SE460151B - DEVICE FOR INDIRECT EVAPORATIVE COOLING - Google Patents

Abstract

Apparatus for indirect, evaporative cooling of an useful air current, including a contact body (10) made up in layers, with duct systems between the layers. There are two separate duct systems, useful air for cooling passing through one system (16), while a cooling air current passes through the other system (18). Cooling takes place by evaporation of water in the other duct system (18). The duct-forming means (16, 18) in both systems are disposed such that the useful and cooling air currents flow horizontally, while water supply means (24) supplying water to the other duct system (18) are disposed at the top of the contact body (10), allowing the water to flow vertically downwards in this system (18).

Description

The contact body 10 shown in Figure 1 is used as an indirect, evaporative heat exchanger between a useful air stream which flows substantially horizontally through the contact body 10 and which is to be cooled and which is supplied to the lower oblique end surface 28 shown in Figure 1, which forms the inlet. to a first duct system in the contact body 10, and flows it through in the longitudinal direction in said ducts or gaps which are separate from adjacent ducts or gaps in a second duct system which is passed by a cooling air stream.

The contact body 10 can for instance be built up of a number of flat plates 11-15 which, as can be seen from Figure 5, are assembled with intermediate, flange-like stiffening and surface enlarging means which in the embodiment shown are formed by pleated plate 16. the folds in plate 16 form the channels for the useful air to be cooled in the contact body 10 and the plates 16 are arranged with the folds running in the direction of flow of the air.

The inclined plate 16 thus defines the width of the channels or gaps in the contact body through which the useful air passes.

The plates 11-15 and 16 are made of a thin material with good thermal conductivity, such as metal, for example aluminum, and are joined together, for example by heat bonding, gluing or some other suitable bonding method. They can be made, for example, as sandwich elements which are rigid in themselves. A desired number of such elements are, as can be seen from Figure 5, connected to each other by a space which is determined by spacers 32 arranged between the elements (Figure 6). In this way, the spacers also define the width of the slots 18 of the second duct system in the contact body through which the cooling air stream is to pass.

In order to achieve the evaporative cooling effect, the walls of the slits 18 are wetted in a known manner for which purpose the surface of the plates 11-15 facing the slits 18 is provided with a layer, denoted by 20, of a water-absorbing and / or absorbent material. During the passage of the cooling air through the gaps 18, an evaporation of water to the cooling air will take place so that an intensive transfer of heat is obtained from the useful air in the first duct system to the cooling air in the gaps 18, whereby the temperature of the useful air is lowered to a low value. The walls are normally kept moist only to the extent required for evaporation. Due to the evaporative cooling effect, the gaps passed by the cooling air can be made much narrower than the gaps passed by the useful air, which is made possible in a simple way by the construction according to the invention where the sandwich elements 12, 14, 16 and the gaps 18 can be made. with any desired width independently. Normally, the required amount of cooling air is also less than the amount of useful air due to the evaporative effect.

The flanges of the stiffening member or elm 16 included in the sandwich element 12-16 constitute a large heat transfer surface which is coated by the passing useful air stream.

In the embodiment shown in Figure 5c, the rigid panels are made of five flat plates 11-15 with intermediate, pleated plates 16, but the panels can of course be built up of only two flat plates 11, 15 with an intermediate three flat plates and inclined plates. depending on the desired stiffness and heat transfer surface desired.

The described device 10 is connected in a ventilation system, the useful air flow being sucked through the ducts 16 in the first duct system by means of a fan 22 (figure 1). A part of the air stream, for example 10-50% of this cooled useful air stream is returned as cooling air stream in countercurrent to the useful air stream through the second duct system 18 where it is moistened by water supplied from the top of the device 10 through nozzles 24, the described evaporative cooling having room. The cooling air flow through the device 10 is provided with a second fan 23 which leads the cooling air flow to the outlet or exhaust air duct. The useful air flow is supplied to the supply air duct in the ventilation system or directly to a room to be conditioned. 460 151 Figure 2 shows how the main part of the useful air stream leaves the ducts 16 and which cooled air flows out into the room or into the supply air duct in a ventilation system, while a partial stream turns and enters the ducts 18 as cooling air stream, as described above. Preferably, as shown in Figures 1, 3 and 46, the plates 11 to 15 are shaped rectangular, but at a vertical end, the left one in the figures, provided with a connecting part preferably as a triangularly shaped connecting part where the shorter side 26 forms outlet from the second duct system 18 while the longer side 28 forms the inlet to the duct system 16. To seal the duct system 18 from the duct system 16 at this triangular end, a sealing strip 30 is arranged between the plates 11, 15 adjacent to the ducts 18, which are shown in figure 6. In this figure which shows the plate 11 or 15 seen from the inside of a channel 18 the spacer holders 32 which determine the width of the channels 18 are also shown. It can be seen that the sealing strip 30 also forms a spacer. The more or less point-shaped spacers 32 can also be replaced by inclined strips at the upper and lower edges of the plate 11, 15 and the right end. The wells in the strips shall then run in the water's resp. the direction of the cooling air flow.

Figure 3 shows the flow pattern of the cooling air flow in a channel 18, from which it appears that the cooling air flow flows from the right side of the body to the outlet 26. When the second channel system comprises channels 18 which extend over the entire surface of the plate and are not divided by partitions or Veller it may happen that the cooling air flow at the top has a tendency to deviate upwards where the duct is open towards the water supply nozzles 24 shown by the upper dashed line in figure 3. To reduce this deviating tendency various measures can be taken, for example partitions 34 can be arranged between the nozzles 24,. as shown in Figure 4. Figure 3 also shows that the body below is provided with a collecting trough 36 for excess water. If desired, a recirculation of water from the trough 36 to the nozzles 24 can be provided. 460 151 In order to prevent the cooling air flow from deviating from the horizontal flow path at the bottom in the same way as at the upper part, partitions 35 can also be arranged in the trough 36 which extend down to the normal water level in the trough and prevent the air from deviating downwards. In this way, the cooling air flow both at the top and bottom of the contact body will flow substantially horizontally in heat-exchanging exchange with the useful air flow in the ducts 16.

The triangular inlet part of the duct system 16, which also constitutes the outlet part of the duct system 18, is suitably arranged at the inlet 28 of the ducts 16 so that a substantially lower flow resistance is obtained than in the package itself. This can be achieved, for example, by the welded plates 16 here being replaced by a plate with larger wells or by a number of strips which stiffen up the inlet part without exerting any significant resistance to the air flow. Examples of such strips are shown at 27 in figure 1. It appears from the figure that the inlet-outlet part 26, 28 is unilateral, ie. the inlet for the useful air stream is larger than the outlet 26 for the cooling air stream. The outlet for the moist cooling air stream is also suitably directed upwards to prevent unnecessary entrainment of water from the moist channels 18. Of course, the inlet 28 to the channel system 16 of the useful air stream could be the entire vertical side and the cooling air stream taken out vertically upwards. However, the triangular design shown provides other advantages as described below.

As shown in Figure 7, a number of modules or connector bodies 10 may be built on top of each other into a larger assembly. In such a stack, the useful air can thus be supplied to the contact bodies 10 via the inlets 28 and the cooling air stream is diverted from the bodies via the outlets 26 in a very simple manner thanks to the triangular design of the inlet-outlet part. Another advantage of this design is that the water can be supplied jointly to all the contact bodies 10 at the top of the stack via the nozzles 24 and collected at the bottom of the stack in the trough 36. The same water thus flows through all the modules 10 "4so 151 through their duct system 18. The composition shown of several contact bodies or modules 10 also does not change the thermodynamics.

The embodiments shown and described are, of course, only examples of the realization of the invention, and changes may be made within the scope of the underlying idea. w

Claims (12)

460 151 1. CLAIMS 1. An apparatus for indirect, evaporative cooling of a useful air stream comprising a contact body which is made up of layers with ducts existing between the layers which are divided into two duct systems which are separated and of which a system is traversed by the useful air stream to be cooled and the the second duct system of a cooling air stream which provides the cooling of said useful air stream, the cooling being effected to a substantial extent by evaporation of water in the second duct system, characterized in that the duct-forming means in the two duct systems are arranged so that both the useful air flow as the cooling air flow runs horizontally, while water supply means for supplying water to the second duct system are arranged at the top of the contact body so that the water flows vertically downwards in the second duct system. Device according to claim 1, characterized in that the inlets and the outlets of the two duct systems are arranged so that the useful air flow and the cooling air flow flow in countercurrent to each other. Device according to claim 1 or 2, characterized in that the outlet from the first duct system and the inlet to the second duct system are arranged adjacent to and connected to each other so that the cooling air flow to the second duct system is branched off as part of the air leaving the first duct system. Device according to one of Claims 1 to 3, characterized in that the contact body at its one vertical side is formed with a triangular tip, the two projecting sides of the triangle being designed as an inlet to the first channel system resp. outlet from the second duct system. 460 151 8 5. Device according to claim 4, characterized in that the triangular tip is unilateral and that the larger side forms an opening for the useful air flow. Device according to one of Claims 1 to 5, characterized in that the contact body is built up of a number of flat plates with intermediate, flange-like stiffening and surface-enlarging members lying therebetween which form a number of rigid panels, which by means of spacers are joined to the contact body, the spacers defining the second channel system, while the panels comprise the first channel system. Device according to one of Claims 4 or 5, characterized in that the triangular inlet part of the first duct system is designed with a lower flow resistance than the rest of the duct system. Device according to one of Claims 1 to 7, characterized in that the outlet from the second duct system is directed upwards. Device according to claim 6, characterized in that the spacers are designed so that the cooling air and the water flow substantially unhindered in the second duct system, for example they are point-shaped. Device according to any one of the preceding claims, characterized in that means are arranged at the upper and lower side of the contact body, which means are arranged to prevent cooling air from deviating from the water supply means or water collecting means at the lower side of the contact body. ' 11. ll. Device according to claim 6, characterized in that the stiffening means are formed by inclined plates between the flat plates and that the inclined plates are arranged with the well tops lying in the same horizontal plane. lv 460 151 Device according to any one of the preceding claims, characterized in that a plurality of contact bodies are stacked on top of each other, the water supply at the top of the stack to the second duct system and collection of water at the bottom of the stack being common to all contact bodies in the stack.