquid phase (F1) of the first medium (M1) is umvorbar. According to the invention, a plurality of parallel cylindrical channels (10) for guiding the liquid phase of the first medium (M1) is provided in the jacket space (3) laterally of the at least one heat exchanger block (4).

Description

The invention relates to a heat exchanger for indirect heat transfer between a first medium and a second medium according to the Anspruch1.

Such a heat exchanger usually has a jacket (also called "shell"), which defines a jacket space for receiving a liquid phase of the first medium, and at least one heat exchanger block (also referred to as "core" or "block"), the first Heat transfer passages for receiving the first medium and second heat transfer passages for receiving the second medium, so that between the two media indirectly heat transferable, wherein the heat transfer block is arranged in the jacket space, that it is umvorbar with a located in the shell space liquid phase of the first medium ,

Such a heat exchanger is for example in " The standards of the brazed aluminum plate-fin heat exchanger manufacturer's association (ALPEMA) ", third edition, 2010, page 67 shown in Figure 9-1. Such a design of a heat exchanger is also called "core-in-shell" or "block-in-shell" heat exchanger.

The driving force for the flow through the at least one heat exchanger block with the first medium (eg refrigerant) is preferably generated by the thermosiphon effect due to the evaporation itself. However, the jacket space of the heat exchanger not only fulfills the purpose of an original container, but also serves as a separating apparatus for separating the generated vapor of the first medium from the refrigerant liquid and the liquid phase of the first medium, respectively. As a result of the system, a free surface of the liquid phase of the first medium forms in the shell space. The jacket of the heat exchanger, which is preferably cylindrical in shape, can be oriented both horizontally and vertically as far as the orientation of the longitudinal or cylindrical axis is concerned. The heat exchanger block is flowed through mainly by the refrigerant liquid mainly upwards. The flow direction of the stream to be cooled (second medium) is not restricted in particular.

If the heat exchanger on a mobile surface, e.g. Therefore, the well-known problems associated with partially liquid-filled containers may arise, in particular, the liquid may reciprocate in the container space so that e.g. At several locations in the mantle space, time-varying levels result. As a result, e.g. the immersion depth of the heat exchanger blocks into the liquid phase of the first medium, which is e.g. may affect the effectiveness of heat transfer. If possible, therefore, the liquid movement of the bath is to be damped so far that a safe and reliable operation can be guaranteed.

Proceeding from this, therefore, the present invention seeks to provide a heat exchanger of the type mentioned, which reduces the above problem.

This problem is solved by a heat exchanger with the features of claim 1.

Thereafter, it is provided that a plurality of parallel cylindrical channels for guiding the first medium is provided in the lateral space laterally to the at least one heat exchanger block, which in particular are in flow connection only with the bath or the liquid phase.

Cylindrical here means in the general sense that the base of the cylinder, which in the present case is the cross-sectional area of the channel can be any flat surface, which may be circular (circular cylinder), rectangular, square, triangular or hexagonal in particular. The respective cylinder is formed by displacement of that flat surface along a straight line or longitudinal axis, which does not lie in the plane of the flat surface and preferably runs normal to that flat surface or cross-sectional surface.

The individual channels are furthermore preferred over their circumference by walls, and preferably in the form of circumferential walls, in particular completely closed walls, separated from each other. In such completely closed walls, the medium flowing in the respective channel along the longitudinal axis of the channel can not enter an adjacent channel (transverse to the longitudinal axis).

It is possible that a channel, some channels or all channels have a separate, own circumferential wall. There is also the possibility that a wall of a channel also forms part of a wall of an adjacent channel. This can also apply to several or all channels.

Because of the solution according to the invention, the liquid phase of the first medium in the jacket space of the heat exchanger can advantageously be calmed in fluctuating movements of the heat exchanger. In this context, a fluctuating movement is understood in particular to mean a movement in which the longitudinal or cylindrical axis of the jacket alters its spatial position or inclination, in particular periodically (for example, due to the sea in an arrangement of the heat exchanger on a float on a body of water).

Are the channels - based on a designated heat exchanger, which is assumed in the following - e.g. Aligned along the vertical, the liquid phase during operation of the heat exchanger at the upper end of the heat exchanger block exit and flow through the channels laterally back to the heat exchanger block. The channels thereby represent a flow resistance in the horizontal direction, which suppresses a movement of the liquid phase of the first medium along the horizontal.

In the case of horizontally oriented channels, the liquid phase may flow back and forth in the channels during fluctuating movements of the heat exchanger, the channels also acting as flow resistors in the horizontal direction due to the limited flow cross section and therefore damping a corresponding movement of the liquid phase of the first medium , If the longitudinal axes of the parallel channels are aligned horizontally, in particular a liquid movement is damped, which results from a fluctuating movement in which the inclination of the longitudinal axes changes.

In principle, the at least one heat exchanger block can be any possible heat exchanger, which in particular can transfer heat indirectly from the second medium to the first medium.

Preferably, however, the heat exchanger block is a plate heat exchanger. Such plate heat exchangers generally have a plurality of mutually parallel plates or plates, which form a plurality of heat transfer passages for participating in the heat transfer media. A preferred embodiment of a plate heat exchanger has a plurality of heat conducting structures, e.g. in the form of average meandering, in particular corrugated or folded sheets (so-called fins), which are each arranged between two parallel partition plates or sheets of Plattenwärmeübertragers, wherein the two outermost layers of the Plattenwärmeübertragers are formed by cover plates. In this way, a plurality of parallel channels or a heat transfer passage are formed between each two partition plates or between a partition plate and a cover plate due to the respective interposed fin, through which a medium can flow. Heat transfer may therefore take place between the media flowing in adjacent heat transfer passages, the heat transfer passages associated with the first medium being referred to as first heat transfer passages and the heat transfer passages associated with the second medium correspondingly being referred to as second heat transfer passages.

To the sides are provided between each two adjacent partition plates or between a cover plate and the adjacent partition plate preferably end strips (so-called side bars) for closing the respective heat transfer passage. The first heat transfer passages are open along the vertical upwards and downwards and in particular not closed by end strips, so that the liquid phase of the first medium from below can get into the first heat transfer passages and top of the plate heat exchanger from the first heat transfer passages as liquid and / or gaseous Phase can escape.

The cover plates, separator plates, fins and side bars are preferably made of aluminum and are used e.g. soldered together in an oven. Via corresponding headers with nozzles media such as e.g. the second medium are introduced into or removed from the associated heat transfer passages.

The jacket of the heat exchanger can in particular have a circumferential, (circular) cylindrical wall, which is preferably aligned with a heat exchanger arranged as intended, so that the longitudinal axis or cylinder axis of the wall or the jacket extends along the horizontal or along the vertical. At the front, the jacket preferably has mutually opposite walls connected to that wall, which extend transversely to the longitudinal axis or cylinder axis.

With regard to the mode of operation of the heat exchanger, as already explained, it is preferably provided that the at least one plate heat exchanger is designed to cool the second medium guided in the second heat transfer passages against the first medium guided in the adjacent first heat transfer passages and / or at least partially to liquefy, so that forms a gaseous phase of the first medium, wherein the jacket space is formed for collecting the gaseous phase.

Preferably, it is further provided that the at least one plate heat exchanger is formed so that the first medium rises during operation of the heat exchanger in the at least one plate heat exchanger, namely in designated first heat transfer passages of the at least one plate heat exchanger, in particular the at least one plate heat exchanger is designed to the second medium in the second heat transfer passages in countercurrent or cross-flow to the first medium to lead. The liquid phase of the first medium emerging at the upper end of the plate heat exchanger together with the gaseous phase flows down again on the sides of the plate heat exchanger, possibly in the vertically oriented channels.

According to a preferred embodiment of the invention it is provided that the channels or their walls are fixed to each other so that they form a coherent unit, which is also referred to as a register. These Unit is preferably formed separately from the heat exchanger block and / or jacket.

Furthermore, it is provided according to a preferred embodiment of the invention that the channels or at least some of the channels along their respective longitudinal axis (or cylinder axis) are formed longitudinally, ie, the extent along the respective longitudinal axis is greater than the largest inner diameter of the respective channel perpendicular to the respective longitudinal axis.

The channels are thus flowed through along their respective longitudinal or cylindrical axis of the liquid phase of the first medium, wherein they each have an opening at the two end faces, via which the liquid phase in the respective channel can enter or exit. The two openings of a channel lie opposite each other along the longitudinal or cylindrical axis of the respective channel, that is, they are aligned with one another.

According to a preferred embodiment of the invention, it is provided that all channels - with respect to the longitudinal axes - have the same length. Alternatively, it is provided according to a preferred embodiment of the invention that some or all channels for adapting the unit to a curved portion of an inner side of the shell of the heat exchanger - with respect to the longitudinal axes - have different lengths. This makes it possible to achieve a gradation of an outer side of the assembled unit following the course of the inner side region (e.g., a hollow cylindrical shell).

In principle, it is possible to fix the unit arranged in the jacket space on the jacket so that it does not contact the at least one heat exchanger block in particular. Alternatively, the unit may also be fixed to the at least one heat exchanger block or to a separate carrier.

It is particularly preferred according to an embodiment of the invention that the respective channel is formed by a hollow profile. The hollow profile, which is preferably made of a metal (such as aluminum or steel), thereby forms a wall surrounding the respective channel and limits or thereby forms the respective channel. Preferably, the hollow profiles are connected to each other so that that coherent unit is formed. The hollow sections can be welded together or be suitably fixed to each other by other fastening means, so that that unit or the hollow profile register is formed.

According to another embodiment of the invention, the channels are formed by a plurality of interconnected plate-shaped elements (e.g., sheets). These elements may be flat (e.g., planar sheets) or may have a structure (e.g., those elements may be formed as cross-section corrugated or folded or serrated elements / sheets). The individual elements may e.g. be fixed by nesting each other and may optionally be additionally fixed to each other. For fixing or fixing, e.g. Soldering and / or welded joints, rivet joints or other non-positive, positive and / or cohesive connections conceivable.

According to a preferred embodiment of the invention, it is provided that the longitudinal axes of the channels extend again parallel to the vertical, again in relation to a heat exchanger arranged as intended. In this case, the longitudinal axes of the channels can extend in a lying jacket perpendicular to the longitudinal or cylindrical axis of the shell. In a standing jacket, the longitudinal axes of the vertical channels preferably run parallel to the longitudinal or cylindrical axis of the jacket.

According to an alternative preferred embodiment of the invention, it is provided that the longitudinal axes of the channels - again in relation to a heat exchanger arranged as intended - run parallel to the horizontal. In this case, the longitudinal axes of the channels can extend parallel to the longitudinal or cylindrical axis of the jacket in a lying jacket. In a standing jacket, the longitudinal axes of the horizontal channels preferably extend perpendicular to the longitudinal or cylindrical axis of the jacket.

Furthermore, it is provided according to a preferred embodiment of the invention that at horizontally extending channels, at least some of the channels have a flow brake or are closed in order to make targeted the action on the liquid phase.

According to a preferred embodiment of the invention, it is further provided that the unit or possibly the channels along the vertical has or have a length which is at least greater than half the height of the at least one plate heat exchanger or heat exchanger block along the vertical greater than or equal to the height of the at least one plate heat exchanger or heat exchanger block along the vertical.

Furthermore, it can be provided with horizontal channels that they are shorter along their longitudinal axis than the length of the optionally laterally arranged heat exchanger block along the same direction.

Preferably, the unit composed of a plurality of channels or hollow profiles is arranged between the at least one heat exchanger block and the jacket or a section or inner side region of the jacket lying horizontally opposite the block.

If a plurality of separate heat exchanger blocks arranged in the shell space, the unit may also be arranged between two such blocks.

Finally, a plurality of units each having a plurality of channels can be provided both in a heat exchanger block and in a plurality of heat exchanger blocks, wherein the respective unit is then preferably arranged between one of the heat exchanger blocks and the jacket (see above) or between two adjacent heat exchanger blocks.

The respective unit can be designed as described above. The further heat exchanger blocks are in turn preferably designed as a plate heat exchanger, in particular in the form described above.

Further details and advantages of the invention will be explained by the following description of exemplary embodiments with reference to the figures. Advantageous embodiments of the invention are also specified in the subclaims.

Fig. 1

eine schematische, teilweise geschnittene Ansicht eines erfindungsgemäßen Wärmeübertragers mit stehendem Mantel und vertikalen Kanälen,

Fig. 2

eine ausschnitthafte Draufsicht auf die in der Fig. 1 gezeigten vertikalen Kanäle;

Fig. 3

eine schematische, teilweise geschnittene Ansicht eines weiteren erfindungsgemäßen Wärmeübertragers mit liegendem Mantel und vertikalen Kanälen;

Fig. 4

eine schematische, teilweise geschnittene Ansicht eines erfindungsgemäßen Wärmeübertragers mit stehendem Mantel und horizontalen Kanälen,

Fig. 5

eine ausschnitthafte Draufsicht auf die in der Fig. 4 gezeigten horizontalen Kanäle;

Fig. 6

eine schematische, teilweise geschnittene Ansicht eines weiteren erfindungsgemäßen Wärmeübertragers mit liegendem Mantel und horizontalen Kanälen; und

Fig. 7

eine schematische Schnittansicht zweier Wärmeübertragungspassagen eines Plattenwärmeübertragers wie er bei den Figuren 1, 3, 4 und 6 zum Einsatz kommen kann.

Show it:

Fig. 1

a schematic, partially sectioned view of a heat exchanger according to the invention with a standing jacket and vertical channels,

Fig. 2

a fragmentary plan view of the in the Fig. 1 shown vertical channels;

Fig. 3

a schematic, partially sectioned view of another heat exchanger according to the invention with a lying jacket and vertical channels;

Fig. 4

a schematic, partially sectioned view of a heat exchanger according to the invention with a standing jacket and horizontal channels,

Fig. 5

a fragmentary plan view of the in the Fig. 4 shown horizontal channels;

Fig. 6

a schematic, partially sectioned view of another heat exchanger according to the invention with horizontal jacket and horizontal channels; and

Fig. 7

a schematic sectional view of two heat transfer passages of a plate heat exchanger as in the FIGS. 1 . 3 . 4 and 6 can be used.

FIG. 1 shows in connection with FIG. 2 a heat exchanger 1, which has a standing, preferably (circular) cylindrical jacket 2, which delimits a jacket space 3 of the heat exchanger 1. The jacket 2 in this case has a circumferential, cylindrical wall 14, which is delimited by two opposing walls 15 frontally. The longitudinal or cylindrical axis of the shell 2 coincides with the vertical z.

In the jacket space 3 enclosed by the jacket 2, in the present case two heat exchanger blocks 4, 5 are arranged horizontally next to one another, which are plate heat exchangers 4, 5 which have a plurality of parallel heat transfer passages P, P '(cf. FIG. 7 ).

The respective plate heat exchanger 4, 5 in this case has a plurality of Wärmeleitstrukturen 41, which may be sheets that are formed in a meandering cross section, so for example wavy, jagged or rectangular course. These structures 41 are also referred to as fins 41 and are each arranged between two flat separating plates or plates 40 of the plate heat exchanger 4, 5. In this way, between each two partition plates 40 (or a partition plate and a cover plate, see below) a plurality of parallel channels or a heat transfer passage P, P 'is formed, through which the respective medium M1, M2 can flow. The two outermost layers 40 are formed by cover plates of the plate heat exchanger 4, 5; towards the sides 40 end strips 42 are provided between each two adjacent partition plates or separation and cover plates. The FIG. 7 1 shows, by way of example, a first heat transfer passage P for the first medium M1, which is formed by a fin 41 and two adjacent separating plates 40 and an adjacent second heat transfer passage P 'for the second medium M2, which is likewise formed by a fin 41 and two adjacent separating plates 40 becomes. Such an arrangement of passages is preferably repeated in the respective plate heat exchanger 4, 5, so that a plurality of first and second heat transfer passages P, P 'are arranged alternately side by side.

The jacket space 3 is filled with a first medium M1 during operation of the heat exchanger 1. This inlet flow into the heat exchanger 1 is usually two-phase, but may also be liquid. The liquid phase F1 of the first medium M1 then forms a bath surrounding the plate heat exchangers 4, 5, the gaseous phase G1 of the first medium M1 accumulating above the liquid phase F1 in an upper region of the jacket space 3 and being removable therefrom.

The liquid phase F1 of the first medium M1 rises in the first heat transfer passages P of the plate heat exchangers 4, 5 and thereby becomes through the second medium M2 to be cooled, which is guided eg in crossflow to the first medium M1 in the second heat transfer passages P 'of the plate heat exchangers 4, 5, partially evaporated by indirect heat transfer. The resulting gaseous phase G1 of the first medium M1 can escape at an upper end of the plate heat exchangers 4, 5 and is withdrawn from the jacket space 3 above the blocks 4, 5. Furthermore, a part of the liquid phase F1 circulates in the shell space 3, wherein that part in the plate heat exchangers 4, 5 in the first heat transfer passages P is conveyed from bottom to top and then flows outside the plate heat exchanger 4,5 in the shell space 3 back down.

The second medium M2 is passed into the plate heat exchanger 4, 5 and after passing through the associated second heat transfer passages P 'cooled or liquefied withdrawn from the plate heat exchanger 4, 5.

In order to calm the liquid phase F1 in the mantle space 3 in the event of a fluctuating movement of the shell 2, in which the longitudinal or cylinder axis fluctuates about the vertical z, are in accordance with FIG. 1 three units 100 are provided, each with a plurality of parallel channels 10, each extending along a longitudinal axis L which is parallel to the longitudinal axis z of the shell 2. These channels 10 are preferred according to FIG. 2 formed by a plurality of suitably interconnected hollow sections 11, for example, limit the circular cylindrical channels 10 and thereby each have an opening 10a, 10b on both sides, wherein the opening 10a is turned upwards and - along the vertical z - approximately is at the level of an upper end of the respective plate heat exchanger 4, 5 and the other, opposite opening 10b respectively facing down and - along the vertical z - below the blocks 4, 5 ends. The channels 10 are preferably arranged next to each other along second orthogonal spatial directions.

Through the vertical channels 10 can now from the respective plate heat exchanger 4, 5 at the upper end of the first passages P emerging liquid phase F1 circulate down again, where the liquid phase F1 then at the lower end of the plate heat exchanger 4, 5 in the first heat transfer passages P occurs and is pulled back upwards due to the thermosiphon effect, thereby partly evaporating and cooling the second medium M2.

The vertical channels 10 represent a flow resistance in the horizontal direction and therefore suppress corresponding horizontal movements of the liquid phase F1 of the first medium M1, while those vertical circulation is protected by the channels 10.

According to FIG. 1 one of the units 100 is arranged between the two plate heat exchangers 4, 5 laterally to the two blocks 4, 5. The other two units 100 are each arranged between a plate heat exchanger 4, 5 and a horizontally adjacent section or inner side region 2 a of the peripheral wall 14 of the shell 2.

FIG. 3 shows a modification of the heat exchanger 1 according to FIG. 1 that in difference to FIG. 1 a lying, longitudinally extending jacket 2, which extends along a longitudinal or cylindrical axis which coincides with the horizontal, that is perpendicular to the vertical z. Here, two plate heat exchangers 4, 5 in contrast to FIG. 1 along the longitudinal axis of the shell 2, the two blocks 4, 5 being laterally flanked on both sides by a unit 100 formed as described above, the units 100 covering the two blocks 4, 5 over the whole, Flank combined length of the two blocks 4, 5 along the longitudinal axis of the shell 2.

FIG. 4 shows a further modification of the heat exchanger 1 according to FIG. 1 , in which now the channels 10 in contrast to FIG. 1 run horizontally, ie perpendicular to the longitudinal axis of the stationary shell 2, which coincides with the vertical z. The openings 10a, 10b of the channels 10 now each have a horizontal direction. The units 100 are according to FIG. 1 with respect to the plate heat exchangers 4, 5, wherein the unit 100 between the two blocks 4, 5 channels 10 having a larger flow cross-sectional area than the units 100 on the outsides of the blocks 4, 5. All units 100 are along the vertical z on the upper and lower ends of the plate heat exchangers 4, 5, so as to calm as possible the entire level of the liquid phase F1 of the first medium M1 in a fluctuating movement of the heat exchanger 1, wherein the longitudinal axis z of the shell 2 according to FIG. 4 their inclination changed, in particular from the leaf level out. The reassurance is generated by the flow resistance, the liquid phase F1 in the horizontal channels, for example when flowing back and forth between the openings 10a, 10b of the channels 10 experiences. The channels 10 or units 100 according to FIG. 4 can be formed with a plurality of rectangular cross-section or square hollow profiles or by nested or attached to each other flat, plate-shaped elements, in particular sheets (see above). According to FIG. 5 For example, the vertical channels 10 may not only be rectangular in cross-section, as exemplified in FIG Fig. 4 shown, but also circular. Other shapes are also conceivable. To increase the flow resistance in the horizontal direction, individual horizontal channels 10 may be equipped with an additional flow brake (eg a cross-sectional constriction) 12 or be completely closed 12.

FIG. 6 finally shows a heat exchanger 1 by type FIG. 4 with horizontal channels 10, wherein now the jacket 2 of the heat transfer according to FIG. 3 is formed and arranged horizontally. In this case, on both sides of the plate heat exchangers 4, 5, which are arranged one behind the other, according to FIG FIG. 3 are placed, respectively provided between the respective block 4, 5 and a horizontally adjacent inner side region or portion of the circumferential wall 14 of the shell 2, a unit 100 with a plurality of stacked and juxtaposed horizontal channels 10, but along the longitudinal axis of the jacket 2 a smaller Have expansion as the blocks 3, 4 along this direction. This allows the least possible disturbance of the vertical circulation of the liquid phase F1 (see above). Furthermore, along the longitudinal axis of the shell 2 according to FIG. 6 another unit 100 between the two blocks 4, 5 is arranged. Again, the reassurance of the liquid phase F1 of the first medium works as based on the FIG. 4 described.

Basically, the interconnected (or individual) hollow sections 11 and channels 10 in different cross-sectional shapes (eg circular, rectangular, honeycomb) and length at any position of not occupied by the respective plate heat exchanger 4, 5 shell space 3, but mainly in the liquid-filled area (So next to the block 4 or 5, the blocks 4, 5 and / or between the blocks 4, 5) be attached. The number of units or Register 100 is customizable. These units 100 are flowed through only in the vertical direction or in the horizontal direction of the liquid phase F1. The composite itself represents a flow resistance in the horizontal direction. This dampens horizontal flows. The units 100 or channels 10 can be adapted to the respective requirements both in vertical and in the horizontal dimensions and can also be subdivided if necessary. The size of the individual channels 10 in cross section is flexible and can also be adapted to the respective requirements. The individual channels 10 of the units 100 may have different lengths. Especially with horizontal channels 10 or hollow sections 11, individual profiles 11 may be closed in order to adapt the flow resistance. This dampens horizontal currents.

In summary, the units or hollow profile register 100 according to the invention allow a great influence on the flow direction of the circulating liquid F1 in the container 2, without requiring a high number of individual parts. The volume of liquid outside the plate heat exchangers 4, 5 can be very highly segmented, although the manufacturing and assembly costs for it remains relatively low. The segmentation further allows low wall thicknesses of the units 100 or channels 10 / hollow sections 11, since the composite 100 represents a robust body 100 and only allows small-scale fluid movements. By adjusting the dimensions of the individual elements 10 and of the composite 100 as a whole, the natural frequencies of oscillating liquid F1 in the container 2 or jacket space 3 can be influenced and movements dampened. Thus, a stimulation in natural frequency and high vibration amplitudes can be prevented.

Particularly preferably, the heat exchanger 1 according to the invention is used on a float on a body of water, for example as a component of a floating plant for the production of liquid natural gas (LNG). <B> LIST OF REFERENCES </ b> 1 Heat exchanger 2 coat 2a inside 3 shell space 4, 5 Plate heat exchangers 10 channel 10a, 10b opening 11 hollow profile 14 wall 15 wall 40 partition plates 41 Wärmeleitstrukturen or Fins 42 Side bars 100 unit M1 First medium M2 Second medium G1 Gaseous phase first medium F1 Liquid phase first medium P First heat transfer passage P ' Second heat transfer passage Z vertical

Claims (14)

Heat exchanger for indirect heat transfer between a first medium (M1) and a second medium (M2), comprising: - A jacket (2) having a jacket space (3) for receiving a liquid phase (F1) of the first medium (M1), and - At least one heat exchanger block (4), the first heat transfer passages (P) for receiving the first medium (M1) and second heat transfer passages (P ') for receiving the second medium (M2), so that between the two media (M1, M2) indirect heat is transferable, wherein the at least one heat exchanger block (4) is arranged in the jacket space (3) such that it can be surrounded by a liquid phase (F1) of the first medium (M1) located in the jacket space (3), characterized,
that the jacket space (3) laterally to the at least one heat exchanger block (4, 5) comprises a plurality of mutually parallel cylindrical channels (10) for guiding the liquid phase of the first medium (M1) is provided. Heat exchanger according to claim 1, characterized in that the channels (10) are fixed to each other so that they form a coherent unit (100), in particular separately from the at least one heat exchanger block (4) and / or the jacket (2) is formed , Heat exchanger according to claim 1 or 2, characterized in that the extent of the channels (10) along the longitudinal axis (L) of the respective channel (10) is greater than the largest inner diameter of the respective channel (10) perpendicular to the respective longitudinal axis. Heat exchanger according to one of the preceding claims, characterized in that the channels (10) - with respect to the longitudinal axes (L) - have the same length, or that at least some channels (10), in particular for adapting the unit (100) to a curved Area of an inside (2a) of the jacket (2) - with respect to the longitudinal axes (L) - have different lengths. Heat exchanger according to one of the preceding claims, characterized in that the respective channel (10) is formed by a hollow profile (11), wherein in particular the hollow profiles (11) are interconnected so that that coherent unit (100) is formed. Heat exchanger according to one of the preceding claims, characterized in that the channels (10) are formed by a plurality of interconnected plate-shaped elements which are interconnected. Heat exchanger according to one of the preceding claims, characterized in that the longitudinal axes (L) of the channels (10) extend parallel to the vertical (z). Heat exchanger according to one of claims 1 to 6, characterized in that the longitudinal axes (L) of the channels (10) extend parallel to the horizontal. Heat exchanger according to claim 8, characterized in that at least some of the channels (10) have a flow brake (12) or are closed (12). Heat exchanger according to claim 2 or one of claims 3 to 9 as far back referred to claim 2, characterized in that the unit (100) along the vertical (z) has a length which is at least greater than half the height of the at least one heat exchanger block (4 ) along the vertical (z) is, preferably greater than or equal to the height of the at least one heat exchanger block (4) along the vertical (z). Heat exchanger according to claim 2 or one of claims 3 to 10 as far back referred to claim 2, characterized in that the unit (100) between the at least one heat exchanger block (4) and an adjacent portion (2a) of the jacket (2) is arranged. Heat exchanger according to one of the preceding claims, characterized in that the heat exchanger (1) has a further, in the jacket space (3) arranged heat exchanger block (5) which is arranged along the horizontal next to the one heat exchanger block (4). Heat exchanger according to claim 2 and 12, characterized in that the unit (100) between the two heat exchanger blocks (4, 5) is arranged. Heat exchanger according to one of the preceding claims, characterized in that the heat exchanger (1) comprises a plurality of units (100), each having a plurality of parallel cylindrical channels (10) for guiding the liquid phase (F1) of the first medium ( M1), wherein in particular the respective unit (100) between one of the heat exchanger blocks (4, 5) and an adjacent portion (2a) of the jacket (2) or between two heat exchanger blocks (4, 5) is arranged.

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