EP0844454A1 - Counterflow heat exchanger - Google Patents

Abstract

The heat exchanger has plates (1) which are fitted above, below or against each other to form intermediate cavities (6). They are sealed to each other at the edges (8). Two fluid flows (A,B) pass through the intermediate cavities alternately in opposite directions. Each plate has a sinusoidal cross-section (3), with wave troughs (4) and wave crests (5). The wave troughs lie against the wave crests of the adjacent plate at one side, and the wave crests lie against the wave troughs of the plate on the other side.

Description

The invention relates to a counterflow heat exchanger with plates, forming gaps arranged above or below or next to each other and the spaces between them to the direction of flow of the two alternating and essentially anti-parallel flowing fluid flows parallel edges tightly together are connected.

Such counterflow heat exchangers have thermodynamic favorable properties because the two fluid or Gas flows passed through them antiparallel in countercurrent will. You can, for example, as a recuperative Heat recovery systems for waste heat recovery, for heat recovery in air conditioning Systems and in cooling, especially in application evaporative cooling.

The invention has for its object the described generic counterflow heat exchanger to develop in such a way that its efficiency increases further is.

This object is achieved in that each plate of the counterflow heat exchanger essentially one sinusoidal corrugated cross section with troughs and has wave crests with their wave valleys against the wave crests of those neighboring on one side Plate and with their wave crests against the Wave valleys of the plate adjacent on the other side is present. Due to the sinusoidal structure chosen of the plates forming the countercurrent heat exchanger transversely to the direction of flow of the fluid flows successive fluid channels that are practical on their entire circumferential surface of fluid channels, each of which flow through another gas or fluid stream, are surrounded. This will make the specific heat exchange surface of the counterflow heat exchanger according to the invention compared to conventional counterflow heat exchangers significantly increased. In addition, the effort for entertainment and maintenance of the counterflow heat exchanger according to the invention comparatively low because of the rounded structure of the two fluid flows leading channels the risk of contamination is only slight.

The maximum possible specific heat exchange area as well one in terms of pollution prevention particularly advantageous structure of the gaps or Channels can be reached if the is essentially sinusoidal corrugated cross section of the plates is designed that the space forming and transverse to the direction of flow the fluid flows successive fluid channels are approximately circular.

Around both the inlet and outlet widths of the counterflow heat exchanger for the two fluid flows, it is appropriate if each plate on its two Longitudinal ends at a transition section gradual reduction in the depth of their troughs or the height of their wave crests from their sinusoidally wavy ones merges into a flat cross section. By means of such a Transitional section on the fluid flow Input section of the counterflow heat exchanger can the fluid flow in a way that is less susceptible to interference Interspaces forming, arranged side by side Fluid channels are introduced. For that for this fluid flow provided output section of the counterflow heat exchanger applies accordingly that the respective fluid flow from the side-by-side arrangement as trouble-free as possible round fluid channels in a single due to the flat Design of the plates more or less gap-shaped Flow cross section can pass.

The fact that at the one transition section each Plate one inlet section and to the other transition section an outlet section connects each plate, both the inlet section and the outlet section a sealing edge on one side of the panel's longitudinal center line the counterflow heat exchanger - seen in flow direction or in flow directions - both at one end and at the other End each an inlet section and an outlet section form, with a fluid flow through the inlet portion at one end and the outlet section at the other end and the other fluid flow through the inlet section at the other end and the outlet section one end is led.

They can be constructed in a structurally less complex manner Inlet and outlet sections for the two fluid streams designed when the inlet portion and the outlet portion each plate from its transition section side Ends towards their free ends about taper triangular, with one leg of the triangular Inlet or outlet section the sealing edge having.

Provided the inlet and outlet sections of each plate support elements abutting against an adjacent plate may also have in the inlet and outlet sections of the counterflow heat exchanger created a structure become more neighboring due to mutual support Plates even with large pressure differences between the two flowing through the counterflow heat exchanger Gas or fluid flows are extremely high Stability guaranteed.

The separation of the Inlet section of a gas or fluid stream and Outlet section of the other gas or fluid flow at both Realize end sections of the counterflow heat exchanger, if the sealing edge of the inlet section is one Plate on one and the sealing edge of the outlet section this plate on the other side of the plate longitudinal line are arranged.

The flow conditions at both the inlet sections as well as at the outlet sections of the counterflow heat exchanger can be advantageously compared if the support elements parallel to the sealing edges of their Extend plates and designed as fluid guide elements are.

The counterflow heat exchanger according to the invention can be used a comparatively low design effort and with the smallest possible number of different components manufacture when the inlet portion of a plate is the outlet portion the following plate and the outlet section one plate to the inlet section of the following plate are assigned, the sealing edge of the inlet section one plate on one side of the plate longitudinal center line and the sealing edge of the outlet section the following plate on the other side of the Longitudinal plate center line, the sealing edge of the outlet section one plate on the other side of the Longitudinal plate center line and the sealing edge of the inlet section the following plate on one side the plate longitudinal center line are arranged and wherein the fluid guide elements of the inlet and outlet sections one plate perpendicular to the fluid guide elements of the The outlet and inlet sections of the following plate run.

In an advantageous embodiment, there is the invention Counterflow heat exchanger essentially only two plate types, the sealing edges and fluid guide elements of the one plate type perpendicular to the sealing edges and fluid guide elements of the other Plate type are arranged and being on a plate of the one plate type a plate of the other plate type follows.

To ensure a secure seal between the successive plates, it is advantageous if the Dimension of the parallel to the flow direction of the fluid flows Edges of the panels correspond to twice the panel spacing; so that for example by welding or Glue these angled flat together Edges can be firmly and tightly connected.

In the following, the invention is illustrated by an embodiment explained in more detail with reference to the drawing.

Figur 1

einen Querschnitt durch einen Haupt- bzw. Gegenstromabschnitt einer Ausführungsform eines erfindungsgemäßen Gegenstromwärmetauschers;

Figur 2

eine Draufsicht auf eine Platte des in Figur 1 dargestellten erfindungsgemäßen Gegenstromwärmetauschers;

Figur 3

eine Schnittdarstellung durch einen Übergangsabschnitt des in Figur 1 dargestellten erfindungsgemäßen Gegenstromwärmetauschers;

Figur 4

eine Längsansicht des in Figur 3 dargestellten Übergangsabschnitts und eines Einlaß- bzw. Auslaßabschnitts;

Figur 5

ein Endbereich der in Figur 2 dargestellten Platte des erfindungsgemäßen Gegenstromwärmetauschers;

Figur 6

den Schnitt A - B in Figur 5;

Figur 7

eine Querschnittsdarstellung von durch die Platten des erfindungsgemäßen Gegenstromwärmetauschers gebildeten annähernd kreisförmigen Fluidkanälen;

Figur 8

den Schnitt A - B in Figur 9; und

Figur 9

eine Prinzipdarstellung eines Endabschnitts des erfindungsgemäßen Gegenstromwärmetauschers.

Show it:

Figure 1

a cross section through a main or countercurrent section of an embodiment of a countercurrent heat exchanger according to the invention;

Figure 2

a plan view of a plate of the countercurrent heat exchanger according to the invention shown in Figure 1;

Figure 3

a sectional view through a transition section of the counterflow heat exchanger according to the invention shown in Figure 1;

Figure 4

a longitudinal view of the transition section shown in Figure 3 and an inlet or outlet section;

Figure 5

an end region of the plate of the countercurrent heat exchanger according to the invention shown in Figure 2;

Figure 6

the section A - B in Figure 5;

Figure 7

a cross-sectional view of approximately circular fluid channels formed by the plates of the countercurrent heat exchanger according to the invention;

Figure 8

the section A - B in Figure 9; and

Figure 9

a schematic representation of an end portion of the counterflow heat exchanger according to the invention.

A in Figure 1 in cross section of its actual countercurrent section illustrated countercurrent heat exchanger according to the invention is made up of plates 1, one of which Type of construction is shown in Figure 2.

In their the actual counterflow section of the counterflow heat exchanger middle sections 2 the plates 1 have a sinusoidally corrugated cross section 3 on.

With the troughs 4 of the sinusoidally corrugated cross section 3 lies each plate 1 on the wave crests 5 of sinusoidal corrugated cross section on one side adjacent plate 1; the same applies to the wave crests 5 and the troughs 4 on the other side neighboring plate 1.

Due to the plant between the troughs 4 and Wave crests 5 of the plates 1 result in a stable structure of the counterflow heat exchanger, the between the plates 1 formed spaces 6 from a A large number of almost circular fluid channels 7 exist. Here, as can be seen from FIG. 1, each fluid channel 7, which flows through the one fluid or gas stream A. is surrounded on all sides by fluid channels 7, which by flow through the other fluid stream B. This gives a particularly high specific heat exchange surface of the counterflow heat exchanger according to the invention. Because of the approximately circular configuration of the cross section of the fluid channels 7 is the risk of contamination within of the countercurrent section shown in cross section in FIG of the counterflow heat exchanger is extremely low.

Because of the routing of the two fluid or gas flows A, B in countercurrent, the heat exchange between the two gas or fluid flows A, B in thermodynamic accomplish favorably.

As can be seen from FIGS. 1, 3, 7 and 8, the Plates 1 bent at right angles on their long sides Edges 8, the dimensions of which are approximately twice the average Distance of the plates 1 corresponds to each other. On this Edges 8 can be the plates 1 by welding or connect the adhesive seal.

At the points of contact between the wave crests 5 and the troughs 4 is no attachment between the Plates 1 provided, since the possibly by column on the mentioned contact points Fluid channels 7 all from the same gas or fluid flow A or B are flowed through.

As can be seen in particular from FIG. 2, each plate has 1 the middle section 2 by the one shown in Figure 1 has sinusoidally corrugated cross section 3; on that formed by the sinusoidally corrugated cross section 3 middle section or counterflow section 2 of the Plate 1 closes a transition section on both sides 9 or 10. In the transition sections 9 and 10 goes the plate 1 from the sinusoidally corrugated cross section 3 to a flat cross section 11 about how best to look Figures 3, 4 and 8 results.

In the plate 1 shown in Figure 2 is above or before the transition section 9, an inlet section 12 trained, whereas below or behind the transition section 10 an outlet section 13 follows. One of Both gas and fluid flows A, B pass through the inlet section 12 and the transition section 9 in the middle Section 2 of plate 1 or the counterflow heat exchanger a; after flowing through the middle or counterflow section 2 occurs this gas or fluid flow A or B through the transition section 10 and the outlet section 13 from the counterflow heat exchanger.

The inlet section 12 and the outlet section 13 taper triangular from the transition section 9 or 10. One leg 14 or 15 of the triangular inlet section or outlet section has a sealing edge 16 and 17 respectively, which in the case of the inlet section 12 on the left side of one shown in Figure 9 Plate longitudinal center line 18 and in the case of the outlet section 13 on the right side of this longitudinal plate center line 18 is arranged.

The gas or fluid flow A, B occurs in the area of the sealing edge free Leg 19 of the inlet portion 12 in the Counterflow heat exchanger enters and occurs in the area of the sealing bend-free Leg 20 of the outlet section 13 on the counterflow heat exchanger.

To equalize the flow conditions are both in the area of the inlet section 12 as well as in the area of the outlet section 13, support elements 21 are provided, which are parallel to the sealing edge 16 or 17 of the Extend inlet section 12 or outlet section 13, so that the support elements 21 at the same time as fluid guide elements serve and those passing through the inlet portion 12 Gas or fluid flow A, B in the transition section 9 deflect or from the transition section 10th escaping gas or fluid flow A, B for sealing bend-free Deflect leg 20 of outlet section 13.

The support elements 21 correspond in terms of their dimensions in the thickness direction of the plate 1 the plate distance in Area of the two end sections of the countercurrent heat exchanger, so that they rest against the adjacent plate 1. This also results in the area of the two end sections of the counterflow heat exchanger even at strong different pressures of the two gas or fluid flows A, B sufficient stability.

The counterflow heat exchanger according to the invention consists of Plates 1 of the type shown in Figure 2 and from plates 1 of the type of construction partially shown in FIG. 9, at which the sealing edges 16 and 17 and the support elements 21 perpendicular to the sealing edges 16, 17 and Support elements 21 of the type shown in Figure 2 run.

By alternately stacking plates 1 of the two construction types mentioned arises in the middle or Counterflow section 2 the cross-sectional image shown in Figure 1, being in the two end sections of the counterflow heat exchanger Inlet sections 12 for one Gas or fluid flow A or B with outlet sections for change the other gas or fluid flow B or A. There the inlet sections 12 and the outlet sections 13, respectively Plate 1 - for both types of plates 1 - on each different sides of the plate longitudinal center line 18 are arranged, are the legs without sealing edges 20 of the outlet sections 13 offset by about 90 degrees to the Legs free of sealing edges of the outlet sections 13 overlying inlet sections, as best shown in Figure 9 emerges. The flow path of both the fluid or Gas flow A and the opposite fluid or Gas stream B is thus Z-shaped, the two gas or Fluid flows A, B in the middle or counterflow section 2 of the counterflow heat exchanger flow past each other in antiparallel.

The depth and number of wave valleys 4 and wave crests 5 of the sinusoidally corrugated cross section 3 in the middle or counterflow section 2 of the counterflow heat exchanger is arbitrary and according to the requirement profiles regarding the pressure loss and the heat recovery suitably selectable. With the counterflow heat exchanger according to the invention can be due to the thermodynamic favorable countercurrent flow high heat recovery achieve; due to the smooth, almost circular cross-sections of the fluid channels 7 in the middle or counterflow section 2 the pressure loss is comparatively low, in addition, the effort for elimination of dirt or the like. for this reason significantly reduced is. Since the individual plates 1 of the invention Countercurrent heat exchanger support each other and a comparatively rigid structure of the invention Form countercurrent heat exchanger, there is a Stability, even with large pressure differences between the two gas or fluid streams A, B is sufficient.

Claims (11)

Counterflow heat exchanger with plates (1) which are arranged one above the other, one below the other or with the formation of gaps (6) and at their parallel edges parallel to the flow direction of the two fluid flows (A, B) alternating and essentially antiparallel flowing through the gaps (6) (8) are tightly connected to one another, characterized in that each plate (1) of the countercurrent heat exchanger has an essentially sinusoidally corrugated cross-section (3) with wave troughs (4) and wave crests (5), with their wave troughs (4) against the wave crests ( 5) which is adjacent to the plate (1) on one side and with its wave crests (5) against the troughs (4) of the plate (1) adjacent to the other side. Counterflow heat exchanger according to claim 1, wherein the essentially sinusoidally corrugated cross section (3) of Plates (1) is designed such that an intermediate space (6) forming and transverse to the flow direction of the fluid flows (A, B) successive fluid channels (7) approximately circular are. Counterflow heat exchanger according to claim 1 or 2, wherein each plate (1) at each of its two longitudinal ends Transitional section (9, 10) by gradual reduction the depth of their wave valleys (4) or the height of their wave crests (5) from its sinusoidally corrugated (3) into one flat cross section (11) merges. Counterflow heat exchanger according to claim 3, wherein to a transition section (9) of each plate (1) Inlet section (12) and to the other transition section (10) each plate (1) is connected to an outlet section (13), wherein both the inlet section (12) and the outlet section (13) on one side of the plate longitudinal center line (18) have a sealing edge (16, 17). Counterflow heat exchanger according to claim 4, wherein the inlet section (12) and the outlet section (13) each Plate (1) from its transition section ends in Taper towards their free ends approximately triangularly, one leg (14, 15) of the triangular inlet (12) or outlet section (13) the sealing edge (16, 17). Counterflow heat exchanger according to claim 3 or 4, wherein the inlet (12) and outlet (13) portions of each plate (1) against an adjacent plate (1) supporting elements (21). Counterflow heat exchanger according to one of claims 4 to 6, in which the sealing edge (16) of the inlet section (12) a plate (1) on one and the sealing edge (17) of the outlet section (13) of this plate (1) on the arranged on the other side of the plate longitudinal center line (18) are. Counterflow heat exchanger according to claim 6 or 7, wherein the support elements (21) parallel to the sealing edges (16, 17) extend and designed as fluid guide elements are. Counterflow heat exchanger according to one of claims 4 to 8, in which the inlet portion (12) of a plate (1) the Outlet section of the following plate (1) and the outlet section (13) the one plate (1) the inlet portion of the following plate (1) are assigned, the sealing edge (16) of the inlet section (12) of the one plate (1) on one side of the plate longitudinal center line (18) and the sealing edge of the outlet section of the following plate (1) on the other side of the plate's longitudinal center line (18), the sealing edge (17) of the outlet section (13) one plate (1) on the other side of the plate longitudinal center line (18) and the sealing edge of the inlet section the following plate (1) on one side the plate longitudinal center line (18) are arranged and wherein the support or fluid guide elements (21) of the inlet (12) and the outlet section (13) of one plate (1) perpendicular to the fluid guide elements of the outlet and inlet sections the following plate (1). Counterflow heat exchanger according to claim 9, which consists of two Plate types is made, the sealing edges (16, 17) and the support and fluid guide elements (21) of one Plate type perpendicular to the sealing edges and fluid guide elements of the other plate type are arranged and wherein on a plate (1) of one type of plate a plate (1) of the other plate type follows. Counterflow heat exchanger according to one of claims 1 to 10, where the dimension of the flow direction the fluid flows (A, B) parallel edges (8) double Distance between plates.

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