NL2026943B1 - Recuperator with improved channel configuration - Google Patents

Abstract

The invention relates to a recuperator, comprising a number of stacked plates extending parallel to each other with their main planes mutually parallel, which are provided with repeating mutually parallel profiles which form channels extending between the plates, each of the plates at one end. adjacent on its sides to channels of the first type and on its other side to channels of the second type, the profiles being provided with parts extending with a directional component transverse to the main plane of the plates, which form side walls of the channels and of parts extending substantially parallel to the major plane of the plates, forming end walls of the channels, and wherein the channels have a cross-section of a trapezoid, and the cross-section has a greater dimension in the direction transverse to the main direction of the plates than the largest dimension of the cross-section in the main direction of the plates.

Description

Recuperator with improved channel configuration The invention relates to a recuperator.

A recuperator is a heat exchanger in which two fluid flows are passed past each other without coming into contact with each other, but in which thermal energy can be exchanged between the two flows.

Such recuperators are known from various patent documents, including EP-A-0 835 416. More particularly, the present invention relates to recuperators comprising a plurality of superimposed plates extending parallel to each other with their major planes, which of repeating, mutually parallel profiles are provided which form channels extending between the plates, each of the plates adjoining on one of its sides to channels of the first type and on its other side to channels of the second type, and wherein the profiles are provided with parts extending with a directional component transverse to the main plane of the plates and forming side walls of the channels and with parts extending substantially parallel to the main plane of the plates and forming end walls of the channels, the channels having a cross-section of a trapezium, and the cross-section has a larger dimension in the direction transverse to the main direction ng of the plates then has the greatest cross-sectional dimension in the main direction of the plates.

Such recuperators are known from NL-B-2 016 347. In this known recuperator the side walls of the channels extend substantially perpendicular to the main plane of the plates.

In order to be able to release the plates from the moulds, the side walls should extend slightly convergently towards the mould.

This applies to plates formed by thermoforming as well as plates formed by injection moulding.

In the latter case the degree of convergence may indeed be very small, in the order of magnitude of 19, but even this small degree of convergence has a strong adverse effect on the heat transfer between the fluid flows in adjacent channels.

The present invention attempts to eliminate these drawbacks.

The invention is based inter alia on the insight that the slight trapezoidal shape of the channels caused by the convergence of the side walls means that the distribution of the fluid flow in the channels is not uniform. Since the shape of the trapezoidal channels separated by a single side wall is opposite, the distribution of the flow rates of the flows is also opposite so that the flows with the largest flow rates are far from each other. The heat that has to be exchanged by the flows therefore has to travel a relatively large distance, which greatly affects the effectiveness of the heat transfer.

Applicant has found that by providing bulges in the narrow end sides of the channels a much more uniform distribution of the flow occurs, so that heat transport between the flows in adjacent channels has to transfer a smaller distance and the heat transfer is greatly improved.

Although the positive effects are already achieved with a partial application of the measures according to the invention, the effects are optimized when all channels are provided with a bulge at their narrow end sides. It is noted here that it is possible that not all channels apply this measure at the edges of the recuperator.

The effects of the invention, i.e. the uniform distribution of the current density of the flow over the cross-section of the channels, are best manifested when the channel is narrow, i.e. the size of the cross-section of the channels in the transverse direction is in the main direction of the plates is at least twice as large as the largest dimension of the cross-section of the channels in the main direction of the plates. Instead of a factor of five between the measures of the channel, the effects appear to be better when the factors 8, 10, 12, 15 or 20 are applied as the limit.

The effects of the measures according to the invention are already apparent with a bulge of an arbitrary shape, but the effects appear to be optimal when the bulge is provided with two side walls extending substantially transversely to the main direction of the plate.

To form a recuperator, the plates are stacked. Stacking is made easier when the side walls of the bulge are separated from the side walls of the channels by shoulder strips extending with a component in the main direction of the plate. As a result of this measure, the narrow end faces fit onto each other and space is created for a vertical play between the plates in order to absorb small differences in size and deformation of the plates without creating space between the channels, thereby negating the effect of the invention. This same advantage arises when the plates are stacked with the open bottoms of the channels above the closed tops of the underlying channels and that the side walls of channels located diagonally above each other touch each other.

In order to facilitate stacking of the formed plates, it is preferred that the protrusion is provided with an outwardly bent front side.

Applicants have found that the effects of the invention are optimal when the width of the bulge is less than 2 of the smallest width of the channel. Furthermore, this has the advantage that the plates fit well into each other.

It is attractive when the corners of the seams of the bulge on the outside of the seams are rounded. This simplifies production.

The clearance between the plates, together with small dimensional deviations of the plates, leads to recuperators in which shoulder strips adjacent to abutting sidewalls of bulges do not all touch.

In order to arrive at a functioning recuperator, it is important that it is provided with headers connecting on both sides to the channels of the recuperator for forming a connection to supply and discharge channels.

Although the advantages of the invention are manifested in plates produced in various ways, it is preferred that the plates are manufactured by means of injection molding.

Next, the invention will be elucidated with reference to the accompanying figures, in which: Figure 1: a schematic cross-sectional view of a part of a recuperator for explaining a first effect; Figure 2: a cross-sectional view of another detail of a recuperator for explaining a second effect; and Figure 3: a cross-sectional view of part of a recuperator according to the invention.

Figure 1 shows a schematic cross-sectional view of a series of channels of a recuperator. This recuperator 1 is provided with channels 2 with a trapezoidal cross-section. As already mentioned in the introduction, for releasing the walls 3 from the channels 2, plates forming the molds require that the walls 3 taper slightly. This not only applies to plates formed by means of thermoforming, but also to plates formed by injection moulding. In the latter case, the inclination need only be small, on the order of 1°. Particularly in the case of narrow channels, the trapezoidal shape results in the majority of the fluid flow in the channel 2 being located in the widest part of the channel. This is shown in Figure 1. The adjacent trapezoidal channels have their widest part alternately above and below, so that the distance between the widest parts of adjacent channels is large. It is in the widest parts of the channels that the most flow takes place, and the heat flow between the largest fluid flows has to travel a great distance, which reduces the effectiveness of the recuperator. To reduce this problem, the invention provides means for better distributing the flow density over the cross section of the channels. To this end, a bulge is made on the narrow side of the channels 2 . This bulge is shown in figure 2. This figure shows a detail of the front sides 5 of a number of plates forming channels 2 . The end walls 5 are each provided with a bulge 6 . Applicants have found that the protrusions lead to a more even distribution of the fluid flow over the cross-section of the channels. As a result, the distance between the largest fluid flows in adjacent channels is greatly reduced, so that the effectiveness is greatly improved. Figure 2 further shows an example of a protrusion, which has a substantially rectangular configuration. The end walls 5 each comprise two shoulder strips 7, which separate the protrusions 6 from the longitudinal walls 8 of the channels 2. The protrusions 6 each comprise two side strips 9 and a head strip 10. In the present case, there is talk of a symmetrical configuration. Although asymmetrical configurations are not excluded a priori, it is now assumed that symmetrical configurations are more attractive, as they lead to a symmetrical current distribution in the channels and thus to a better heat transfer.

A second effect of the protrusion resides in providing clearance between the protrusions belonging to different plates. It is hereby possible to compensate for small deviations in the flatness of the stacked plates without a connection being created between different channels. Such a connection does not per se lead to mixing of the fluid flows of the first and second type, but it does lead to a disturbance of the flow pattern and thus to a deterioration of the effectiveness. Such problems are avoided by the shape of bulges.

Finally, figure 3 shows a cross-sectional view of a recuperator according to the invention. The main difference with the recuperator shown in figure 2 is the kink 11 in the head strip 10 of the bulge, as a result of which the head strip is divided into two parts 10a and 10b. Due to this bend 11, the plate fits easily into the lower or upper plate. Incidentally, it is also possible in this embodiment that the kink is omitted and that the parts 10a and 10 are co-parallel. As a result, the wall 9 can be made slightly higher, so that greater deviations from the flatness of the plates can be accommodated.

Furthermore, in this embodiment the shape of the seams on the inside between the shoulder strips 7 and the side strips 9 of the bulges 6 on the side of the channel is rounded, which is attractive for the flow distribution. Also, the seams between the side strips 9 and the head strip parts 104, 10b of the bulge 6 on the side of the connecting channel are rounded, so that the sliding of the plates into each other when forming the recuperator is facilitated.

The above description is for the purpose of illustrating the invention only and the scope of the invention is defined only by the claims.

Measures shown in various embodiments can be combined with one another.

Claims (12)

Conclusions Recuperator, comprising: - a number of stacked plates extending parallel to each other with their main planes, which are provided with repeating mutually parallel profiles which form channels extending between the plates, - each of the plates on one of its sides are adjacent to channels of the first type and on its other side are adjacent to channels of the second type, the profiles being provided with parts extending with a directional component transverse to the main plane of the plates, which form side walls of the channels and of parts extending substantially parallel to the main plane of the plates, forming end walls of the channels, and - wherein the channels have a cross-section of a trapezoid, and the cross-section has a greater dimension in the direction transverse to the main direction of the plates than the largest dimension of the cross-section in the main direction of the plates, characterized in that at least part of the number all channels are provided with a bulge on their narrow ends. 2. A recuperator according to claim 1, characterized in that each of the channels is provided with a bulge on their narrow end sides. 3. A recuperator according to claim 1 or 2, characterized in that the size of the cross-section of the channels in the direction transverse to the main direction of the plates is at least five times greater than the largest size of the cross-section of the channels in the main direction of the plates. 4. A recuperator according to any one of the preceding claims, characterized in that the protrusion is provided with two side walls extending substantially transversely to the main direction of the plate. 5. A recuperator according to claim 4, characterized in that the side walls of the bulge are separated from the side walls of the channels by shoulder strips extending with a component in the main direction of the plate. 6. Recuperator as claimed in claim 4 or 5, characterized in that the protuberance is provided with an outwardly bent end wall. 7. A recuperator according to claim 4, 5 or 6, characterized in that the width of the bulge is less than % of the smallest width of the channel. Recuperator according to one of Claims 4, 5 or 6, characterized in that the corners of the seams of the bulge are rounded on their outer side of the seams. A recuperator according to any one of the preceding claims, characterized in that the plates are stacked with the open undersides of the channels above the closed top of the underlying channels and in that the side walls of channels located diagonally above each other touch each other. 10. A recuperator according to claim 9, characterized in that the shoulder strips adjacent to adjacent side walls of bulges do not all touch. A recuperator according to any one of the preceding claims, characterized in that the recuperator is provided with headers connecting on both sides to the channels of the recuperator for forming a connection to each of the channels of the first and second types, respectively. . A recuperator according to any one of the preceding claims, characterized in that the plates are manufactured by means of injection moulding.