DE3301211A1 - Plate heat exchanger - Google Patents

Abstract

The invention relates to a plate heat exchanger consisting of a plurality of plates, which can be joined to one another to form a plate stack with the interposition of sealing strips which essentially run around the plate rim, can be inserted into sealing beads and have inwardly directed transverse strips, between which plates flow gaps are formed into which there open apertures, constructed in the plates, for two separate media which flow through the flow gaps on both sides of the plate. In order to increase the heat transfer capacity and the economic efficiency of the heat exchanger, the flow gaps have for one medium webs which conduct the medium along multiple paths through the flow gaps, and the plates are provided in a manner known per se with fins embossed in a zigzag fashion. <IMAGE>

Description

The invention relates to a plate heat exchanger according to the preamble of claim 1.

Such a plate heat exchanger is known from DE-PS 615 356. The sealing strips and transverse strips, which are made of rubber, are vulcanized onto the plate, with the plate having recesses or elevations for the firm connection of the strips to the sheet metal plate. Due to the transverse strips, the flow path in the flow gap is zigzag. The transverse strips reduce the flow cross-section, which increases the flow rate, which has the advantage that the heat transfer coefficient oL and thus the heat transfer coefficient k can be improved with lower or different flow rates. In the case of very low or very different flow rates, however, even with such a heat exchanger, the heat transfer is not yet possible.

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There is a temperature overlap, ie when the outlet temperature of the heat-emitting medium is below the outlet temperature of the heat-absorbing medium. With the practiced series or series / parallel connection of the volume flows, an ideal countercurrent is not possible, because the heat exchange is worsened or canceled by direct current phases at overlapping temperatures. Optimal heat transfer performance can only be achieved with large heat transfer coefficients oL on both sides of the medium. The heat transfer coefficients oL depend, among other things, strongly on the turbulence of the medium, in such a way that the heat transfer coefficient becomes smaller with decreasing turbulence and becomes larger with increasing turbulence. An increase in the flow velocity also has an increasing effect on the heat transfer coefficient cL . The lower heat transfer coefficient in each case determines the heat transfer coefficient k. If the flow rates or the flow rates of the media are very low or very different, the flow rate can be increased by providing deflection strips in the manner of the plate heat exchanger of DE-PS 615 356, but the resulting increase in the heat transfer coefficient is usually not sufficient. To achieve a satisfactory heat transfer rate, so that heat exchangers with a larger pool must nevertheless be used in order to achieve a specific

Lowering the temperature of the heat-emitting medium and increasing the temperature of the heat-absorbing medium.

The object of the present invention is therefore to provide a plate heat exchanger according to the preamble of To train claim 1 so that the heat transfer performance and thus the economy of the heat exchanger, at which the flow rates are very small or very different, is increased.

This object is achieved by the design specified in the characterizing part of claim 1.

The object solution according to the invention is a multi-way one Formation of the flow path for the medium before, but the flow paths are not strictly separated from one another are, but have mixed phases. This and the larger number of flow edges an increase in turbulence is achieved. In addition, the inventive design of the flow cross-section decreased and thus increased the speed. The profiling of the plate surface is simultaneously the heat exchange surface increases. By the invention Training can thus the heat transfer and correspondingly the heat transfer coefficient and thus the heat transfer performance can also be increased. The design according to the invention can reduce the flow behavior Both media can be adapted to the respective conditions so that even with very small or strong different flow rates and with countercurrent operation

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can achieve a satisfactory specific heat transfer performance.

Advantageous and expedient developments of the invention The solution to the problem is characterized in the subclaims.

The invention is now based on the accompanying drawing, the embodiments of the inventively designed Plate.eines plate heat exchanger shows, are explained in more detail.

It shows

1 shows a plate designed according to the invention for a plate heat exchanger as a four-way plate,
2 shows a plate designed according to the invention

as an eight-way plate, Fig. 3 shows another embodiment of the invention

and

Fig. 4 schematically shows the flow path through a plate stack with parallel connection of the Flow gap based on the countercurrent principle.

The same components are shown in the figures of the drawing are given the same reference numerals.

The drawing shows a plate 2 of a not shown, usually consisting of a plate pack Plate heat exchanger. The plate, which here has an approximately rectangular shape (other shapes are possible), has

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in the corners openings 4, 6, 8 'and 1o for the passage of the heat exchanger media, one or two of the openings depending on the mode of operation and arrangement in the plate pack can be closed. To increase the heat exchange surface, the plate is shaped with profiles 12 - r> ier zigzag embossed grooves - provided, as shown schematically in the drawing. One side of the plate is provided with a circumferential edge sealing bead 14 which surrounds an exchange surface 16 for the one medium, which the openings 4 and 8 includes. Further sealing beads 18 surround the openings 4 to 10 for the other Medium.

With the interposition of sealing strips 22, 24, which are inserted into the sealing beads, several panels are then hung in a frame and pulled together (not shown) . The seals 22, 24 are arranged so that the media do not mix can.

On one side, the plate 2 is also rr.with transverse beads 28, into which sealing webs 3o, 31 can be inserted. The Cicntungsstege 3o are with both sides of the edge seal 22 connected crossbars, the free ends of which are arranged opposite one another at a distance from one another, so a central flow channel 32 is formed between them will. Dii: also QuoiTuioue forming sealing webs. "-. 1 are with ti '.; between .-. Ic η ^ ufoinar.dorfolondari lateral.

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Arranged transverse webs 3o and preferably form, as shown in FIGS. 1 and 2, the first and last Cross web in the row of cross webs 3o, 31. They each form two lateral flow channels 33, 34.

The sealing webs 3o, 31 form deflecting webs or guide webs through which the flow path is deflected several times, divided and brought together again. The central transverse webs 31 act as flow dividers and the lateral ones Cross webs as flow mergers. This design reduces the flow cross-section and thus the Flow velocity as well as the flow turbulence increased. The lateral sealing webs 3o are integral with the Edge seal 22 is formed.

To simplify production and to adapt the heat exchanger to different To facilitate conditions, both sealing crosspieces 3o, 31 initially form rungs between opposite ones Pages of the Randdicbtung 22 - in the manner of a ladder grid. Only when the individual panels are put together are the Sealing crossbars - as described above - by lateral separation from the edge seal and shortening as well as central Trained to cut and shorten. The webs 3o, 31 are preferably glued into the transverse beads embossed in the plate. The number of way, i.e. the number of cross bars and the flow cross-sections can be selected depending on the conditions.

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The central flow channels 32 do not need to be along them to run along the center line of the plate, but can also alternate left and right offset to the center line be arranged, whereby a wave-shaped 'flow path' superimposed on the multi-path flow path v; ird.

Fig. 3 shows another embodiment of the plate, in which two connected to the edge seal 22 lateral Cross webs 38, 4o one behind the other, are provided alternately on the left and right, so that, as in the prior art known to result in a zigzag flow path. In addition, however, there are more in the middle on both sides of the lateral crosspieces

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Cross bars available as guide bars.

4 shows schematically the flow path through a plate pack with parallel connection of the flow gaps the countercurrent principle. There are only the flow gaps of the one medium with the low flow rate Provided cross webs according to the above training, which is in the

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Drawing has been indicated by the zigzag lines.

If the flow rates of both media are low, the Provide flow gaps in both media with crossbars according to the design and arrangement described above.

Due to the formation of the plates described above A flatworm exchange is a substantial increase read heat transfer - and with it the heat aurcnganaakceffiiiientün t "for i: the medium with each lower flow

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The individual plates of the heat exchanger are the same

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educated. They throw 180 consecutively assembled rotated so that the embossed grooves 12 cross. The crossing points form a multitude of support points, which, even with a relatively low material thickness for the plate, ensures a stable behavior of the flow gap to back up.

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Claims (8)

Expectations 1J plate heat exchanger, consisting of several plates that can be joined together with the interposition of sealing strips, which essentially run around the plate edge, can be inserted into sealing beads and have inwardly directed transverse strips, to form a plate pack, between which flow gaps are formed, into which openings for two are formed in the plates separate media flowing through the flow gaps open on both sides of the plate, characterized in that the flow gaps for a medium have webs (3o, 31) leading the medium through the flow gaps in several ways, and that the plates in a known manner with zigzag-shaped ribs are provided. 2. Plate heat exchanger according to claim 1, characterized in that the webs from opposite sides of the edge seal (22) of the plate (2) integrally connected, protruding into the interior of the flow gap, lateral crossbars (3o) and from both sides or between these crossbars ( 3o) approximately in the middle, spaced on both sides Dr.K./H. -2- COPY! formed in front of the edge seal (22) ending transverse webs (31) are. 3. Plate heat exchanger according to claim 2, characterized in that the lateral transverse webs (3o) are arranged opposite one another and that a central flow channel (32) is formed between the free ends of these webs. 4. Plate heat exchanger according to one of the preceding claims, characterized in that a central and two lateral, opposite transverse webs are arranged alternately one behind the other over the flow gap length. 5. Plate heat exchanger according to one of the preceding claims, characterized in that the mif-.tigoi transverse webs (31) are provided as flow dividers and the lateral transverse webs (3o) are provided as flow mergers. 6. Plate heat exchanger according to one of the preceding claims, characterized in that the webs (3o, 31) consist of sealing strips which can be inserted into beads (28) formed in the plates (2). 7. Plate heat exchanger according to one of the preceding claims, characterized in that the webs (3o, 31) -3- in the form of rungs are connected to two opposite sides of the edge seal (22) of the plate and to Production of the lateral crosspieces can be separated and shortened approximately in the middle and for the production of the approximately centrally arranged Cross webs (31) on both sides of the edge seal (22) can be separated and shortened. 8. Plate heat exchanger according to one of the preceding claims, characterized in that the webs (3o, 31) are provided in the flow gaps for both media.