DE2650565A1 - DEVICE FOR EXCHANGING HEAT AND / OR SUBSTANCES BETWEEN A LIQUID AND A GAS OR STEAM - Google Patents

Description

PATENT ADVERTISER 2650565 DIPL-ING-GERDCOMMENTZ

7 STUTTGART 1

KLIPPENECKSTRASSE4 - TELEPHONE (0711) 465644

November 4, 1976 W 1019 P

György Gusztav BdIa HALMOS, Bloemendaal (Netherlands)

Device for exchanging heat and / or substances between a liquid and a gas or vapor

The invention relates to a device for exchanging heat and / or substances between a liquid and a gas or Steam, with several vertically aligned guide bodies for the liquid, arranged essentially parallel to one another, which is made to flow along this guide body by means of a device provided above. Such devices are known from DT-PS 140 727.

The invention has for its object to improve a device of this type so that the contact surface between the flowing liquid and the gas or vapor is stabilized. This is intended to be a more reliable way of working and a larger Freedom in the flow rate of both the liquid and the gas or vapor can be achieved and therefore also an improved efficiency for a given size of the surface available for the exchange of heat and / or substances this exchange.

Tests carried out in this direction have shown that

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COMMERZIiANK STUTTGART (BLZ fi004 (X) 7l) 7751027 POSTSCHECKAMT STUTTOAIiT 25780-700 TELEPHONE INFORMATION ARE NECESSARY

with an increase in the flow rate of the gas or Vapor from the liquid flowing along the guide body Droplets are released, which results in a corresponding deterioration in this efficiency. It should therefore be used for prevention such a detachment of droplets created flow conditions for the liquid along the guide body which prevent the occurrence of locally excessive speeds, for example flow eddies that viewed as a possible cause of such droplet formation can be. It is for a cheap exchange of heat and / or substances that are also important for this flow a certain irregularity is achieved, the proviso in particular still being sufficient that all areas of the guide bodies must be soaked by the liquid, as strongly deviating temperatures can occur at all areas that remain undetected, which, with the support of the flowing gas or steam, can lead to the spread of these points and thus to a corresponding promotion of such droplet formation.

To solve the aforementioned problem and at least to a large extent Mastering this problem is according to the invention for a device of this type is provided to provide the guide body with a coating of a porous material. Under a "Porous material" is intended to mean a smaller one with spaces in between Dimension provided material be understood that is arranged in any case on the surface of the guide body, so that the liquid flowing over it due to the opposite to the Guide bodies effective capillary force can at least partially fill the spaces. As suitable materials for this In particular, a fiber fleece or a foam plastic come in consideration of the latter, preferably with an open cell structure, because the relevant interstices from the surface also have a connection with corresponding interstices inside the material. The material chosen for this coating should preferably also be water-absorbent be.

As for the actual guide bodies, they should

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be made as thin as possible, since the thickness of the guide body does not increase the working capacity of such Device contributes. Consequently, thinner guide bodies of the same dimensions result in a larger flow cross-sectional area for the Gas or steam, although the boundary condition applies that the guide bodies must still be sufficiently stable so that they are not subject to any vibration that would otherwise promote said droplet formation. According to a preferred embodiment of the invention The guide bodies therefore have a wavy or zigzag-shaped horizontal cross section, which is quite considerable An increase in the mechanical strength of such guide bodies results, so that even with a sufficiently thin design, hardly any there is a risk of vibration in the guide bodies. A thin design of the guide body is also from the point of view preferred that in this way their mutual spacing is minimal can be chosen to be small without the cross-sectional area for the gas or steam flowing through being significantly reduced will. Under comparable conditions, one becomes essential for the same flow rates of the gas or steam More economical training is provided, which is particularly focused on the achievable stability of the system dimensioned and the prevention of said droplet formation. If the guide bodies are arranged close enough, then it becomes practical every vortex formation prevents, according to the knowledge available up to now, precisely such droplet formation promotes. Also get the flow channels between the guide bodies another changing shape, so that the width of the flow channels changes perpendicular to the direction of flow, then thereby a certain irregular flow is achieved, which the exchange of heat and / or substances in the gas or Steam promotes.

From DT-AS 1 299 665 there is a similar device for Exchange of heat and / or substances between a liquid and a gas or vapor is known in which the liquid flows along undulating panels. The panels are arranged so that their waves at an angle of 45 ° against

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the vertical are aligned and the waves of adjacent panels are perpendicular to each other. This is known in this case Arrangement built up a fairly large flow resistance and it is hardly possible to continue with all surface areas to wet the panels evenly, so that a rather non-uniform flow pattern occurs in which there is locally there is very strong droplet formation.

According to a preferred embodiment of the invention, the individual Conductor extremely thin sheet-like structure, which is made up of a comparatively thin coating on both surfaces are provided with a porous material. For example, aluminum foils with a thickness of 0.05 mm are used as flat structures Consider that coated on each surface with a coating of the porous material with a layer thickness of 0.2 mm are. It is then possible to use water with a layer thickness of up to at least along the surface of such a guide body to flow about 2 mm. Polyvinyl chloride proves to be the most suitable coating material, also from the point of view that this material can be glued very easily to all types of metal foils, which by the way makes them one can get fairly great rigidity that they are braced over their upper and lower edges. If the guide body a have a greater length, it may also appear expedient to support the guide bodies on the front and back against each other, and preferably by means of suitable bridge pieces that should be streamlined so that they are in the Flow direction present a sufficiently low flow resistance and therefore also to a reduced Contribute to droplet formation.

As far as the supply of the liquid is concerned, there are in principle numerous possibilities for this. So they can Guide body, for example, be attached to an upper and a lower sheet, of which the upper sheet is perforated so that all the liquid applied to it to flow over, for example, at a mutual distance of 1 cm arranged guide body is brought without

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it comes to the formation of droplets of the supplied liquid at the individual holes of such a sieve plate. The screen plate can also be designed so that its individual holes open directly on the individual guide bodies. Alternatively for this purpose it is also possible to use a flat structure with an open cell structure instead of such an upper sieve plate to arrange. In addition, such a device should also be equipped with means that the flow rate let the liquid control along the guide body, for example in that the level of the liquid is changed over such a sieve plate or closing body for the holes of which are provided, for example in the form of a further, overlying screen plate, the holes with those of the screen plate arranged for the upper attachment of the guide bodies can be brought to overlap so that only then does the desired flow of liquid occur along the guide body. Such constructions are known per se.

An exemplary embodiment of the invention is shown in the drawing shown schematically and is described in more detail below. It shows

1 shows a horizontal section through a device according to the invention along the line I-I according to FIG. 2,

Fig. 2 is a vertical section through this device along the line H-II in Fig. 1,

3 shows two details of this device on an enlarged scale in a respective top view,

Fig. 4 shows on a greatly enlarged scale a cross section through a guide body of the device according to the Fig. 1 to 3,

5 shows a further detail of this device,

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Fig. 6 shows a cross section along the line VI-VI in Fig. 5,

7 shows a further detail of this device, also on an enlarged scale, and FIG

8 shows, on a further enlarged scale, the detail corresponding to FIG. 7 in an alternative Embodiment of the device according to the invention.

The device for exchanging heat and / or substances between a liquid and a gas or vapor comprises a cuboid housing 1, on the left side of which an inlet 2 and on the right side of which an outlet 3 is provided for gas or steam through which the housing flows. Within of the housing 1, a larger plurality of wave-shaped guide body 4 is arranged, which at an upper point with a water-permeable sheet-like structure 5 are covered, which forms the bottom of a container 6 with upright walls 7. the individual guide bodies 4 are attached to the top of the sheet-like structure 5 and to the bottom of another perforated sheet-like structure 8, the downward against the bottom 10 of the housing 1 provided with upright walls 12 delimits a gap 9 on which an outlet 11 is connected for the liquid which is fed into the container 6 at the top and then along the individual Guide body 4 flows downwards. The container 6, the guide bodies 4 attached to the bottom thereof and the lower sheet-like structure 8 can be designed as an installation unit, so that assembly with the housing 1 is correspondingly simple.

The individual guide bodies 4 are wave-shaped and arranged so that their upper edge is close to slot-shaped openings 13 runs, with which, for example, the upper sheet-like structure 5 for the permeability for liquid desired for this is provided. Instead of such slot-shaped openings, a regular hole pattern 14 can also be provided, see above so that the upper sheet 5 can be defined as a sieve plate, in which the discharged into the container 6 liquid

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passes through the individual holes without it at a sufficiently close distance between the individual guide body 4 to a
The formation of droplets on the underside of the sieve plate occurs
Liquid then rather directly from this underside to the
Flow is brought along the individual guide body. Instead of these two embodiments, shown on a greatly enlarged scale in FIGS. 3A and 3B, for the planar structure 5
Another material that is correspondingly permeable to liquid can also be used, in particular a foam plastic with an open cell structure. As far as the other cell structure 8 is concerned, no comparable regular perforation has to be provided for it
rather, it is sufficient for this flat structure that
it has a somehow suitable passage possibility for the liquid for subsequent collection in the intermediate space 9, before the liquid then emerges from the housing 1 via the outlet 11.

The individual guide bodies 4 are on the flat structures 5 and 8
glued on or just pinned on, provided that the flat structures are made of a sufficiently soft material that allows such a plug-in option. Each guide body preferably consists of a centrally arranged sheet 15, in particular a rolled aluminum foil, which is coated on both surfaces with a conventional protective layer, such as a suitable protective paint or a suitable protective lacquer. These protective layers
are each covered with a glued-on nonwoven fabric 16, preferably based on polyvinyl chloride with a thickness of
for example 0.2 mm, the polyvinyl chloride under
from the point of view particularly suitable that with it without special
Difficulties a fluid flow along such guide bodies with a layer thickness of up to 2 mm can be achieved.
The polyvinyl chloride is also suitable for bonding to such metal foils with commercially available adhesives.

In FIGS. 5 and 6 it is shown how the individual guide bodies 4 are spaced apart from one another by means of streamlined bridge pieces 18 are held. Each guide body 4 is provided for this purpose

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provided with an edge-side bend 17 with which it can be inserted into a relevant plug-in slot 19 of the respective bridge piece 18 is inserted and clamped in it. For guide bodies of the dimensions mentioned above, such bridge pieces 18 should approximately all 15 cm are arranged so that at a flow velocity of the steam or gas of about 7-8 m / sec and a mutual Distance of the guide bodies of 1 cm any risk of vibration of the guide bodies is prevented. By the bridge pieces are streamlined, they have a correspondingly low flow resistance, which is practically at all does not interfere and also does not lead to the formation of droplets, which is particularly to be avoided. The bridge pieces 18 increase on the other hand the stability of the arrangement is quite considerable, especially if this also means that the guide bodies are attached to the upright walls 12 of the housing 1 is made.

As for the attachment of the individual guide bodies to the upper sheet 5 is concerned, the embodiment shown in FIG. 7 can alternatively be implemented for this purpose. After that is the Metal foil of a first guide body extended upwards so far that it is used to bridge the gap to the next Guide body can be angled at right angles and thus creates a partial area 20 for the bottom of the container 6, which is glued to the similarly designed metal foil of this next guide body by means of a repeated bend 21. Or, as shown in FIG. 8, the upper ends of the individual Guide body 4 be glued between individual strips 22, which have the same wave shape as the individual in plan view Guide body, so that also with it the undulating spaces shown in FIG. In both cases it is possible to account for the permeability of liquid to design relevant openings both slot-shaped and round, within the aforementioned dimensions, a slot width of 2 mm or a hole diameter of 3 mm for these two alternatives have proven particularly useful.

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The wave shape of the individual guide bodies 4 is not special To make demands. This is primarily intended to ensure that the guide bodies thereby have an increased rigidity obtained so that they are sufficiently self-supporting even with the stated values of a still fairly small thickness and so only need to be attached to their upper and lower edges and, if necessary, to the lateral upright edges. So For example, within the aforementioned dimensions, a fairly high strength is achieved when at a wave period a length of 15 cm a wave height of 5 cm is maintained, i.e. a distance between wave crest and wave trough of 10 centimeters. It is therefore possible, under otherwise comparable conditions, in a housing 1 of such a device to process larger amounts of liquid and steam or gas for the intended exchange of heat and / or substances, not least because of this extreme thinness of these guide bodies, which with the wave shape even at higher flow velocities of the gas or vapor flowing through result in a regular flow pattern of the liquid without the There is a risk of droplets forming. Because the individual flow channels have a variable flow cross-section between the guide bodies perpendicular to the local flow direction, this creates an extremely favorable prerequisite for the intended exchange of heat and / or other substances, also to the extent of the detail that local flow eddies and thus also any formation of droplets are prevented.

Devices of the type according to the invention can with these requirements find a very wide area of application, for example as cooling towers, condensers, air humidifiers, heat collectors of partially expanded vapor, etc. Because there is only a small thermal resistance between the gas or the vapor of the liquid, is also a use of the device for a heat transfer from a liquid or an optionally wetted one Gas first possible through a heat exchanger, in which a heat exchange between a liquid and a liquid

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takes place, and thereafter via a device according to the present invention Invention, which in many cases can be cheaper and also more effective than a direct heat exchange between a liquid and a gas, possibly also using a humidifier.

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Claims (19)

Expectations \ 1.) Device for exchanging heat and / or substances between a liquid and a gas or vapor, with several essentially parallel and vertically aligned guide bodies for the liquid, which is made to flow along the guide body by means of a device provided above , characterized in that the guide bodies are provided with a coating made of a porous material. 2. Apparatus according to claim 1, characterized in that the coating consists of a fiber fleece. 3. Apparatus according to claim 1, characterized in that the coating consists of a foam plastic. 4. Apparatus according to claim 3, characterized in that the foam plastic has an open cell structure. 5. Device according to one or more of claims 1 to 4, characterized in that the guide bodies have a wavy or zigzag-shaped horizontal cross section. 6. Device according to one or more of claims 1-5, characterized in that the guide bodies consist of a thin sheet which is provided on its two surfaces with a thin coating of a porous material. 7. Apparatus according to claim 6, characterized in that the sheet consists of metal. 8. Apparatus according to claim 7, characterized in that the thickness of the sheet is less than 0.5 mm. 709819/0332 ORIG 9. Device according to one or more of claims 1-8, characterized in that the guide bodies comprise a metallic sheet-like structure with a thickness of less than 0.1 mm. 10. The device according to one or more of claims 1 - S, characterized in that the guide bodies are supported only at their edges. 11. The device according to claim 10, characterized in that the guide bodies are attached to their upper and lower edges and that their vertical upright edges are connected to one another via bridge pieces. 12. The device according to one or more of claims 1-11, characterized in that the guide bodies are connected at their upper edge to a flat structure provided with openings. 13. The device according to claim 12, characterized in that the sheet-like structure is formed from metal strips which are delimited on at least one edge by a guide body. 14. The device according to one or more of claims 1-13, characterized in that the mutual spacing of the guide bodies measured in the main direction of the guide bodies is between 5 and 20 mm. 15. The device according to one or more of claims 1-14, characterized in that the total height of the wave-shaped or zigzag-shaped guide body measured between the wave crest and the wave trough is smaller than the length or period of the wave in question. 16. The device according to one or more of claims 1-15, characterized in that the porous material is based on polyvinyl chloride. 709819/0332 17. The device according to claim 11, characterized in that the bridge pieces have a streamlined cross-section. 18. The device according to claim 11, characterized in that the bridge pieces are provided with slots, in each of which a bent upright edge of the guide body is clamped. 19. The device according to one or more of claims 1-18, characterized in that the sheet of the guide body is bent at right angles in the section of an upper extension and provided with openings for the liquid and that each bent extension of a guide body is connected to the guide body arranged immediately next to it is. 709819/0332