EP1452817A1 - Heat exchanger - Google Patents

Abstract

Plate heat exchanger comprises a heat exchanger block (1a, 1b) with a number of heat exchanger passages. A header (6a, 6b, 7a, 7b) extending over at least one part of one side of the heat exchanger block is attached to the heat exchanger block. The header forms a flow connection between one part of the heat exchanger passages and is provided with a fluid connection (12, 13) arranged perpendicularly to the side of the heat exchanger block over which the header extends. Devices for guiding the flow of fluid entering or leaving via the fluid connection are provided within the header. Preferred Features: The header has a semicircular cross-section.

Description

The invention relates to a plate heat exchanger with a heat exchanger block, the has a plurality of heat exchange passages, with the heat exchanger block a header is attached which extends over at least part of one side of the Extends heat exchanger blocks and a flow connection between one Part of the heat exchange passages and the one with a fluid connection is provided, the fluid port being substantially perpendicular to the side of the Heat exchanger block is arranged over which the header extends.

The heat exchanger block of a plate heat exchanger consists of several layers of heat exchange passages, each against the other by dividers are delimited. End strips and cover plates form the outer frame of the Heat exchanger block. Additional separating strips can be provided within one layer be the heat exchange passages for different material flows from each other separate.

The heat exchanger block, which initially consists of loose components, is then turned into soldered to a soldering oven so that all components are tightly connected. Then the Heat exchange passages welded header, with a fluid connection are provided. Semi-cylindrical shells are usually used as headers. The fluid connection is formed by pipe sockets in the semi-cylinder jacket of the header are arranged opposite the inlet and outlet openings. To this Pipe sockets become the pipelines for the fluid flows to be fed in and out connected.

By means of a suitable arrangement of separating strips, plate heat exchangers for the simultaneous heat exchange of many fluid flows can be used. For each the fluid flows are then corresponding headers above the respective inputs and Outlet openings of the heat exchange passages to be installed and with pipes to provide. The piping of the plate heat exchanger is very great in this case complex and complex.

The object of the present invention is to provide a plate heat exchanger to improve the type mentioned.

The plate heat exchanger according to the invention has a heat exchanger block a variety of heat exchange passages. The heat exchange passages can be divided into certain groups, with the heat exchange passages a group each serve to guide a specific fluid flow. On the There are entry and exit openings in the heat exchange passages of a group Headers each attached so that there is a flow connection between them Passages is made.

The header, sometimes also called a collector, covers part of one From the heat exchanger block side and forms a closed space with it the inlet or outlet openings of a group of heat exchange passages lead. According to the invention, the header is provided with a fluid connection, which in the Is arranged substantially perpendicular to the side of the heat exchanger block the header extends.

The fluid connection, i.e. the opening of the header to the respective fluid flow or discharging pipelines, is arranged in one plane, which is essentially is perpendicular to the plane in which the corresponding inputs or Exit openings are located in the heat exchange passages. That is, the Fluid connection is not directly opposite the inlet or Exit ports.

The inventive design of the header and in particular the Fluid connection it becomes possible to connect all fluid connections to two opposite Sides of the heat exchanger block. It is often even possible that To design plate heat exchangers so that all fluid connections are on the same Side of the heat exchanger block. The pipes for feeding and discharging the material flows brought into heat exchange therefore no longer have to are laboriously routed around the heat exchanger block. The Piping work is significantly reduced.

The header according to the invention is not only used to distribute the feed Fluid flow on the heat exchange passages or to collect the from Heat exchange passages exiting fluid, but also for supply or discharge the corresponding fluid flows.

This double function is taken into account according to the invention in that within the header means for guiding the flow to or via the fluid connection removed fluids are provided. For example, within the header a baffle can be arranged, which the space within the header in one Flow area, which is preferably used for supplying and discharging the fluid, and into one Distribution area divided in which the flow is calm and one if possible uniform distribution of the fluid on the heat exchange passages.

The headers preferably have a semicircular cross section, in particular semi-cylindrical shells have proven themselves as headers. With one The half-shell-shaped version of the header is then the fluid connection in one of the two semicircular bases. For strength reasons it can be advantageous, the other of the base areas not perpendicular, but for example to be oriented diagonally to the half-cylinder jacket.

In the versions used so far, the supply and discharge of the Fluid flows through a pipe socket that is welded to the half-shell this point must be provided with an appropriate opening, however, as a result the strength of the half-shell is significantly weakened. In contrast to that the fluid connection according to the invention is not in the half-cylinder jacket of the header, but in one of the semicircular bases. With the same wall thickness points thus the header according to the invention has a higher strength than that above known header described. Conversely, at a given Target strength in the design of the header according to the invention is lower Wall thickness can be selected, which reduces costs.

One of the main advantages of the invention, namely the simplification of the piping, comes into play particularly when the plate heat exchanger has several Has heat exchanger blocks. For manufacturing reasons, for example due to the The size of the soldering furnace is limited to the dimensions of a heat exchanger block set. If larger amounts of fluid are to be heated or cooled, it is required to arrange two or more heat exchanger blocks in parallel. So far with such a parallel arrangement of each heat exchanger block, as at the beginning described, with the corresponding headers and those welded to them Provide pipe socket. A manifold is provided for each material flow which are connected to the corresponding pipe socket. The piping of such This makes plate heat exchangers extremely complex.

In contrast, the heat exchanger blocks are not according to the invention Pipe socket and a manifold connected on the flow side, but the Fluid connection of the header of a heat exchanger block is made directly with the Fluid connection of the header of an adjacent heat exchanger block connected. The fluid connection preferably extends over the entire cross section of the Headers and will keep the cross section on the adjacent header connected. The result is a continuous header that spans all Extends heat exchanger blocks.

Are advantageous in a plate heat exchanger with more than one Heat exchanger block the heat exchanger blocks spaced side by side arranged so that a gap remains between the heat exchanger blocks. The Heat exchanger blocks are preferably installed with a spacer connected to each other, usually welded together. Can be used as a spacer for example, an appropriately shaped sheet or a bar can be used.

It is particularly favorable if the spacer is in the area of the header is arranged that the side of the header facing the heat exchanger blocks is completely covered by the spacer in the area of the gap. In in this case, the space inside the header is covered by the header itself, for example a semi-tubular shell, the side walls of the Heat exchanger blocks and part of the spacer limited.

The parallel arrangement of several heat exchanger blocks makes it particularly clear that the header according to the invention not only for distributing the supplied Fluid flow on the heat exchange passages or to collect the from Heat exchange passages exiting fluid is used, but also for the supply or Discharge of the corresponding fluid flows.

Figuren 1 und 2

je eine Seitenansicht eines Wärmetauscherblocks mit zwei Headern,

Figuren 3 und 4

den Wärmetauscherblock mit erfindungsgemäß angeschweißtem Rohrleitungsstück,

Figur 5

zwei nebeneinander angeordnete Wärmetauscherblöcke zur Herstellung eines erfindungsgemäßen Plattenwärmetauschers,

Figur 6

einen erfindungsgemäßen Plattenwärmetauscher und

Figur 7

eine Seitenansicht des Plattenwärmetauschers nach Figur 6.

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

Figures 1 and 2

a side view of a heat exchanger block with two headers,

Figures 3 and 4

the heat exchanger block with a pipe section welded in accordance with the invention,

Figure 5

two side-by-side heat exchanger blocks for producing a plate heat exchanger according to the invention,

Figure 6

a plate heat exchanger according to the invention and

Figure 7

a side view of the plate heat exchanger according to Figure 6.

In Figures 1 and 2, a plate heat exchanger is shown schematically as he is also known from the prior art. The plate heat exchanger has one Heat exchanger block 1 with a variety of heat exchange passages that the For the sake of clarity, the figures are not shown. The inputs and Outlet openings of a group of heat exchange passages are located in the Area 2 on a side wall 3 of the heat exchanger block 1 or in area 4 on the bottom 5 of the heat exchanger block 1. On the areas 2, 3 with the Einund Outlet openings are welded on semi-cylindrical headers 6, 7.

The headers 6, 7 are designed as semi-cylindrical shells with base areas 8, 9, 10, 11. In the headers 6, 7 baffles 23, 24 are arranged, which the space within the Divide headers 6, 7 into a flow area 25 and a distribution area 26. The Baffles 23, 24 are provided with a plurality of openings so that a gas and Liquid exchange between the flow region 25 and the Distribution area 26 is possible.

In Figures 3 and 4, the connection of the piping to the See plate heat exchanger. The bases 8, 9 of the half cylinders 6, 7, i.e. the Side walls of the headers 6, 7 serve as fluid connections for the supply and discharge of the fluid passed through the heat exchange passages. The two others Base areas 10, 11 of the headers 6, 7 are closed. On the base areas 8, 9 pipelines 12, 13 are attached. The pipes 12, 13 are with the Headers 6, 7 tightly connected so that, for example, an inflowing fluid over Pipeline 12 flows through the open base 8 into the header 6 and in the Header 6 is distributed to the corresponding heat exchange passages. In analog Way, the fluid after the heat exchange via the header 7 and Pipeline 13 discharged again.

Both pipes 12, 13 are on the same side of the Heat exchanger blocks 1. The connection of the heat exchanger and the others Piping is therefore easily possible.

Figure 5 shows an intermediate stage in the manufacture of an inventive Plate heat exchanger. The heat exchanger blocks 1a, 1b are identical to that in 1 and 2 shown heat exchanger block 1 constructed.

The heat exchanger blocks 1a, 1b are first of all with their respective headers 6a, 6b, 7a, 7b subjected to a leak test and a pressure resistance test. To all bases 8a, 9a, 10a, 11a of headers 6a and 7a are successful of the heat exchanger block 1a and the bases 8b, 9b of the headers 6b, 7b of the Heat exchanger blocks 1b separated. On the two sides facing each other the header 6a, 6b, 7a, 7b is separated, as in FIG. 5 by dashed lines Lines 20 shown, oblique to the axis of the semi-cylindrical headers 6a, 7a, 6b, 7b. The base areas 8a, 9a of the heat exchanger block 1a become perpendicular to the axis the semi-cylindrical header 6a, 7a cut off.

The two heat exchanger blocks 1a, 1b are then at their lower ends a sheet 16 welded together. The U-shaped sheet 16 is so on Heat exchanger blocks 1a, 1b attached that the base of the U-shaped plate 16 the Bottom sides 5a, 5b of the two blocks 1a, 1b connect so that one continuous level results. In the area of the headers 6a, 6b, the two Heat exchanger blocks 1a, 1b also connected to a U-shaped plate 27, whose base is in the plane of the drawing and from the upper edge 21a, 21b of the heat exchanger blocks 1a, 1b to the lower edge 22a, 22b of the headers 6a, 6b extends on which the semi-cylindrical header shell on the heat exchanger block 1a, 1b hits.

Figures 6 and 7 show the finished plate heat exchanger. Between the headers 6a, 6b and the headers 7a, 7b of the two heat exchanger blocks 1a, 1b each one adapted pie-shaped intermediate piece 17, 18 used and with the Headers 6a, 6b, 7a, 7b and the U-shaped plates 16 welded. To the Base areas 8a, 9a of headers 6a, 7a are welded on pipes 12, 13. Both pipes 12, 13 are on the same side of the Heat exchanger blocks 1a. The connection and the further piping of the Heat exchangers are therefore easily possible.

In operation, for example, a fluid is supplied via pipeline 12, which fluid flows into the through the baffle 23 separated flow area 25 of the header 6a and over the pie-shaped connector 18 in the flow area 25 of the header 6b flows. The baffles 23 of the two headers 6a, 6b have a plurality of Openings through which the fluid flows into the flow-reduced distribution areas 26 arrives. In the distribution areas 26 of the heads 6a, 6b, the fluid is applied to the corresponding heat exchange passages of the heat exchanger blocks 1a, 1b distributed.

In an analogous manner, the fluid after the heat exchange via the headers 7a, 7b with the intermediate connector 17 and the pipe 13 again dissipated. The headers 7a, 7b are also in one by a baffle 24 flow-reduced area 26 and a flow area 25 divided. The In this case, flow-calmed region 26 essentially serves for collecting and bringing together the fluid exiting the heat exchange passages and the flow region 25 for discharging the fluid to the pipeline 13.

Claims (4)

Plate heat exchanger with a heat exchanger block, which has a plurality of heat exchange passages, a header being attached to the heat exchanger block, which header extends over at least part of one side of the heat exchanger block and which establishes a flow connection between part of the heat exchange passages and which is provided with a fluid connection, wherein the fluid connection is arranged substantially perpendicular to the side of the heat exchanger block over which the header extends, characterized in that within the header (6, 7) means (23, 24) for guiding the flow via the fluid connection (12, 13) - Or discharged fluids are provided. Plate heat exchanger according to claim 1, characterized in that the header (6, 7) has a semicircular cross section. Plate heat exchanger according to one of claims 1 or 2, characterized in that the plate heat exchanger has a plurality of heat exchanger blocks (1a, 1b) and the header (6a, 6b; 7a, 7b) establishes a flow connection between heat exchange passages of different heat exchanger blocks (1a, 1b). Plate heat exchanger according to claim 3, characterized in that the heat exchanger blocks (1a, 1b) are spaced apart and the gap between the heat exchanger blocks (1a, 1b) is closed by means of a plate (16, 27) or a strip that the heat exchanger blocks (1a, 1b) facing side of the header (6a, 6b; 7a, 7b) through the side surfaces (5a, 5b; 6a, 6b) of the heat exchanger block (1a, 1b) and / or the sheet (16, 27) or the strip is completely covered.

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