DE4127245A1 - Heat exchanger for cooling tower - has elements with zigzag grooves for flow of water in opposite direction to flow of gas - Google Patents

Abstract

The cooling tower, or a water treatment plant, has a heat exchanger constructed from elements in which corrugations or folds are formed. These corrugations form channels for the flow of water which flows in the opposite direction to that of the gas. Each element (1) is constructed from a number of sections (2b,2c,2d) in which the channels are arranged obliquely to the direction of flow of the gas with the obliquity of the grooves changing from section to section. In addition the length of the grooves of each section is reduced successively from section to section (2b,2c,2d) in the direction of the flow of the water. USE/ADVANTAGE - Heat exchanger for cooling tower or water treatment plant. The heat exchangers are simple to construct.

Description

The invention relates to a trickle installation element for a directions for mass and / or heat exchange between gases and Liquids, especially for cooling towers and water treatment horse riding equipment consisting of a plurality of profiled Surface elements with corrugations and / or folds Formation of countercurrent from each gas and each channels are provided with liquid, which ver at a predetermined angle to the main flow direction run, the sloping channel course over the height of the entire trickle installation shows several changes of direction.

Such trickle installation elements are particularly for cooling towers known. The profiled surface elements are made of foils, Sheets or mats made. The identically trained Surface elements are arranged side by side in such a way that the oblique to the main flow direction of the liquid and the Gases trending, generated by corrugations and / or folds Cross channels of adjacent surface elements. Hereby result in contact between adjacent surface elements points at which the surface elements form one with the other Trickle installation element are connected. Of such ripples Construction elements are usually placed on top of each other arranges, which match in the known trickle installations other elements are arranged so that over the height of the entire trickle installation several changes of direction with regard to the course of the individual channels.

The invention has for its object a trickle built-in element of the type described above with regard of the mass and / or heat exchange as well as regarding the improve hydraulic and aerodynamic conditions, while maintaining the inexpensive manufacturability and simple installation of such trickle installation elements.

The solution to this problem by the invention is characterized in that the channels of each surface element through appropriate profiling at least two directions have changes and that the length of the thus formed Channel sections in the flow direction of the liquid from Ab cut to section is reduced.

By the in each individual trickle installation element according to the Er finding effective multiple changes of direction of the opposite flow of liquid and gas result additional run-up routes that increase turbulence and thus the heat and / or mass transfer between liquid and gas improve; it has been found that the reduction the run lengths of each in the direction of liquid flow following channel sections surprisingly no reduction in Exchange performance results. For this reason, with the trickle installation element according to the invention either a Ver decrease in installation height or an increase in the total Exchange service possible with constant installation height.

According to another feature of the invention is the reduction the channel section lengths from section to section are approximately the same large. It is preferably about 50%, so that one the length of the channel with two changes of direction the channel sections in the direction of flow of the liquid like 3: 2: 1 behavior. Of course it is also possible that Length reduction varies from section to section  train, for example, that the reduction in second channel section 20% and in the third channel section 30%, is based in each case on the preceding channel section.

The impact losses when the gas enters the individual The surface elements can reduce pouring elements according to a further feature of the invention in the field of gas entry with a ver parallel to the gas flow direction running channel section. If the surface elements according to the invention also in the area of the liquid inlet one running parallel to the direction of liquid flow Channel section are formed, the erosion of the trickle built-in elements by hitting their top Liquid drops avoided or significantly reduced.

The inventive design of the surface elements with parallel to the direction of flow of the gas and / or the liquid directed channel sections has the additional advantage that there is a line in this area of the trickle installation elements contact between adjacent surface elements results in a very durable connection, preferably by welding the adjacent elements allowed. Such trickle installation elements accordingly have a in the area of the upper and lower surface high strength and rigidity. This does not allow only the measures for holding and storing the fiction, ge reduce moderate pouring elements; the inventive After installation, elements are without additional measures walkable.

In an expedient development of the invention Trickle installation element is the entire area of the surface elements in a manner known per se approximately across the direction of the Ver channel course with a wave-like fine profile see. This results in a reduction in the outflow  dizziness and thus a longer dwell time Liquid on the surface of the surface elements; Furthermore becomes an equalization of the liquid flow over the Channel flanks achieved.

In a preferred embodiment of the invention this fine profiling to the direction of the channel course below an angle that is about the angle of inclination of the channels to the main Direction of flow of gas and liquid corresponds. The resulting, approximately horizontal course of the fine profiling in the installed state causes the liquid to the flank of the channels within the respective flow channel is held and the channel despite the sloping channel flank does not leave.

Finally, the invention proposes each adjacent surface elements with sloping channels in to arrange in a known manner such that their channels cross. The associated improved liquid ver division transverse to the main flow direction has in a known manner an increase in efficiency.

In the drawing are two embodiments of the Invention according to the trickle installation element, which shows:

Fig. 1 is a side view of a Rieseleinbau element with a first embodiment of the profiled surface elements,

Fig. 2 is a plan view of two flat elements according to FIG. 1,

Fig. 3 is a partial view of a second embodiment of a profiled surface element and

Fig. 4 is a plan view of the surface element according to FIG. 3.

The drawn in Fig. 1 side view of a Rieselein construction element also represents the view of a profiled surface element 1 , which was made for example from a plastic film. A plurality of such surface elements 1 together form a trickle installation element. A large number of such trickle installation elements in turn form the trickle installation, for example in a cooling tower or a water treatment system, with several trickle installation elements not only being arranged next to one another but also one above the other. In a cooling tower with an hourly throughput of 20,000 to 30,000 m ³ of recooling water, for example, 2,000 to 3,000 m ^{3 of} such trickle installation elements are arranged.

The liquid to be cooled, so in the case of a cooling tower, the recooling water, is given from above to the trickle installation elements by means of a distribution device, not shown in the drawing. This liquid passes from above into the channels formed by the profiling of the surface elements 1 , which flows from below with gas, ie in the case of a cooling tower with cooling air in counterflow to the liquid.

In the first embodiment according to FIGS. 1 and 2, each surface element 1 is profiled in such a way that cross-sectionally V-shaped channels 2 result, the channel cross-section of which can best be seen in FIG. 2. The course of the channels 2 on the level of the surface element 1 is again best to take the Fig. 1 to ent.

This illustration shows that each channel 2 in the flow direction of the liquid to be cooled, entering from above, a section running parallel to the liquid flow direction Kanalab section 2 a, to which channel sections 2 b, 2 c and 2 d follow, which are at an acute angle to Main flow direction of liquid and gas and have at least two changes of direction. In the game Ausführungsbei run the channel sections 2 b, 2 c and 2 d each at an angle of 20 ° to the main flow direction. Since the surface element 1 is formed with three such channel sections 2 b, 2 c and 2 d, it contains two such changes of direction. Each of these channels 2 finally ends on the underside of the surface element 1 in turn in a channel section 2 e, which is aligned parallel to the main flow direction and thus parallel to a flowing gas. The length of the channel sections 2 b, 2 c and 2 d is reduced in the flow direction of the liquid from channel section 2 b to 2 c and from channel section 2 c to 2 d.

The liquid to be cooled, which is given from above the Rieselein construction elements formed from a plurality of surface elements 1 , is subject to a certain orientation in the channel sections 2 a aligned parallel to the main flow direction, which leads to an equalization, in particular in the case of laterally oriented spray nozzle systems. In addition, erosion of the surface elements 1 by the liquid impinging on the surface elements 1 is substantially reduced as a result of the alignment of the channel sections 2 a running parallel to the liquid flow direction.

The liquid then passes from the channel sections 2 a into the inclined channel section 2 b. Because of the oblique channel profile, the liquid only hits one flank of the V-shaped channels 2 , namely the flank facing the liquid flow. However, wetting of the respective other flank of the channels 2 takes place within each channel 2 in the region of b to the channel section 2 at closing the channel section 2 c is the average over the Kanalab 2 b by the same acute angle, however, is inclined toward the other side. Due to the change in direction of the channel course lying between the channel sections 2 b and 2 c, reliable wetting of those flanks of the V-shaped channels 2 that have not been subjected to liquid in the channel section 2 b also takes place. In the channel section 2 d, which is in turn inclined to the other side, the liquid flow on both flanks of the channels 2 is further evened out.

Since the demands on the liquid distribution within the channels 2 decrease in the flow direction of the liquid and the formation of a liquid film on the flanks of the channels 2 is to be designed in the sense of an effective interface renewal, the length of the channel sections 2 b, 2 c and 2 d from. In the game Ausführungsbei the lengths of the channel sections 2 c and 2 d in relation to the previous channel section 2 b and 2 c are each reduced to half. Of course, it is possible to choose a percentage of the reduction that differs from this and, if necessary, also a percentage that varies from section to section.

In practice, it has been found that the effective in each surface element 1 multiple changes of direction of the oblique channel sections 2 b, 2 c and 2 d create additional run-up sections for the liquid film, which due to the turbulence that occurs the heat and / or matter Improve exchange between liquid and gas in such a way that, in conjunction with the reduction in the length of the passage sections in the flow direction of the liquid, successive channel sections 2 b, 2 c and 2 d result in such an improvement in efficiency that either the total height of the trickle installations with the same exchange performance is significantly reduced or at the same installation height, the exchange performance can be increased significantly.

The alignment of the channel sections 2 e formed on the underside of the surface elements 1 parallel to the main flow direction, which can be seen in FIG. 1, reduces the impact losses when the gas enters the trickle installation elements formed by a plurality of surface elements 1 . Together with the targeted gas deflection into the trickle installation elements, this results in the lowest possible impact and deflection losses.

The course of the channel sections 2 a and 2 e parallel to the main direction of flow of liquid and gas but also has manufacturing advantages. It will become apparent namely in the region of the channel portions 2 a and 2 e even line contacts between adjacent surface elements 1, if these areas elements are arranged next to each other that their running obliquely to the main direction of flow channel sections 2 b, 2 c and 2 d are each cross, as this is indicated by dashed lines in Fig. 1. Such a course of the channel sections 2 b, 2 c and 2 d, which crosses from surface element 1 to surface element 1 , ensures good liquid distribution and uniform wetting of the entire surface of the surface elements forming the trickle installation elements 1 . Since the surface elements 1 touch each other only at points in the intersecting channel sections 2 b, 2 c and 2 d, that is to say they can only be "stitched" together, the line contacts between adjacent surface elements 1 in the area of the channel sections 2 a and 2 e a reliable connection of all surface elements 1 of a trickle installation element is ensured. The surface elements 1 can thus cuts in the area of Kanalab 2 a and 2 c durable glued or welded. In practice, the connection has been found to be so secure that, with increased strength and rigidity of the trickle installation elements, there is no need for greater effort in mounting and storing the elements, and even accessibility of the trickle installation elements can be achieved without additional measures.

In the second exemplary embodiment, which shows a side view and a plan view of a surface element 1 in sections from FIGS . 3 and 4, the channels 2 are not designed with a V-shaped but with a trapezoidal cross-section. This results in larger-area connections between adjacent surface elements 1 within a trickle installation element. Furthermore, FIG. 3 that the edges of the channels 2 are provided in known manner with a wave-like fine profiling 3, which is about transversely aligned with the direction of the channel path. In the embodiment according to FIG. 3, the fine profiling 3 extends to the direction of the channel profile at an angle which corresponds to the angle of inclination of the channels 2 to the main direction of flow of gas and liquid. This fine profiling 3 holds the liquid film on the surface of the flanks of the channels 2 . At the same time, the outflow speed is reduced and a longer residence time of the liquid within the trickle installation elements is achieved. Finally, the fine profiling 3 prevents the liquid film from converging in the channel base or exiting from the channel 2 despite the oblique channel profile over the edge of the flanks, so that an improvement in efficiency is achieved by the fine profile 3 .

Reference list

1 surface element
2 channel
2 a channel section
2 b channel section
2 c channel section
2 d channel section
3 fine profiling

Claims (8)

1. trickle installation element for devices for mass and / or heat exchange between gases and liquids, in particular for cooling towers and water treatment systems, consisting of a plurality of profiled surface elements with corrugations and / or folds to form in countercurrent of the respective gas and the respective liquid are provided by flowing channels, which run at a given angle to the main flow direction, the inclined channel course over the height of the entire trickle installation has several changes of direction, characterized in that the channels ( 2 ) of each surface element ( 1 ) by ent speaking profile at least two changes of direction and that the length of the thus formed Kanalab sections ( 2 b, 2 c, 2 d) is reduced from section to section in the direction of flow of the liquid. 2. trickle installation element according to claim 1, characterized in that the reduction in channel section lengths from section to section is about the same size. 3. trickle installation element according to claim 1 and 2, characterized records that the reduction in channel section lengths of Section to section is about 50%. 4. trickle installation element according to at least one of claims 1 to 3, characterized in that the surface elements ( 1 ) in the region of the gas inlet with a parallel to the gas flow direction channel section ( 2 e) are provided. 5. trickle installation element according to at least one of claims 1 to 4, characterized in that the surface elements ( 1 ) in the region of the liquid inlet with a parallel to the liquid flow direction channel portion ( 2 a) are provided. 6. trickle installation element according to at least one of claims 1 to 5, characterized in that the surface elements ( 1 ) are provided approximately transversely to the direction of the channel profile with a wave-like fine profile ( 3 ). 7. trickle installation element according to claim 6, characterized in that the fine profiling ( 3 ) to the direction of the channel course extends at an angle which corresponds approximately to the angle of inclination of the channel sections ( 2 b, 2 c, 2 d) to the main flow direction of gas and liquid . 8. trickle installation element according to at least one of claims 1 to 7, characterized in that the respectively adjacent surface elements ( 1 ) with inclined channel sections ( 2 b, 2 c, 2 d) are arranged such that the sections in the channel ( 2 b, 2 c, 2 d) cross formed channels ( 2 ).