NL1022795C2 - Dew point cooler, has heath-conducting wall and protrusions that are covered by hydrophobic coating to absorb evaporable liquid and water supply conduit to wet medium using evaporable liquid - Google Patents

Abstract

The cooler has two medium circuits coupled via a heath- conducting wall. Two media flow through the circuits such that the latter medium has conducting protrusions. The wall and the protrusions are covered with a hydrophobic coating to absorb the evaporable liquid. A water supply conduit (59) wets the latter medium using the liquid such that the liquid entrained by the medium extracts heat from the former via the wall.

Description

V

Dew point cooler

The invention relates to a cooling device and in particular a dew point cooler.

The invention provides a dew point cooler, comprising: a first medium circuit and a second medium circuit thermally coupled thereto via an at least partially heat-conducting wall, which two circuits can be flowed in countercurrent through two respective media, wherein at least the second medium is a gas, for example air , contains with a relative humidity of less than 100%; which heat-conducting wall has break-up means for breaking up at the location of at least heat transfer active zones in at least the primary medium both media of at least the thermal boundary layer, the laminar boundary layer, and the relative humidity boundary layer, which breaking-up means comprise heat-conducting protrusions which comprise the effective heat-conducting surface of said wall 20; wherein the heat-conducting surfaces of said wall and the break-up means are covered at least in part in the area of the secondary medium with a hydrophilic, for example hygroscopic, cover layer, which cover layer is for instance porous and / or a vaporizable liquid through capillary action, for example can absorb water, retain it, and relinquish it by evaporation, such that the wetted cover layer and thereby also the heat-conducting surfaces and the break-up means are cooled; differential pressure-based primary drive means, for example a fan or pump, for the primary medium; differential drive based secondary drive means, for example a fan, for the secondary medium; and a wetting unit for wetting the secondary medium through wetting by evaporating liquid from the cover layer such that the evaporated liquid entrained by the secondary medium extracts heat from the primary medium via the heat-conducting wall; wherein the cover layer consists of a porous technical ceramic material, for example a baked layer, a cement such as a Portland cement, or a fibrous material, for example a mineral wool such as rock wool, and wherein the heat transfer coefficient of the entire wall is at least IW / m2K .

Very good results have been achieved, in particular with Portland cement. The layer may consist of this microporous-type cement, the layer thickness being, for example, of the order of 50 µm.

It is known that a liquid can be cooled more or less in a very primitive manner, for example in a warm, sunny environment by enveloping the liquid in a container by a damp cloth. Because the water in the cloth evaporates due to the heat and possibly wind, an evaporation occurs which is accompanied by a temperature reduction in the wall of the container, which is passed on to the liquid present therein. This dew point cooling, known per se, is based on this generally known basic principle.

A dew point cooler is a specific type of enthalpy exchanger. As is known, enthalpy 35 is defined as the sum of the internal energy and the product of pressure and volume in a thermodynamic system. It is an energy-like property or state function and has the dimension of energy. The 1022795 3 value is determined solely by temperature, pressure and composition in the system.

According to the law of energy conservation, the change of the internal energy is equal to the heat transferred to the system minus the work done by the system. For example, if the only work performed is a volume change at constant pressure, the enthalpy change is exactly the same as the energy supplied to the system.

10 In the context of dew point cooling, the heat of evaporation of water is an essential aspect. When boiling water, energy is supplied to the water, but the temperature cannot rise above the boiling point. The work performed on the system in this case is used to cause the water to pass into water vapor. This process is referred to as evaporation and takes place isothermal in this case. It is essential that a phase change occurs from the liquid phase to the vapor or gas phase.

The reverse process, in which gas or vapor condenses into liquid, is referred to as condensation. For example, condensation can occur in moist air, ie water-evaporating air, in the case where the air in question comes into contact with such a cold surface that the relative humidity locally rises to the saturation value associated with the relevant temperature. In that case the air is no longer able to take up the amount of water present, as a result of which the water changes from the gas or vapor phase to the liquid phase.

Compared to this known technique, the dew point cooler according to the invention is superior in the sense that its performance is substantially improved by the various characteristic features mentioned. Important is the use of the aforementioned surface-enlarging break-up means, which make the substantial contribution to the heat transfer between the heat-conducting wall and the respective passing-through media. The characteristic 1022795 4 quantity here is the so-called Nusselt number, which is a measure of this heat transfer and can achieve very high values according to the invention.

It is important to draw attention to the fact that the surface-increasing break-up means make the temperature working range of the dew point cooler considerably larger. For example, under practical conditions and with a well-designed dew point cooler according to the invention, it is possible to work with an inlet temperature, i.e. the inlet temperature of the primary medium, of, for example, 80 ° C.

Furthermore, it is important that the heat-conducting surfaces and the break-up means 15 are covered in the indicated manner with a hydrophilic cover layer, which is moreover capable of buffering a sufficiently large amount of water, which water is supplied intermittently, for example, by said humidifying unit.

It is emphasized that the humidification unit must be designed in such a way that no, or at least negligible, misting occurs, but that there must be, for example, an intermittent liquid stream that directly keeps the hydrophilic cover layer wet. Only in this way is the operation as a dew point cooler ensured with high efficiency, unlike, for example, in the case where a heat-conducting wall without a cover layer or with a thin cover layer is sprayed through a sprayed liquid. In this case, evaporation already takes place in the relevant medium flow, whereby, although this flow cools, the heat transfer to the wall, through the wall and then to the medium on the other side of the wall will be very limited.

According to an aspect of the invention, the dew point cooler has the special feature that the cover layer consists of a plastic. In this embodiment, too, the plastic can be of a porous type. The porosity may, for example, have been obtained by shrinking on cooling or curing. Use can also be made of a gel, which can for instance have a hygroscopic character, can thus absorb water and can relinquish a flowing stream of air.

The embodiments described above can advantageously have the special feature that the effective outer surface of the cover layer from which the liquid can evaporate is at least 100x, preferably at least 1000x, as large as the projected surface thereof. It should be understood that the outer surface of a cover layer may, for example, have an irregular shape, comparable to, for example, the Brittany coastline. In this case it can be achieved on a micro-scale that the effective surface is extremely much larger than the projected surface and that a highly effective breaking up of said boundary layers can take place locally due to turbulences and other air movements.

A preferred embodiment has the special feature that the dew point cooler is dimensioned in such a way that the medium flows have values such that in the secondary flow the dew point is approached within 1 ° C. The dimensioning in question can be realized on the basis of the above-mentioned prescriptions according to the invention by designing the dew point cooler in depth on the basis of knowledge.

According to yet another aspect of the invention, the dew point cooler can have the special feature that the break-up means comprise fins, which fins are designed as a number of strips, each with a general wave shape, of each of which strips consecutive wave crests on one side with the wall and that the cover layer is applied substantially only to the surface of each strip remote from the wall. Such fins without a covering layer are known per se, for example from car radiators. They are very effective and, in the context of the dew point cooler according to the invention, give a surprisingly high efficiency in combination with a carefully selected hydrophilic cover layer, in particular a cover layer consisting of microporous Portland cement.

As already mentioned above, on the basis of available knowledge with regard to heat exchangers, the dew point cooler according to the invention can be designed with care on the basis of the principles of the present invention, such that a high efficiency is realized. In this connection, a variant is important in which use is made of the said aspect with regard to substantially increasing the effective outer surface of the cover layer, wherein also the properties of the cover layer and those of the liquid are mutually chosen such that that (a) a predetermined amount of liquid can be buffered in the cover layer per unit area of the wall and the break-up means; and (b) the heat resistance of a coating filled with liquid 20 is negligible transversely of its main surface with respect to the total heat resistance in the path between the heat-conducting wall and the secondary medium flowing past.

Use can be made of an optionally adjustable reversing unit for reversing a part of the primary medium flow at the output of the first medium circuit to form the secondary medium flow. In this case there is a gross primary medium flow, a net primary medium flow that is delivered as an effective flow in the cooled state and a tare branch flow, which has a cooling effect via the evaporation of liquid in the branched medium active as a secondary medium. exercise on the gross primary medium flow. The tare secondary flow heated by the gross primary flow is discharged as a loss to the environment, in particular to the outside environment. The secondary current may have a value of, for example, in the order of 30% of the gross primary energy.

Since the ratio between the said gross current and the tare current substantially influences the efficiency of the dew point cooler, an embodiment can have the special feature that the ratio between the primary current and the said part of the primary current is adjustable such that the efficiency of the dew point cooler is adjustable.

In a particular embodiment in which the last aspect is included, the dew point cooler according to the invention has the special feature that the adjusting means are designed as an optionally adjustable passage in the primary circuit and an adjustable passage in the secondary circuit. The primary circuit, like any flow-through circuit, has a certain flow resistance. This means that in the case of a branch of a secondary circuit a certain flow will occur therethrough, which depends on the flow resistances in the upstream and downstream primary circuit and those in the secondary circuit. For example, in the case where the primary circuit is not variable, by selecting the flow resistance in the secondary circuit, the ratio between the respective flow rates can be set to adjust the efficiency of the dew point cooler. A valve with adjustable passage can also be used in both the downstream primary circuit and the secondary circuit.

In order to promote the heat transfer as much as possible, the protrusions in the flow direction should disturb each other as little as possible, in the sense that each protrusion, such as a fin, cooperates with a virtually undisturbed flow. In this connection use can advantageously be made of an embodiment in which the protrusions have mutually offset relationships.

In the case of substantial heat conduction in the longitudinal direction, i.e. in the direction of the medium flows that flow in mutually opposite directions to achieve an optimum efficiency, the dew point cooler according to the invention can advantageously have the special feature that the protrusions have a limited length in the direction of flow promoting heat transfer.

The dew point cooler can also have the feature that the protrusions are separated in the flow direction by parts with a substantially lower heat conductivity.

In order to achieve the desired high efficiency, the dew point cooler according to the invention must be provided with a good wetting of the cover layer, which may consist of separate parts, in which in particular no dry surface parts may remain.

This is because a temperature difference could occur locally, which causes undesired heat flows that result in the performance of the cooler leaving something to be desired. Furthermore, the ratios between the surfaces of the heat-conducting surfaces and the break-up means in the primary and the secondary circuit must be chosen such that, given all boundary conditions, the heat flows between the primary and the secondary medium are as large as possible.

The invention offers the possibility of constructing a dew point cooler with greatly increased efficiency, wherein the temperature at the output of the primary circuit in the so-called h, x-diagram according to Mollier is at least on the line of 85% RH 30 (relative humidity) and where a greatly reduced temperature difference arises between the primary inlet and the secondary outlet, namely 2 to 3 ° C. It is noted that it is desirable that the saturation line (100% RH) is approached as closely as possible, with the aim in practice for a value of approximately 85%.

The invention will now be explained with reference to the accompanying figures. Herein show: 1 022 795 9

FIG. 1 is a block diagram of a dew point cooler with a primary circuit and a secondary circuit;

FIG. 2 one with FIG. 1 corresponds to a block diagram of a dew point cooler, the secondary circuit connecting to the output of the primary circuit;

FIG. 3 is a highly schematic example of a dew point cooler with a reversing unit for reversing a portion of the primary medium stream; and

FIG. 4 is a schematic and highly simplified perspective view of a dew point cooler.

FIG. 1 shows a dew point cooler 1 with a primary circuit 2 and a secondary circuit 3. The media flowing therethrough are in counter-flow as indicated by arrows 4, 5. The primary medium I flows in via an input 6 and is discharged via an outlet 7 Apart from the drawing of a pump, a fan, or a similar medium-transport means. The secondary medium II flows in via an inlet 8 and leaves the exchanger via a outlet 9. Two respective weaving and manifolds 10, 81 are shown, which unite a plurality of interwoven channels within the dew point cooler 1 into the respective single lines for the primary and secondary circuit respectively.

By means of humidifying means (not shown), the heat exchanging wall is moistened in the secondary circuit 3 for cooling of that wall by evaporation of the water on the wall by the flowing secondary air flow.

In the cooler 1, the media I, II are in heat-exchanging contact. In this embodiment, the cooler comprises an external primary input 11, an external primary input 12, an external secondary input 13 and an external secondary input 14.

FIG. 2 differs in particular with regard to this last aspect of the embodiment according to FIG. 1 in the sense that the secondary input 8 receives from the dew-point cooler 1 a medium stream I'1, which is a tap off of the total medium stream I. The through-going stream I 'is passed through manifold 81' to output 12. The sum of the flows I1 and I1 'is equal to I. The flow I1' is equal to the flow II. The ratio between I 'and I1' determines to a large extent the performance of the cooler and may, for example, have a value in the order of 70:30. The medium flow I can be considered as the gross flow, that is to say the total medium flow introduced into the device. The stream I1 is the thermally treated stream, in particular the cooled stream, which can be referred to as the net stream. The difference between the gross current I and the net current I '15 is the branch current I' 'or II, which corresponds to the current II according to FIG. 1. This current II flows through the secondary circuit and is in the configuration according to FIG.

2 as the tare flow. The thermally treated, in particular heated, medium at the outlet 14 is discharged to the outside as a loss.

FIG. 3 shows very diagrammatically a dew point cooler 20. This comprises a primary circuit I and a secondary circuit II. A primary air flow 21 flows through the primary circuit. A secondary air flow 22 flows through the secondary circuit II. This is a branch of the primary air flow 21 which itself continues as a partial flow 21 '.

The dew point cooler comprises a primary inlet 23, a primary outlet 24 and a secondary outlet 25, 30 which discharges form part of a housing 26. A fan 27 drives the primary air flow 21. A heat exchanging wall 28 is placed in the housing which separates the primary circuit I from the secondary circuit II. In the wall there is an opening 29 which can be closed and opened by means of a valve 30 which is controlled by an actuator 31.

In the open position shown, a selected portion of the primary stream 21 is tapped off in the form of the stream 22 while the remainder continues as the stream 21 '.

The wall 28 carries primary fins 32 and secondary fins 33. These serve to break up the boundary layers involved and for effective surface enlargement of the wall 28. The secondary fins 33 are provided with a Portland cement coating. As a result, the fins on the surface are effectively hydrophilic and can buffer a certain amount of water. This water is supplied via a water pipe 34 and a metering valve 35 to a metering pipe 36. This ensures continuous wetting of the said cover layer.

The secondary air stream 22 flowing past causes evaporation of the water present in the cover layer, which is accompanied by a cooling of the fins 33, the wall 28, and thereby the fins 32, whereby the primary stream 21 is cooled. Thus, the primary output current 21 'has a lower flow than the primary current 21 but also a lowered temperature. This stream 21 'is therefore used as the effective cooled air stream for, for example, space cooling. The secondary air stream 22 entrained by the water vapor can be discharged to the outside.

A variant which does not use the valve 30 is not shown. The ratio between the currents 21 and 22 is then not adjustable.

FIG. 4 shows a dew point cooler 50, the casing of which has been omitted for the sake of clarity. The dew-point cooler in this greatly simplified representation comprises three heat-conducting and media-separating walls 51, 52, 53, on either side of which fins 54, 55, 56, 57 are located, which in the form of zigzag-shaped strips are located transversely to extend the flows to be described below. The fins have a limited length in the flow directions, while said walls 51, 52, 1022795 12 53 are heat-conducting in the region of the fins and heat is indicated between the respective strips of fins, designated 57, 57 ', 571', respectively -insulating parts show 58, 58 'respectively. As a result, heat transport in the longitudinal direction is avoided, as a result of which the exchanger 50 has an excellent efficiency.

The middle two of the four channels shown correspond to the primary circuit I. The outer two channels, which are further limited by the housing (not shown), define the secondary circuit II.

The various currents and circuits are designated with the same references as in FIG. 2.

Furthermore, the dew point cooler 50 comprises a central water supply line 59 with nozzles 60 for wetting the fins 54 - 57 which are provided with a hydrophilic cover layer. The fins have perforations whereby the water coming from the nozzles 60 can also completely wet the lower fins. Any excess water is drained by means (not shown). As can be seen from the figure, the perforations 61 are designed as slots. These slots are not punched out, but formed by forming cuts in a punching machine and pressing the fin material out of the main surface of the surrounding surface, such that a louver-like structure is created. The shape of the perforations 61 now to be designated as louvres is such that they are grouped into two groups of louvres following one another in the direction of flow, designated 62 and 63 respectively. In this example, the group of louvres which is most upstream in the direction of flow is that with reference numeral 63. The louvers are positioned such that the current 5 is intercepted by the louvres to be diverted to the other side of the fin, where the deflected current is in turn intercepted by the louvres of the group 62 around to resume its original job again. This structure provides excellent heat transfer between the flowing medium and the fins.

1022795 13

The energization of the water supply line 59 with the nozzles 60 for dispensing water on the coated side, i.e. the fins 54-57 in the tare secondary medium stream II, preferably takes place intermittently. The watering system irrigates the cover layer, making the fins hydrophilic.

As far as possible, it is avoided to directly wet the secondary air stream, since this only has the effect of reducing the efficiency of the dew point cooler 50. The use of nozzles according to the invention is therefore definitely avoided. The evaporation only takes place from the coating of the water-wetted fins and the possibly also provided with a hydrophilic cover layer of the walls 51, 52, 53, that is to say the fin-free zones designated with 58 and 58 '.

According to the invention, it is achieved by a slight over-watering that the wet wall, including the fins, is substantially homogeneously irrigated and almost everywhere, however, contains water.

The floating pressure difference for evaporation is therefore optimal everywhere. A good choice of the flow speed and the turbulence rate ensure a high efficiency.

It is also the place here to pay attention to the efficiency of the enthalpy exchanger in general, in particular with reference to the FIG. 4. After passing through the primary heat-exchanging side, part I1 'of the gross primary air stream I is passed along the secondary side 30 of the enthalpy exchanger 50 to absorb water vapor in the manner described above. The heat of evaporation of the absorbed evaporated water is used to cool the gross primary air stream I 'to the temperature of the net primary air stream I', which is ultimately the desired air that is blown into the room to be cooled. The ratio between gross flow and tare flow has an optimum with each dimensioning of the dew point cooler.

102279j 14

The heat extracted from the primary gross air flow is multiplied by the thermal efficiency of the dew point cooler 50. For the secondary extraction of enthalpy, the latent evaporation heat 5 of the irrigation water is largely used. This makes it possible to suffice with a low air flow. In the typical case, the mass flow ratio between the primary stream and the secondary stream is in the order of 2 to 3.

With regard to the hydrophilic or hygroscopic coating or the surface treatments that the fins and the heat-bearing walls bearing the fins exhibit the required moisture-distributing and moisture-buffering properties, storage of the water to be evaporated takes place between two irrigation periods. The coating or cover layer is so thin that it gives a virtually negligible heat resistance, as a result of which the heat transfer between the primary medium flow and the secondary medium flow can take place virtually undisturbed.

In FIG. 4, the drawing of the necessary manifolds for joining the outer two channels and the inner two channels 25 on both sides of the exchanger 50, is also omitted. The drawing of the provisions necessary for forming the partial flows is also omitted I 'and I'1 from the stream I. For this purpose the device according to FIG. 3 or any other suitable device.

Because in the dew point cooler of the type according to FIG. 4 or in general of the type according to the invention a slight floating temperature difference occurs and because the saturated vapor pressure is directly dependent on the temperature, it is of great importance to ensure that this temperature difference is not caused by longitudinal conduction (in the direction of flow) the wall is destroyed. This is achieved by choosing relatively small wall thicknesses, or by providing non-heat-conducting or at least negligibly heat-conducting separations between the fins in the flow direction of the media. These are the heat-insulating parts which are designated 58, 58 '.

In order to achieve as much dust transport as possible on the wet side, i.e. the evaporation of water to water vapor carried by the secondary medium stream, the pressure difference between the vapor pressure saturated at the prevailing temperature and the vapor pressure of the supplied air should be as large as possible. to be.

Saturated air, or almost saturated air, makes this difference so small that it is at the expense of the performance of the enthalpy exchanger. On the irrigated secondary side, the dew point cooler preferably has a partially uncoated surface, which removes the water-absorbing air and therefore further away from the saturation point, so that water can still be absorbed to an optimum extent. This can be a continuous or a discontinuous process of vapor absorption and heating.

Apart from the described heat separations between the fin-lined zones, the heat conductivity of the partition between the primary stream and the secondary stream is not important. The heat conduction of the heat transfer promoting means, in particular the fins, which extend to some distance from the wall in the relevant channel and thus have to transport heat absorbed by conduction to the wall, is of great importance and must be well-chosen. to be. In a particular embodiment the invention uses in this connection the fins folded in a tipping shape or a zigzag shape consisting of copper strips with louvered perforations, as in FIG. 4 shown.

35 ***** 1022795

Claims (10)

1. Dew point cooler, comprising: a first medium circuit and a second medium circuit thermally coupled thereto via an at least partially heat-conducting wall, which two circuits can be flowed in countercurrent through two respective media, wherein at least the second medium contains a gas, for example air, with a relative humidity of less than 100%; which heat-conducting wall has break-out means 10 for breaking up at least the thermal boundary layer, the laminar boundary layer, and the relative humidity boundary layer in at least the heat transfer active zones in at least the primary medium, which breaking-up means 15 comprise heat-conducting protrusions which comprise the effective heat-conducting surface of enlarge said wall; wherein the heat-conducting surfaces of said wall and the break-up means are at least partially covered at least in the area of the secondary medium with a hydrophilic, e.g. can absorb water, retain it, and relinquish it by evaporation, such that the wetted cover layer and thereby also the heat-conducting surfaces and the break-up means are cooled; differential drive-based primary drive means, for example, a fan or pump, for the primary medium; differential pressure based secondary drive means, e.g. a fan, for the secondary medium; a wetting unit for wetting the secondary medium through wetting by evaporating liquid from the cover layer such that the evaporated liquid entrained by the secondary medium extracts heat from the primary medium via the heat-conducting wall; and wherein the cover layer consists of a porous technical ceramic material, for example a baked layer, a cement such as a Portland cement, or a fibrous material, for example a mineral wool such as rock wool; And wherein the heat transfer coefficient of the entire wall is at least 1 W / m2K. 2. Dew point cooler according to claim 1, wherein the secondary medium flow is a partial flow that is branched off at the end of the primary medium flow and has the value of, for example, approximately 30% thereof. Dew point cooler according to claim 1, wherein the cover layer consists of a plastic. 4. Dew point cooler according to claim 1, 2 or 3, wherein the effective outer surface of the cover layer from which the liquid can evaporate is at least 100x, preferably at least 100x, as large as its projected surface. 5. Dew point cooler according to claim 1, wherein the dew point cooler is dimensioned and the medium flows have values such that in the secondary flow the dew point is approached within 1 ° C. 6. Dew point cooler according to claim 1, wherein the break-up means comprise fins, which fins are designed as a number of strips, each with a general wave shape, of which strips successive wave crests are coupled on one side to the wall, and in that the cover layer substantially only on the surface of each strip remote from the wall. 1022795 δδ 7. Dew point cooler according to claim 4, wherein the properties of the cover layer and those of the liquid are mutually chosen such that (a) a predetermined amount of liquid is buffered in the cover layer per surface unit of the wall and the break-up means can become; and (b) the heat resistance of a liquid-filled covering layer transverse to its main surface is negligible with respect to the total heat resistance in the path between the heat-conducting wall and the secondary medium flowing past. The dew point cooler of claim 1, wherein the protrusions exhibit mutually offset relationships. 9. Dew point cooler according to claim 1, wherein the protrusions have a limited length in the direction of flow promoting the heat transfer. The dew point cooler according to claim 1, wherein the protrusions are separated in flow direction by parts with a substantially lower heat conductivity. 20 ***** 1022795