DE1300136B - Block heat exchanger - Google Patents

Description

1 2

The invention relates to a heat exchanger, housing wall of the heat exchanger deflected consisting of one or more one-piece and the flow divided into several sections.

Blocks, each of which has a cylindrical Das in its respective section on the associated

Coat is surrounded and a first group of threshold collecting condensate drips from there tubular channels for a first medium and a 5 free from or is from there against the housing

second group of slit-shaped channels for a wall flung and flows on their inner

second with the first standing in heat exchange area to the exit. It no longer gets into the

Has medium, wherein the slot-shaped channels following section of the slot channels. The condensate

start from the circumference of each block and apply the same sizing medium (e.g. heating steam) to this

Direction as the channels of the first group run. io way repeated each time at the thresholds of the

Such a heat exchanger is freed from the condensate from p. 137 and the heat transfer

Chemical Engineering magazine, July 9, 1962, passage between the flowing medium and the

knows. Slot duct wall improved. Otherwise wetted

In addition, heat exchangers are known from a namely the condensate in the form of a film the number of slots and recesses provided with grooves and recesses, the film in the thickness of graphite plates that are joined together to form a block and accordingly also with heat transfer resistance (German utility model 1867 931). increases downwards. If this phenomenon can be eliminated or at least reduced as a binding agent, an acid-resistant putty can be used. Here, an ao channel groups extending in the axial direction and widening alternately from plate to plate due to the heat transfer value between the two is significantly increased. If you take for and tapering central recess for the gas the one-piece block a height of about 3 m is provided on the shaped medium, which is slotted and divided by the mentioned thresholds connect, while for the total height of the one-piece block in Waste medium channels circular cross-sectional sections of 0.4 m, so one obtains in operation one that is provided which run parallel to the slit-shaped heat transfer value between the two channel recesses. These recesses have groups that are 3 times higher than it is without the over the entire block on a kinked shape; subdivision would be the case. If there are drops or individual kinks, there is the possibility that mixed condensation occurs instead of film condensation, and any condensate that may be present drips off. Since this results in a further increase in the heat over kinks, however, in the interior of the duct block, up to z. B. to ten times the amount of the gene, the dripping condensate parts remain in value, which is established with a continuous fiImden slot channels and are not added to condensation from these,
reliably removed. If above from a one-piece block for the

Furthermore, a corrugated plate heat exchanger is also used for both channel groups, so that should not be the case

known in which by a bundle of corrugated plates 35 exclude the entire block in the longitudinal direction

to subdivide parallel channels in the longitudinal direction of the exchanger into several individual blocks or, with

be formed, at the ends of the exchange- in other words, into several shots. That recommends

Schers corrugated plate-shaped filler pieces with around- often for manufacturing reasons, especially when

directing the medium from the cross-flow direction in the overall block a relatively large length

has the longitudinal flow direction in the entry area or in the 40 (z. B. of several meters). This can also come from

Outlet area curved inner edges provided for reasons of easier overhaul and repair

are. The deflection elements serve to be attached. In this case, only one

for redirecting the media. They are not individual shots to be exchanged

suitable for removing steam from entrained condensate. The division into individual shots also has the

free. 45 Advantage of the above-mentioned thresholds in

With vertical tubular heat exchangers, which can form more easily from the slot channels,
a condensing medium are applied, For further explanation, it is known to the drawing, referred to by attached to the pipes guide, in which some embodiments surfaces, eg. B. Rings, at certain intervals that the new heat exchanger are shown; it shows forming condensate draining from the pipes and 50 F i g. 1 shows a cross section along the line SS of the heat generated by thinning the condensate film. 2 to increase considerably by a heat transfer according to the invention. exchanger,

The invention is based on the object, from Fig. 2, the associated longitudinal section according to the

going from the aforementioned known type line AB of Fig. 1,

of heat exchangers, when using these 55 Fig. 3 and 4 each a modification in the arrangement

Heat exchanger for a duct in the slot ducts,

Densifying medium, the heat transfer in the F i g. 5 in a longitudinal section the transition between

To improve slot channels. see two blocks with interposed sealing

According to the invention, this object is achieved by

solves that he is to operate for a in the slot channels 60 F i g. 6 is a plan view of the sealing plate

condensing medium is provided and that according to FIG. 5.

each slot channel of the heat exchanger in its accordance with FIGS. 1 and 2 contains the heat length through one or more of the bottom of the exchanger the cylindrical block 2 with circular slot channel up to the circumference of the block there is a cross-section; he is from a coat 1 that made lifting thresholds to form a drip or 65 a steel sheet can be formed, surrounded. Of the Separating edge for the condensate is divided. Block 2 has for the mutual heat exchange

As a result, the flowing medium becomes a group of media to be passed through

through the threshold outwards towards the tubular channels 3 round cross-section and a

3 4

Group of slot ducts 4. The ducts 3 of the first As a result, a group runs into the inlet opening 16, as can be seen in FIGS. 1 and 2 seen medium is borrowed into the individual tubular, in the same direction as the channels 4 of the channels. At the other end of the heat exchanger, the second group. Between the cylindrical one, the medium emerging from the tubular channels of the Bloktel 1 and the concentrically arranged block 2 5 kes7 leaves via the bell-shaped one, a cylindrical gap 5 which forms the entire end part of the heat exchanger,
of the slot-shaped channels 4 spatially with one another The unit, consisting of the individual blocks connects and forms a common access to the velvet-2, 6 and 7 and the two bell-shaped end parts borrowed slot channels. The slot channels 4 are 16 α and 17 α is held together by several tie rods 1 c to 1 i evenly distributed over the circumference in cross section in this embodiment, for example radially towards the center axis of the block 2 via the two end plates 1 a, 1 b.
aligned. The tubular channels 3 round the heat exchanger according to FIG. 1 and 2 can cross-section are arranged in between, as in the z. B. be used as an evaporator, which in the following the F i g. 1 and 2 show. The block can be written on. The liquid to be evaporated, also in one piece over its entire length, is introduced through the inlet opening 16 and rises. In the embodiment of FIG. 1 and 2 is high in the tubular channels 3, in which it is however heated in three individual ways over its length in such a way that it evaporates. The steam enters blocks 2, 6 and 7 divided, each of which is in one piece through the outlet opening 17 from here. The blocks 2, 6 and 7 each have channels 3 closed, not shown pipe or the like. For a round cross-section in the same number and distribution ao heating of the liquid is via the supply line and are joined together so that the channel stubs 14 are in the gap 5 and thus cover in the slot openings of butting shots. Intermediate channels 4, directed steam, in particular water vapor, see the abutting end faces 8 and 9 which, on its way through the slot channels from blocks 6 and 7, is suitably cooled by an edge seal 10 and partially condensed there. The steam and its thickness are placed in a groove in each of the two end faces. processing nozzle 15 discharged.

As a result of the illustrated design of the slot, there is necessarily an intermediate space 11 at the joint, via which the tubular channels 4 receive the steam flow for the most part, as the one channels 3 are connected to one another. This drawn course deflected several times. The gap would be in this embodiment 30 steam penetrates when entering the uppermost block 7, it suffices if the individual tubular in the slot channels 4 and is near their ends shaped channel of one block with that of the other through the formed there Sleepers against the zylin blocks would be directly connected. The intermediate shell 1 deflected. In the following block space is not harmful either, it even leads to the same flow course,
a desired intermixing of the condensate emerging from the tube in the first block from the vapor, which is formed in the first block from the condensate, which is formed as a liquid film on the Wan quantities of one medium. On the other hand, if the slot channels are fertilized, this congestion is not passed on to the next block, the space enclosed by it, with the use of the ring seal and densate, but becomes a very simple area with the steam flow to the interior and generally meets the requirements of the jacket 1 deflected. At the threshold and / or following individual blocks formed by the sufficient connection between the shape of the slot channels 4 on top of one another. or drips or drips on the inner surface of the jacket 1

The slot channels 4 are along the axis of the condensate flowing in downwards without entering the next

Zelblocks 2,6 and 7 each not completely drawn through to get block. So only steam penetrates into it

Instead, they begin in each block in 45 a, separated from the one in the first block

Proximity of one end face (for example the front condensate. The same applies to the following blocks,

surface 9 of the block 6) and only extend close. This is a major advantage over the

to the other end face (for example the end face previous block heat exchangers. If

area 12 of the same block), the depth of the condensate being formed over the whole of the remaining

the slot channels 4 continuously changes in the longitudinal direction, 50 length of the block runs, as it is regularly

in such a way that it is the case approximately up to the cross-sectional mean, as a liquid film on the walls

level increases and then decreases again. In this way the channels concerned, the heat must be removed from the

In the area of the joint in the individual slot duct, heating steam makes its way through this liquid film

a threshold is formed in each case. take the one down towards the end of the channels

On the jacket 1 is in the vicinity of its upper 55 is getting thicker. Such a phenomenon has not the end face a supply pipe 14 and in the vicinity agile as a consequence that the heat transfer of its lower end face a discharge pipe 15 constantly decreases for number. If, on the other hand, according to the finding flowing in the slit-shaped channels 4, the individual slotted channel is attached by a or dium. An inlet opening 16 and a plurality of thresholds are divided into several sections of the outlet opening 17 for the type described by the channels 3 round 60, so in each section there is a cross-section flowing medium on which the condensate formed there from the further upper or lower End face of the heat exchange vapor stream finally excreted, so that the shear in each a bell-shaped end portion 16 α or from the condensate resulting liquid film at 17 a, which via an edge seal 16 b, 17 b with the walls of the slot channels does not always correspond Blocks 2 and 7 is connected and 65 is reinforced, rather after each threshold only the lower and upper ends of the two - starting at zero - are newly formed. This leads to a very substantial increase in not-blocks 2 and 7 present tubular channels in a maneuverable manner. the average heat transfer coefficient and

with - given the dimensions - to a significant increase in the performance of the Heat exchanger compared to the performance of the previous design.

The F i g. FIG. 3 shows an arrangement of the channels leading from the FIG. 1 differs slightly. With this arrangement according to FIG. 3, the slot channels, which are designated here by 18 α , are broken down into sub-groups of three channels each and introduced into the block 18. In each subgroup, the central planes of the slot channels 18 α run parallel to one another. This has the advantage that the slot channels of a subgroup can each be introduced in one operation. Within the individual subgroups, the two outer channels are less deep than the central channel; similarly change in the execution according to FIG. 1 and 2 the slot channels alternately in depth. The design according to FIG. 3 can moreover with the according to F i g. 1 and 2 match. The tubular channels 18 b are attached between the slot channels 18 α in the distribution shown in FIG.

F i g. FIG. 4 shows a cross section similar to that of FIG. 1 and 3, but differs from them in the arrangement of the channels. The block 19 has an almost rectangular cross-section with slightly beveled edges, so that it represents an octagon. The slot channels 19 α are - introduced parallel to one another - from two opposite broad sides. This results in the same advantages as in the embodiment according to FIG. 3. The tubular channels 19b are shown in FIG. 4 arranged in rows between and outside of slot channels.

The flow directions of the media can be directed opposite one another or also be in the same direction.

In Fig. 5 is based on a heat exchanger according to FIG. 1 and 2. The block is back divided into several individual blocks. However, the thresholds in the slot channels are not through a corresponding shape of the channels formed in the individual block. The slot channels run rather, as a rule, with a constant depth through the entire block. But for the formation of the A sealing plate is inserted between two successive individual blocks, which is in the area of the tubular channels between the aligned sub-channels of the two blocks, respectively has an equally wide bore quickly connecting the sub-channels, but in the area of the slot channels the sub-channels of the successive blocks separates from each other, in the sense of the formation of Swellings between the slot sub-channels at the joint. The thresholds formed in this way serve this purpose same purpose as the thresholds in the explanations according to FIG. 1 and 2.

It is this in Figs. 5 and 6 shown schematically for the two consecutive individual blocks 40 and 48. The one-piece individual blocks 40 and 48 contain the tubular channels 41 and 44 and the slot channels 42 and 43 in the same number and size and distribution for both blocks. The slot channels have a constant depth in their longitudinal direction on. A sealing plate 46 is inserted between the adjoining end faces of the two blocks 40, 48, with passage openings 47 for the mutually aligned tubular channels 41, 44 of the two sections 40 and 48. The top view of the sealing plate 46 is shown in FIG. 6 shown. From her the distribution of the passage openings 47 can be seen.

At the boundary point of the slot channels of one block and the following block, these slot channels become separated by the sealing plate, it does not contain any openings here. It will be so on this one Point, a threshold is formed in the total length of the individual slotted channel, which deflects the in the slit channels causing the flowing medium and so as a drip edge for the in the previous block accumulated condensate is used.

When using the heat exchanger according to the invention at temperatures above 200 ° C is it is advisable to use graphite as the material for the blocks, made by known methods Storage of secondary carbon, even at higher temperatures, is gas- and liquid-tight.

Claims (6)

Patent claims: 1. Heat exchangers consisting of one or more one-piece blocks, one of which each is surrounded by a cylindrical jacket and each has a first group of tubular Channels for a first medium and a second group of slot-shaped channels for a second with the first medium in heat exchange, the slot-shaped Channels emanate from the perimeter of each block and in the same direction as the channels of the first Group run, characterized that it is intended for operation for a medium condensing in the slot channels and that each slot channel (4 in block 2, 6, 7 Fig. 2; 42-43 Fig. 5) of the heat exchanger in its length by one or more from the bottom of the slot channel to the perimeter of the block itself uplifting thresholds to form a dripping or repelling edge for the condensate is divided. 2. Heat exchanger according to claim 1, characterized in that the single threshold has the shape of a wedge, the cutting edge of which extends transversely to the longitudinal direction of the slot channel is directed outwards. 3. Heat exchanger according to claim 1 or 2, characterized in that the single threshold on the block (2, 6, 7 Fig. 2) by decreasing and increasing depth of the slot channel (4 Fig. 2) in its Is formed in the longitudinal direction (F i g. 2). 4. Heat exchanger according to claim 1 or 2, characterized in that the individual threshold forms a separate part (sealing plate 46) inserted into the block (40, 48) (F i g. 5). 5. Heat exchanger according to claim 4, characterized in that between the blocks (40, 48) in the case of slot channels essentially of constant depth (42, 43) each has a sealing plate (46) inserted, which has through openings (47) for the aligned tubular channels (41, 44) of the two blocks (40, 48), however the slot channels (42, 43) of the two blocks locks against each other and so at the joint for the slot channels forms thresholds (Fig. 5). 6. Heat exchanger according to one or more of claims 1 to 5, characterized in that that the blocks are made of gas- and liquid-tight graphite. 1 sheet of drawings