FR2718835A1 - Plate heat exchanger for e.g gas liquefaction - Google Patents

Abstract

The heat exchanger (1) comprises a stack of parallel plates (2), with corrugations (18) between, bounded by beams (16). Each plate pair defines a fluid passage (14), closed longitudinally (3) and transversely by bars, extending full length around the periphery of each passage, with free ways for fluid entry and outlet.A passage (14) may be subdivided over its thickness (e) by at least two sub-passages, each containing corrugations, between beams, (22,23), separated by an intermediate plate (19). Sub-passages may extend the full width of the passage contained by the exchanger, over part of its length (L). The intermediate plate may be parallel to the two plates, defining the fluid passage.

Description

 The present invention relates to a brazed plate heat exchanger of the type comprising a stack of parallel plates and, between these plates, of spacer waves, each pair of plates defining a generally flat fluid passage, and bars of longitudinal and transverse closure extending along the periphery of each passage, leaving free entry / exit windows for fluids.

In conventional exchangers of this type, each passage has the same thickness over its entire extent. This is not the optimum in many cases, for example in the following situations:
(1) During the heating or cooling of a fluid over a wide range of temperatures, the specific volume of the fluid varies considerably, while the passage section offered to it remains constant. In particular, when the cold end of the heat exchanger is supplied with a liquid to be vaporized, the speed of circulation of the liquid at the cold end is too slow, which leads to hydrodynamic instabilities of the flow.

 (2) When, at an intermediate temperature, an auxiliary fluid must be added to a passage, or a fraction of the flow of a fluid must be withdrawn from this passage, or else when an auxiliary fluid must be connected indirect heat exchange with the main fluids over only part of the temperature range, it is necessary to mobilize additional passages, which is unfavorable to the thermal performance of the exchanger.

 The invention aims to avoid these drawbacks, by providing an additional degree of freedom in the design of brazed plate heat exchangers.

 To this end, the subject of the invention is a heat exchanger of the aforementioned type, characterized in that at least one passage is, over only a fraction of its extent, subdivided in its thickness into at least two sub-passages each containing a wave-spacer and separated by an intermediate plate.

The heat exchanger according to the invention may include one or more of the following characteristics
- the sub-passages extend over the entire width of the passage which contains them and only a fraction of its length;
- The auxiliary plate is parallel to the two plates which delimit the passage which contains it;
- At least a first sub-passage leads on the one hand to at least one fluid inlet / outlet window and on the other hand into the passage which contains it;
- at least a second sub-passage leads only into the passage which contains it;
- At least a second sub-passage also opens onto at least one fluid inlet / outlet window and on the other hand into the passage which contains it;
- The spacer wave of each sub-passage which leads to at least one fluid inlet / outlet window forms, over at least part of the length of this sub-passage, a distribution wave or a collecting wave;
- At least a first sub-passage opens only on a fluid inlet window and on a fluid outlet window, while at least a second sub-passage opens only in the passage which contains it; and
- A first sub-passage opens at one of its longitudinal ends in a greater number of sub-passages or in an undivided part of the passage which contains it.

Embodiments of the invention will now be described with reference to the accompanying drawings, in which
- Figure 1 shows in perspective the general constitution of a heat exchanger with brazed plates;
- Figures 2 to 5 respectively illustrate, schematically, four different applications of the invention;
- Figure 6 shows in exploded perspective part of a passage of a heat exchanger according to the invention, corresponding to the application of
Figure 2; and
- Figures 7 to 9 are views similar to Figure 6 but corresponding respectively to the applications of Figures 3 to 5.

 As is well known, and as shown in Figure 1, a heat exchanger 1 with brazed plates consists of a stack of parallel plates 2, generally rectangular and all identical, which define two by two a multitude of flat passages.

The dimensions of the plates can be important; for example, for a heat exchanger of an air distillation installation, they can be up to 6.7 m in length L for 1.2 in width 1. On the other hand, the thickness of the passages is very small , typically of the order of S to 10 mm. The number of passages can be of the order of 100 to 150.

 The mutual spacing of the plates 2 is ensured by spacer waves which also fulfill the function of thermal fins. These waves can be made of corrugated sheet perforated or punctured on their sides (so-called "serrated" waves), and have a square, rectangular, sinusoidal, etc. wave section.

 The passages are closed hermetically over their entire periphery by longitudinal bars 3 and transverse bars 4, all of the same thickness equal to the height of the waves, with the exception of limited regions opening outwards. These regions form a series of vertically aligned windows for fluid inlet / outlet, and each series of windows is hermetically sealed by a fluid inlet / outlet box, typically semi-cylindrical, fitted with a pipe. 6 for introducing or withdrawing fluid. The windows associated with a given box 5 obviously only interest a certain number of passages, reserved for the corresponding fluid.

 As illustrated in FIG. 1, for the fluids circulating from one end to the other, in the longitudinal direction, of the exchanger, the boxes 5 are adjacent to the two ends of it, and boxes can be provided 5 additional along the exchanger, for the input / output of an auxiliary fluid or for the at least partial withdrawal of a fluid during cooling or heating.

 The plates, the waves and the closing bars are typically made of aluminum or aluminum alloy and are assembled in a leaktight manner in a single operation, by brazing in the oven. The boxes 5 are then added by welding. In the classical technique, each passage has the same thickness over its entire extent.

 We will now describe how this structure is modified, according to the invention, by considering by way of example a certain number of applications shown diagrammatically in FIGS. 2 to 5, where the exchanger is assumed to be of the counter-current type, with its hot end and its cold end arranged respectively at the top and bottom.

 In each application, a downward line 7 represents a fluid to be treated which is cooled and possibly liquefied from the hot end to the cold end of the exchanger, and a main rising line 8 represents a main refrigerant which heats up, possibly after vaporization , from the cold end to the hot end of the exchanger.

 In the case of FIG. 2, in addition to the main refrigerant, at an intermediate point 9 of the length of the exchanger, an auxiliary refrigerant supplied by a pipe 10; Alternatively, one could similarly withdraw a fraction of the flow of a circulating fluid.

 In the case of FIG. 3, an auxiliary fluid, circulating in the example illustrated, is put into indirect heat exchange relationship with the two main fluids, that is to say at an intermediate point 11 of the length of the exchanger, as indicated in solid lines (use of the auxiliary fluid in cross flow), or between two intermediate points 11 and 12, as indicated in broken lines.

 In the case of Figure 4, an increasing passage section is offered to the refrigerant during its heating, to compensate at least approximately for its specific volume increase.

 In the case of Figure 5, an auxiliary refrigerant feeds the cold end of the exchanger and is mixed with the main refrigerant.

The two refrigerants can in particular be the two liquid and vapor phases of the same two-phase fluid, previously separated in a phase separator 13.

 The structure of the heat exchangers according to the invention will now be described in more detail.

In the case of Figure 2, the passages 14 reserved for the main refrigerant (line 8 of the
Figure 2) are modified as shown in Figure 6.

 Above and below an area 15 of limited longitudinal dimension L1 less than L, the passages 14 are, like the other exchanger passages over their entire length, delimited by two plates 2 (only one of which is visible in Figure 6), by two longitudinal bars 3 of thickness e, and by two transverse bars 4 (not visible in Figure 6) also of thickness e. In addition, the passages 14 contain, above and below the zone 15, over their entire extent, like the other passages of the exchanger, a spacer wave 16 of height e, and of which, consequently, the vertices d waves are in contact with the plates 2.

 In zone 15, the bars 3 are deleted and replaced by bars 17 of thickness el less than e, and the wave 16 is replaced by a wave 18 of thickness el. An intermediate rectangular plate 19 of longitudinal dimension L1 and of transverse dimension 1 is disposed on the wave 18 and on the bars 17. A longitudinal closing bar 20 of length L1, disposed on a longitudinal edge of the plate 19, is flush with the bar 3 adjacent. A transverse strip 21, flush with the strip 20, extends transversely from the latter to the other longitudinal edge of the exchanger. Thus, the plate 19 is surmounted by an L-shaped half-frame, along one of its longitudinal edges and along one of its transverse edges.

 The rest of the extent of the plate 19 is surmounted by a distribution wave, consisting of an oblique wave 22 extending from the bar 20 and ending in an oblique edge, and a transverse wave 23 s extending from this edge 23 and up to cover the bar 17 opposite the bar 20. The waves 22 and 23 have the same height and are flush with the bars 20 and 21.

 It can be seen that, in zone 15, passage 14 is subdivided into two sub-passages. One of these underpasses constitutes a simple extension of the passage 14, with reduced section, while the other sub-passage forms a space in which an auxiliary fluid can be introduced laterally and then be distributed in the passage 14 thanks to the wave distribution 22-23.

 As will be understood, the same arrangement can be used to withdraw a fraction of the flow rate of a fluid circulating in the passage 14 (from top to bottom when considering Figure 6).

 For the application of Figure 3, as shown in Figure 7, the passages 14 concerned are modified in a similar fashion, but this time we find, in zone 15, on either side of the intermediate plate 19, d on the one hand a sub-passage comprising the elements 17 and 18, and on the other hand a sub-passage comprising two transverse bars 24 which extend from one longitudinal edge to the other of the exchanger and, between them ci, a transverse wave 25. It is thus possible to circulate an auxiliary fluid in cross flow with respect to the main fluids.

 Alternatively, to circulate the auxiliary fluid over a whole range of intermediate temperatures, wave 25 could be replaced by the association of a transverse / oblique input distribution wave similar to wave 22-23 of the Figure 6, a longitudinal heat exchange wave and an oblique / transverse outlet collecting wave, with bars and corresponding input / output windows.

 Figure 8 shows how passages 14 can be modified over part of their length to provide a fluid during heating with a progressively increasing passage section, in particular to ensure the hydrodynamic stability of the flow.

Passage 14 has three different areas, i.e., from the hot end
an outlet zone 26, delimited by two longitudinal bars 3 and a transverse bar 4 of thickness e and containing waves of thickness e, namely a longitudinal wave 16 of heat exchange and oblique waves 27 and longitudinal 28 for collecting the heated fluid and guiding it to an outlet window 29;
an intermediate zone 30, of thickness e2 less than e, delimited by a plate 2 (not visible in FIG. 8), two longitudinal bars 31 of thickness e2 and a first intermediate rectangular plate 32, and containing a longitudinal wave 33 of thickness e2; and
- An entry area 34, of thickness e3 less than e2 delimited by the same plate 2, two longitudinal bars 35 of thickness e3 and a second intermediate rectangular plate 36, and containing on the one hand a longitudinal wave 37 of thickness e3 and on the other hand, at its cold end, an oblique / longitudinal distribution wave 38, also of thickness e3 adapted to distribute the heated fluid, from a median inlet window 39 left free by a bar transverse end 39A, over the entire width of the wave 37.

 Each of the intermediate plates 32 and 36 extends over the entire width of the exchanger and up to the cold end thereof.

 In the example shown, the space defined between the plates 32 and 36 is hermetically sealed by four bars 40 between which is disposed a wave-spacer 41 of the same thickness. Similarly, the space surmounting the plate 32 is hermetically sealed by four bars 42 between which a spacer wave 43 of the same thickness is disposed, the elements 42 and 43 flush with the elements 3, 4, 16, 27 and 28 of the zone outlet 26. The heat exchanger therefore contains spaces which are thermally inactive, but which provide thermal insulation between the adjacent passages. As a variant, these spaces can be used to circulate fluids and / or to create vacuum spaces which can be used to check the tightness of the adjacent passages.

 As can be understood, the embodiment of Figure 8 is also suitable for cooling a fluid, the passage section then gradually decreasing as the contraction of this fluid.

 Figure 9 shows how the invention makes it possible to introduce into passages 14, at the cold end of the exchanger 1, two different fluids, in particular the liquid and vapor phases of the same two-phase fluid previously separated.

In the coldest part 44 of the passages 14, the bars 3 and the wave 16 are replaced by the superposition
- Two longitudinal bars 45 and a transverse end bar 46, framing a longitudinal wave 47 extended to the cold end by a longitudinal / oblique entry distribution wave 48, which opens onto a median entry window 49 left free by the bar 46. The elements 45 to 48 have a thickness e4 less than e.

- An intermediate plate 50 covering the elements 45 to 48; and
- Two longitudinal bars 51, one of which leaves a lateral entry window 52, and a transverse end bar 53, these bars framing a longitudinal wave 54 extended to the cold end by a distribution wave transverse / oblique entry 55, the latter opening onto the window 52. The elements 51, 53, 54 and 55 are flush with the elements 3 and 16.

Claims (9)

 1 - Heat exchanger (1) with brazed plates, of the type comprising a stack of parallel plates (2) and, between these plates, of spacer waves (16), each pair of plates defining a fluid passage (14) generally flat, and longitudinal (3) and transverse (4) closing bars extending along the periphery of each passage, leaving free entry / exit windows for fluids, characterized in that at least one passage (14) is, over only a fraction of its extent, subdivided in its thickness (e) into at least two sub-passages each containing a wave-spacer (18, 22-24; 18, 25; 33, 37, 38 ; 47 to 49, 54, 55) and separated by an intermediate plate (19; 32, 36; 50).  2 - Heat exchanger according to claim 1, characterized in that the sub-passages extend over the entire width (1) of the passage (14) which contains them and over only a fraction of its length (L).  3 - Heat exchanger according to claim 1 or 2, characterized in that the auxiliary plate (19; 32, 36; 50) is parallel to the two plates (2) which delimit the passage (14) which contains it.  4 - Heat exchanger according to any one of claims 1 to 3, characterized in that at least a first underpass opens on the one hand on at least one window (38, 52) of fluid inlet / outlet and on the other hand in the passage (14) which contains it (Figures 6 and 9).  5 - Heat exchanger according to claim 4, characterized in that at least a second underpass opens only in the passage (14) which contains it (Figure 6).  6 - Heat exchanger as claimed in claim 4, characterized in that at least a second underpass also opens onto at least one window (48, 52) for inlet / outlet of fluid and secondly in the passage ) which contains it (Figure 9).  7 - Heat exchanger according to any one of claims 4 to 6, characterized in that the spacer wave (18, 22-24) of each sub-passage which opens onto at least one window (48, 52) d 'inlet / outlet of fluid forms, over at least part of the length of this sub-passage, a distribution wave or a collecting wave.  8 - Heat exchanger according to any one of claims 1 to 3, characterized in that at least a first sub-passage opens only on a fluid inlet window and on a fluid outlet window, while at least one second underpass opens only into the passage (14) which contains it (Figure 7).  9 - Heat exchanger according to any one of claims 1 to 3, characterized in that at least a first sub-passage opens at one of its longitudinal ends in a greater number of sub-passages or in a non-part subdivided from the passage (14) which contains it (Figure 8).