Enthalpy Heat Exchanger

Abstract

The invention relates to a counter flow enthalpy exchanger (1) having a parallelogram-shaped central part (11), whose ends in the flow direction through the exchanger it is joined by end parts (12, 13), which become narrower in the direction from the central part (11), whereby in order to separate the flow of the heat-transfer medium in the direction from the inner space to the outer space are arranged contour identical and with respect to the flowing medium sealed vapour-permeable lamellae (10) with shaping means for generating turbulent flow, whereby every two adjacent lamellae (10) form one interplate flow channel in the central part (11) one interplate flow channel. The lamella (10) is made as a one-piece self-supporting moulding common to the central part (11) and the end parts (12, 13), whereby it does not have a reinforcing support grid. Two adjacent lamellae (10) form one interplate flow channel in the end part (12, 13), in the walls of which are formed straight protrusions (121, 131) situated in the direction of the heat-transfer medium flow between the central part (11) and corresponding inlet or outlet of this medium.

Claims

1. The counter flow enthalpy exchanger (1), having a central part (11) shaped as a rectangular quadrangle, at whose ends it is joined in the flow direction through the exchanger by end parts (12, 13), which become narrower in the direction from the central part (11), whereby for the separation of the flow of the heat transfer medium in the direction from the inner space to the outer space are arranged vapour-permeable lamellae (10) with the same area contour which are sealed with respect to the flowing medium and have shaping means for generating turbulent flow, whereby every two adjacent lamellae (10) form in the central part (11) one interplate flow channel characterized in that the lamella (10) is designed as a one-piece self-supporting moulding common to the central part (11) and the end parts (12, 13) without a reinforcing support grid, whereby every two adjacent lamellae (10) constitute in the end part (12, 13) one interplate flow channel, in whose walls are formed straight protrusions (121, 131) situated in the direction of the flow of the heat-transfer medium between the central part (11) and the corresponding inlet or outlet of this medium.

2. The counter flow enthalpy exchanger (1) according to claim 1, characterized in that the self-supporting moulding of the lamella (10) is composite, whereby one of its components consists of a supporting nonwoven layer, which is connected to a vapour-permeable membrane.

3. The counter flow enthalpy exchanger (1) according to claim 2, wherein the material of the vapour-permeable membrane is sulfonated block copolymer.

4. The counter flow enthalpy exchanger (1) according to claim 2, characterized in that the connection of the supporting nonwoven layer with a vapour-permeable membrane is implemented by moulding or welding or gluing or dipping.

5. The counter flow enthalpy exchanger (1) according to claim 1, characterized in that of the lamellae (10) are interconnected at least in some parts of the circumference by welding or gluing by means of airtight joints.

6. The counter flow enthalpy exchanger (1) according to claim 1, characterized in that a lamella (10) is made from flat blanks which are pressed between forming plates having a temperature higher than 40° C.

Description

DESCRIPTION OF DRAWINGS

[0015] The device according to the invention is schematically represented in the drawing, where

[0016] FIG. 1 shows an oblique view of an enthalpy exchanger with the directions of the working medium flow,

[0017] FIG. 2 illustrates a lateral view of the enthalpy exchanger from FIG. 1 in the direction P1,

[0018] FIG. 3 shows a plan view of a lamella,

[0019] FIG. 4a shows a cross-section C-C from FIG. 3, FIG. 4b represents a detail of the curve of the protrusions of the central part of the lamella from FIG. 3,

[0020] FIG. 5 shows an oblique view of the part of the exchanger comprising four lamellae in their joined state and

[0021] FIG. 6 is a detail of the end part from FIG. 5.

SPECIFIC DESCRIPTION

[0022] An enthalpy exchanger is a device serving to transfer heat and humidity from a gaseous medium coming out of the inner working space to a gaseous medium coming from the outer space into the inner space.

[0023] The basic constructional element of an enthalpy exchanger 1 according to the invention is a profiled plate, hereinafter referred to as a lamella 10. The lamellae 10 are stacked in layers on top of each other, whereby adjacent lamellae are along part of their circumferences connected to each other. Thus, alternating flow interplate spaces arise between pairs of lamellae 10 forming channels 2 for the flow of a gaseous medium in the direction A from the enclosed space to the outer space and channels 3 for the flow of the gaseous medium in the direction B from the outer space to the enclosed space. These lamellae allow heat transfer from the heated and humid medium which is taken away, e.g., from an air-conditioned space to a cool and usually dry medium supplied from outside. The lamellae 10 is substantially a moulding made of a planar blank comprising protrusions and recesses on both sides.

[0024] A set of lamellae 10 is inserted and fixed in a casing 100 of the enthalpy exchanger 1. Both outer lamellae 10′, which are adjacent to the side walls inside the casing 100, contribute to the desired character of the medium flow in both end flow spaces, heat and moisture exchange through them virtually does not occur.

[0025] A diagram of the exchanger is shown in FIGS. 1 and 2. In these hatched are the areas between the lamellae 10, or 10′, the areas between inlet or outlet nozzles in the flow inter-plate spaces, while the closed flow inter-plate spaces are not hatched.

[0026] The lamella 10 consists of two components. The first component is a supporting layer of nonwoven fabric, which is coated with a vapour-permeable membrane. Preferably, the membrane is made of sulfonated block polymer. The connection of the supporting nonwoven layer with the vapour-permeable membrane is accomplished by moulding or gluing or dipping. Sulfonated block polymer is advantageous with respect to the degree of vapour permeability, rigidity and dimensional stability both in dry and wet conditions. Moreover, it is also advantageous in terms of the production technology of the membrane, which can be implemented on known coating or laminating devices. Thus, protrusions and recesses can be formed by compressing in the area of the resulting lamella, their purpose being to generate turbulent flow of the medium passing through the gap which constitutes a flow channel between two adjacent lamellae 10 10′. Generally, turbulent flow increases heat transfer and moisture passage efficiency of the flowing medium separated by the lamella.

[0027] A major advantage is the self-supporting structure of the lamella 10. This structure does not contain a reinforcing grid, which in other structures decreases the efficient area for the exchange of heat and humidity between the exhaust and supply stream of the gaseous medium.

[0028] One clear area in the casing 100 of the exchanger 1 is formed by two lamellae 10, which have the same area contour but which differ by the direction of the bending of peripheral edges, by means of which the lamellae are mutually connected. In the description of the shape, to distinguish these two types according to requirements, they will be hereinafter referred to as lamella 10x and 10y.

[0029] In an exemplary embodiment, the central part 11 of the lamella 10 has the shape substantially of a square or rectangle, which is joined in the direction of the length of the lamella by the end part 12, 13, whose area becomes narrower in the direction from the central part. In an illustrative embodiment, the areas of the end parts are triangular. This facilitates an arrangement of the input and output flow of the medium through the exchanger diagonally (see FIG. 1). The flow space between two adjacent lamellae 10 is not divided by any closed partition. It is, of course, possible for the shape of the central part to be also a rectangle or rhomboid with, for example, adjoining unequal-sided triangles of the end parts 12, 13.

[0030] The central part 11 of the lamella 10x is in an example of embodiment according to FIG. 3 shaped by longitudinal parallel undulated protrusions 111. The curve of their ridges 111′ is in the plane of the surface of the lamella 10 substantially a sinusoid Sx. The distance between two neighbouring ridges 111′ is a pitch R. The ridges 111′ of the protrusions 111 are indicated by the solid line, recesses in the middle between them form protrusions on the other side of the lamella 10. The cross-section C-C of the central part from FIG. 3 is shown in FIG. 4a. In an exemplary embodiment, the height v of the wave of the protrusions 111, that is the maximum thickness of the lamella 10, is 3.5 mm. The sinusoid Sx of the ridge 111′ of the protrusions 111 starts in the part adjacent to the end part 12 with a lower peak DV. In the part adjacent to the end part 13 the sinusoid Sx ends with an upper peak HV.

[0031] In the case of the lamella 10x of the first type, the edge 123 of the end part 12 (in FIG. 3 up on the left) is bent upwards, the second edge 124 of the end part 12 is bent downwards. The edge 133 of the end triangular part 13 parallel to the edge 123 of the end triangular part 12 is bent upwards, while the edge 134 of the end triangular part 13 parallel to the edge 124 of the end triangular part 12 is bent downwards.

[0032] In the case of the lamella 10y of the second type, the sinusoid Sy of the ridge 111″ of the protrusions 111 is shifted relative to the position of the sinusoid Sx of the lamella 10x by half the length λ of the wave of the sinusoid Sx, Sy so that it begins in the part adjacent to the end part 12 with the upper peak HV and in the part adjacent to the end part 13 ends with the sinusoid Sy with the lower peak DV (FIG. 4b). At the points where the sinusoid Sx and Sy cross or touch each other, the adjacent ridges 111′, 111″ touch each other as well.

[0033] The end triangular parts 12, 13 are provided with moulded straight elongated discontinuous protrusions 121, 131, which have the direction of the medium flow in this part of the flow space and which on the opposite side of the lamella form recesses 122,132, which do not worsen the flow on this opposite side of the lamella, although they are perpendicular to this direction.

[0034] The height of the protrusions 121, 131 and recesses 122, 132 of the end parts 12, 13 is at the most 1.7 mm.

[0035] The thickness and planar dimensions of the lamella 10, the height of the protrusions 121, 131, the height v of the wave of the undulated central part 11 in the embodiments according to the technical solution (not shown) may change, without exceeding the scope of protection defined by patent claims.

[0036] In the case of the lamella 10y of the second type, the edge 123 of the end part 12, which is parallel to the protrusions 121, is bent downwards, whereas the second edge 124 of the end part 12 is bent upwards. The edge 133 of the end triangular part 13 which is parallel to the edge 123 of the end triangular part 12, is bent downwards, while the edge 134 of the end triangular part 13, which is parallel to the edge 124 of the end triangular part 12, is bent upwards.

[0037] FIGS. 5 and 6 illustrate stacking the individual lamellae 10 on top of each other and their connection. In an exemplary embodiment, the enthalpy exchanger 1 comprises twenty lamellae 10. FIG. 4 illustrates four lamellae, which are indicated from top to bottom as 10x.sub.1, 10y.sub.2, 10x.sub.3, 10y.sub.4. FIG. 6 shows a detail of the left side of the set of the lamellae.

[0038] The circumferences of the assembled lamellae touch along the longitudinal sides 112 of the central part 11, where they are cement, forming opposite walls 113 of the casing 100 of the exchanger 1. Similarly, also the ends of the end parts forming the narrow faces 114 of the casing 100.

[0039] Adjacent lamellae 10 are alternately closed by the edges 123, 124, 133, 134 according to FIGS. 5 and 6. The edges 123, 124, 133, 134 are connected by welding or gluing.

[0040] On the left-hand side of FIG. 5 and FIG. 6 there are welded edges 123 of the lamellae 10y.sub.2, 10x.sub.3, by which means the space between these lamellae is closed, whereas between the edges 123 of the lamellae 10x.sub.1 and 10y.sub.2 the inlet into or outlet out of the space is opened. Also between the edges 124 of the lamellae 10x.sub.3 and 10y.sub.4 there is an inlet or outlet opening. Further on, there is an illustration of two welded edges 124 of the lamellae 10x.sub.1 and 10y.sub.2, 10x.sub.3 and 10y.sub.4.

[0041] On the right-hand side of FIG. 5 there is a visible welded joint of the edges 133 of the lamellae 10y.sub.2 and 10x.sub.3 and inlet nozzles between the edges 133 of the lamellae 10x.sub.1 and 10y.sub.2, 10x.sub.3 and 10y.sub.4. On the contrary, the invisible art of the circumference of the end part 13 contains analogically to a part of the circumference of the end part 12 with the edges 124 (a front view in FIG. 6) two welded edges 134 of the lamellae 10x.sub.1 and 10y.sub.y, 10x.sub.3 and 10y.sub.4. Between the edges 134 of the lamellae 10y.sub.2, 10x.sub.3 there is also an inlet or outlet opening.

[0042] Beside the major advantage, which is the self-supporting structure of the lamella 10 and therefore the absence of a reinforcing grid, the enthalpy exchanger 1 entails an advantage of a relatively long path, on which the exchange of heat and humidity between counterflow streams of the medium takes place. Beside irregularities of the surface of the lamellae 10 of the central part 11 contributing to a considerable extent to the effectiveness of the exchange of heat and humidity, further increase in the efficiency is achieved by reducing the resistance to the flow of the medium in the end parts 12, 13 by means of the shape and particularly the direction of the protrusions 121, 131 in these parts.

LIST OF REFERENCES

[0043] 1 enthalpy exchanger [0044] 10 lamella (10′, 10x, 10y, 10x.sub.1, 10x.sub.3, 10y.sub.2, 10 y.sub.4) [0045] 100 casing of the exchanger [0046] 11 central part (of the lamella) [0047] 111 protrusion (of the central part of the lamella) [0048] 111′ ridge of the protrusion (of the central part of the lamella) [0049] 111″ ridge of the protrusion (of the central part of the lamella) [0050] 112 longitudinal side of the central part [0051] 113 wall of the casing (of the exchanger upper, lower) [0052] 114 narrow face (of the casing of the exchanger front, rear) [0053] 115 side wall (of the casing of the exchanger) [0054] 12 end part (of the lamella) [0055] 121 (straight) protrusion (in the area of the end part) [0056] 122 (straight) recess (in the area of the end part) [0057] 123 edge (of the end part) [0058] 124 edge (of the end part) [0059] 13 end part (of the lamella) [0060] 131 (straight) protrusion (in the area of the end part) [0061] 132 (straight) recess (in the area of the end part) [0062] 133 edge (of the end part) [0063] 134 edge (of the end part) [0064] 2 channel (flow in direction A) [0065] 3 channel (flow in direction B) [0066] A direction of flow (from the enclosed space outwards) [0067] B direction of flow (from the outer space to the inner space) [0068] DV lower peak (sinusoid) [0069] HV upper peak (sinusoid) [0070] R pitch distance of the crests (of the protrusions of the central part) [0071] S.sub.x sinusoid [0072] S.sub.y sinusoid [0073] v height of the wave of protrusions (of the central part) [0074] λ length of the wave of sinusoid S.sub.x, S.sub.y