DE202011109035U1 - Apparatus for recovering the water emerging from cooling towers in the form of steam - Google Patents

Abstract

Device for recovering the cooling fluid emerging from a cooling tower in the form of vapor, characterized by a roof (2), which tensions over the upper, open end of the cooling tower (1), for trapping the steam emerging from the cooling tower (1).

Description

The present invention relates generally to cooling devices comprising a cooling tower, from the upper, open end of the steam emerges. In particular, the invention relates to a device for recovering the cooling fluid emerging from the cooling tower in the form of vapor.

To dissipate large amounts of heat that occur in industrial processes or may arise in the cooling of larger buildings such as skyscrapers, cooling towers are used regularly, which may be formed in principle as a hollow tower with open ends, the upright and at the bottom sufficiently far away from the Floor surface, the so-called cooling tower cup, can be placed on supports. Ambient air can enter the cooling tower via the lower open end in order to flow upwards through the cooling tower interior in the cooling tower by means of a natural chimney effect and / or a fan-assisted air-flow generator such as a fan, where it exits again at the upper open end. The cooling air flowing in continuously at the lower end and pulling upwards through the cooling tower is used to evaporate a cooling fluid, normally water, and to achieve the desired heat removal by means of the evaporative cooling. In the case of wet cooling towers with a single-circuit cooling system, the process liquid to be cooled can be sprayed inside the cooling tower and sprinkled over filler bodies in order to extract evaporation heat from the process liquid and to extract heat from the process fluid through the finely distributed contact with the air by convection and to the cooling air leave. The sprayed or trickling process water is collected at the bottom of the wet cooling tower, the cooling tower cup, and fed back into the process.

However, it can also be used two-circuit cooling systems in which not the process liquid to be cooled is sprayed in the cooling tower, but a cooling liquid from a secondary circuit, which is continuously withdrawn by said evaporation process and convection heat, while on the other hand, this secondary circuit from the process liquid of the primary circuit heat is continuously supplied. In this case, for example, in a dry cooling tower with indirect dry cooling of the primary circuit can be performed with the process liquid to be cooled in the interior of the cooling tower through a condenser, which is cooled by the circulating in the secondary circuit through the cooling tower cooling liquid. As a coolant for the secondary circuit in this case water can be used, which can escape safely by evaporation at the upper end of the cooling tower into the atmosphere, without causing pollution concerns here, while the process liquid to be cooled regardless of their consistency in the primary circuit can be maintained, so that For the process fluid also fluids or liquids can be used, which could not be safely evaporated.

Nevertheless, there is a need to recover the cooling liquid leaving the upper cooling tower end in the form of vapor. On the one hand, this is of great economic and environmental importance in regions with water scarcity. Since there is a great need for cooling performance, especially in hot and thus often water-poor regions, it would be very helpful to eliminate or at least reduce the cooling liquid losses that usually occur. In conventional cooling towers evaporate about 1.5 to 3.5% of the circulating cooling water, which must be continuously replenished. On the other hand, the recovery of the exiting in the form of vapor cooling liquid is also desirable to prevent excessive concentration of the salts usually dissolved in the cooling water. While the vaporizing water is often very pure and of high quality, the salts dissolved in the cooling water remain in the trickling down portion of the sprayed cooling water, resulting in excessive cooling concentrations in the cooling tower cup which usually require draining and further replacement of the cooling water. In practice, this leads to a significantly greater requirement for cooling fluid beyond the stated 1.5 to 3.5% loss of steam.

Various measures have already been proposed for reducing the steam losses or for recovering the evaporating cooling water, which, however, are generally difficult to retrofit into existing systems and are often very complicated and expensive. For example, the font fails DD 216 527 a method for reducing the formation of steam on wet cooling towers, in which a recirculation zone is created in the interior of the cooling tower, in which the swaths are cooled so far that the dew point occurs. The font DE 103 33 009 describes a cooling tower in the interior of which on the one hand to roof-shaped capacitors configured tube bundles and on the other hand arranged below cooling devices are used to trickle down the recooled cooling water in a pool, from where it can be fed to a surface condenser. Furthermore, the writing describes DE 80 28 136 a wet-cooling tower drip catcher installed between the water distribution and the fan in the cooling tower, the drip catch consisting of a lamella package extending over the entire cross-section of the cooling tower.

The present invention has for its object to provide an improved device for recovering the emerging from cooling towers in the form of vapor liquid, which avoids the disadvantages of the prior art and further develops the latter in an advantageous manner. In particular, a simple retrofittable to existing cooling towers solution should be created that can be used for both single-circuit and dual-circuit systems and avoids over-concentration of dissolved in the coolant ingredients.

According to the invention, the object is achieved by a recovery device according to claim 1 and a cooling device with such a recovery device according to claim 11. Preferred embodiments of the invention are the subject of the dependent claims.

It is proposed to let the liquid exiting in vapor form from the upper end of the cooling tower exit from the cooling tower but to trap it above the cooling tower, to condense it and recover it as condensation. According to the invention, a roof that is exciting over the upper, open end of the cooling tower is provided for trapping the steam emerging from the cooling tower. By such a roof over the upper cooling tower end cooling tower internals such as capacitors or Verrieselungsbausteine inside the cooling tower remain unchanged or need the cooling air flow inside the cooling tower and the necessary construction measures inside the cooling tower are not changed.

In a further development of the invention, the roof can advantageously be dome-shaped or hat-shaped or stretch mushroom-shaped over the cooling tower, so that the upper cooling tower end facing the inside of the roof viewed concavely bulges and captures safely emerging steam from the upper end of the cooling tower. The roof curvature can in principle be chosen differently, wherein advantageously the roof curvature is such that the roof of an upper roof section, which may be advantageously arranged approximately centrally, drops to all sides of the roof edge. The curvature can be formed in an advantageous development of the invention dome-shaped round and / or continuously curved. Alternatively, however, an angular, for example in the manner of a pointed gable faceted beveled curvature can be provided.

Depending on the desired trapping amount, the roof viewed in a plan view may be formed differently large, possibly even cover only a part of the cooling tower outlet cross-section, but considered in an advantageous embodiment of the invention, the roof in plan view is at least as large and contoured that the roof the cooling tower outlet cross section completely covered. In particular, the roof with its lower edge portion may overlap the upper cooling tower end and be formed larger than the outlet cross-section, to avoid lateral loss of steam, the lower edge of the roof may also be pulled a little way over the upper edge of the cooling tower away, so that the lower End of the roof is a bit lower than the upper edge of the cooling tower. The roof advantageously forms a closed, continuous surface which covers the opening cross section above the cooling tower.

In a further development of the invention, a preferably circumferential air outlet gap is provided between the edge of the roof and the upper edge of the cooling tower, nevertheless the cooling air, d. H. despite the trapping of steam under the dome-shaped roof to escape laterally, so that the cooling tower continues to suck fresh air at its lower end fresh air and can deliver at its upper end and in a proven manner, the process liquid to be cooled directly or indirectly by evaporative cooling and also Convection can be cooled by the pulling through the cooling tower cooling air.

Depending on the design of the roof, it may be helpful in this case to provide a fan-assisted air-flow generator in order to maintain the airflow passing through the cooling tower in the manner of a chimney and / or in particular to strengthen it at the upper cooling-tower end. In an advantageous embodiment of the invention, said air flow generator may have a fan device in the region of the upper end portion of the cooling tower, for example in the form of one or more fan motors. The air flow generator is advantageously designed such that the air flow is directed at the upper end of the cooling tower in the dome-shaped spanned roof interior.

In order to achieve a rapid condensation of the liquid contained in the trapped vapor on the inside of the roof, especially under unfavorable, especially hot and sunny ambient conditions, the roof can be assigned a roof cooling device in the invention to cool down the roof inside to a Dampfkondensiertemperatur or the roof inner side temperature not to be allowed to rise above a Dampfkondensiertemperatur enabling the steam condensation.

Such a roof cooling device can in principle be designed differently. According to an advantageous embodiment of the invention the roof cooling device may in this case comprise a cooling liquid circuit which can be connected to the cooling liquid used in the cooling tower such that cooling liquid can be withdrawn from the cooling tower, in particular a coolant tank arranged at the bottom of the cooling tower and passed through or over the roof. In principle, liquid cooling of the roof would also be possible by means of cooling liquid independent of the cooling tower cycle, for example by feeding separate fresh or service water, which is at least a few degrees Kelvin colder than the steam rising from the cooling tower. However, by tapping or using the cooling liquid from the cooling tower cup roof cooling can be achieved without major additional construction measures.

Alternatively, or in addition to liquid cooling of the roof, however, the roof cooling device can also provide for air or gas cooling of the roof, wherein in an advantageous development of the invention the roof can have at least one air chamber through which cooling air or cooling gas can circulate. Such air cooling or gas cooling of the roof is particularly suitable if the roof or at least one layer of the roof consists of a foil or membrane construction which can have at least one, preferably a multiplicity of foil or membrane chambers can be inflated by the cooling air or the cooling gas. The cooling air circuit can continuously suck in fresh ambient air and blow into the at least one air chamber of the roof to achieve a continuous roof cooling.

In order to collect the condensate forming on the inside of the roof, in an advantageous embodiment of the invention, the roof is assigned a condensate collector which collects the condensation water running off and / or dripping off the inside of the roof. In particular, in the roof edges sloping roof shape, such a condensate collector may include a collector gutter, which is associated with the edge of the roof and collects from there dripping condensation water.

Depending on the further use of the recovered liquid, the cooling liquid collected in the condensate collector can be stored separately or discharged from the cooling tower, for example, to be fed into a pipe system. Alternatively, at least a part of the collected condensation water or the collected cooling liquid in the cooling liquid circuit, which is associated with the cooling tower, be fed back. In particular, the aforementioned collecting channel may be associated with a channel drain which is connected to the cooling fluid basin of the cooling tower.

In order to avoid unwanted heating of the roof by sunlight, which would complicate the recondensation of emerging from the cooling tower steam clouds, especially in hot and sunny countries, the roof over the cooling tower exciting roof in an advantageous embodiment of the invention on the outside with a reflective layer in particular in the form of a Be provided mirroring.

The ascending vapor trapping roof assembly may be formed in a further development of the invention, two stages or multi-stage, in particular to the effect that in the arched over the cooling tower opening cross-section outlet or openings are provided to excessive pressures under the roof or on the roof to avoid, over the said roof, a second roof preferably also dome-shaped or mushroom-shaped bulge, at least in the area above said passage openings to capture the steam passing there again. This further roof can be cooled in a similar manner as the first roof by a correspondingly designed cooling device and / or coated on the upper side reflective or mirrored and / or be advantageously provided with a condensation water return to also recycle the condensate collected in the second roof.

The invention will be explained in more detail below with reference to an advantageous embodiment of the invention and an accompanying drawing. In the drawing shows:

1 : A schematic, partially sectional view of a cooling tower and associated with the cooling tower device for recovering the emerging in the form of vapor from the cooling tower liquid according to an advantageous embodiment of the invention.

As 1 shows, the cooling tower 1 an upright, approximately tubular, hollow tower body 16 include, which is designed to be open at both ends and with its lower end, for example, on stilts over a designed as a cooling tower cup cooling water tank 9 can be placed. Alternatively or additionally, the cooling tower 1 at its lower end also Lufteintrittsausnehmungen 17 include, so in the lower end of the cooling tower 1 continuously from the environment cooling air can flow, which then through the interior of the cooling tower 1 rises like a chimney and at the top of the cooling tower 1 exits again. To support the chimney effect, the tower body can 16 have a nozzle-shaped changing and / or hyperboloidal cross-section, which initially tapers from bottom to top and then becomes larger again, cf. 1 ,

The process fluid to be cooled can be supplied via a supply line 18 into the interior of the cooling tower 1 be led and sprayed depending on the design of the cooling device, for example, in a wet cooling tower with single-circuit cooling system inside the cooling tower and trickled down a Verrieselungseinrichtung down in the cooling tower cup, or in a two-circuit cooling system such. B. a cell cooler, like this 1 shows, through a heat exchanger and / or a condenser inside the cooling tower 1 guided and over the mentioned supply line 18 or a parallel derivative 19 back from the cooling tower 1 be led out. The heat exchanger and / or capacitor modules are in 1 with the reference number 20 characterized. In a dual-circuit system, the cooling liquid stored in the cooling tower cup can be sprayed separately from the process liquid to be cooled via a suitable device in the cooling tower interior, preferably in its upper half and trickled down through a Verriesler back into the cooling tower cup, so that it by the chimney-like overhead pulling air flow to evaporation and convective cooling comes, which cools the heat exchanger and / or condenser of the process fluid circuit. As 1 shows, can via an inflow line 26 Cooling liquid can be supplied into the cooling liquid circuit, in particular in the region of the cooling tower cup. Via a drainage line 21 Coolant can be drained from the cooling tower cup, z. B. if the salt content is too high.

The from the top of the cooling tower 1 escaping steam is by means of a roof 2 captured, which dome-shaped bulges and completely over the outlet cross-section of the cooling tower 1 stressed. As 1 shows, the roof can 2 be sloping towards the lateral edges, so that the roof inside 2i is concavely arched. The lower roof edge area 4 may be pulled down to below the upper edge of the cooling tower, advantageously between the upper edge of the cooling tower and the edge of the roof 4 an air outlet gap 6 is provided, which is annular around the opening cross-section 6 of the cooling tower 1 extends.

To make sure that out of the opening cross section 5 escaping steam actually upwards in the dome-shaped interior of the roof 2 flows, can in the area of the opening cross-section 5 an air flow generator 22 be provided, for example, may include a fan rotor, which the air and the steam at the exit from the cooling tower 1 in the roof 2 Overarched roof interior conducts.

The roof 2 can through a roof cooler 7 be cooled to at the roof inside 2i to reach a surface temperature which is a few degrees Kelvin colder than the temperature of the exiting vapor, thereby condensing the vapor on the inside of the roof 2i to enable. The mentioned roof cooler 7 may in this case comprise a liquid cooling, which is a cooling liquid circuit 8th may have, by means of which cooling liquid from the cooling liquid tank 9 and / or external coolant through or over the roof 2 is directed. The roof 2 For this purpose, corresponding cooling fluid conduits, for example in the form of superficially arranged and / or embedded liquid conduits on the inside of the roof, through which the cooling fluid is conveyed by means of a cooling fluid pump 23 through or over the roof 2 can be directed.

Alternatively, or in addition to such liquid cooling, the roof cooling device 7 Also include an air cooling, by means of which cooling air, for example, ambient air through or over the roof 2 can be directed. The roof 2 For this purpose, in an advantageous development of the invention, at least one air chamber 10 or at least one air duct through which the cooling air through the roof 2 can be directed. For example, the roof 2 a foil or membrane construction with several air chambers 10 or air ducts through which the ambient air by means of a cooling air blower 11 can be passed through.

The on the inside of the roof 2i condensed liquid can through the dome-shaped curvature of the roof 2 to the roof edge 4 Run down so that the condensation or the condensed liquid at the edge of the roof 4 through a dewater collector 12 can be collected. For example, along the roof edge 4 a collecting trough 13 be arranged, which from the roof edge 4 dripping dew water collects. Through a gutter drain 14 The collected condensation water or the collected condensed liquid in the cooling tower cup or the coolant reservoir 9 be returned, cf. 1 ,

As 1 shows, can the said roof with passages 24 be provided, which advantageously in an upper end portion of the roof 2 can be arranged to the emergence of an excessive air or vapor pressure under the roof 2 to avoid and let out excess steam. The mentioned passages 24 can advantageously be quite small and in particular make up less than 5% of the roof area. To the through the said passages 25 Nevertheless, capture the passing steam and reuse, so to speak, can over the said roof 2 a second roof 25 be arranged, which is advantageously also mushroom-shaped or dome-shaped over said roof 2 can tension, in particular over an area in which said passage openings 24 are provided to capture the steam exiting there. The aforementioned second roof 25 can be similar to the aforementioned roof 2 by a correspondingly designed roof cooling device, which is separate from the aforementioned roof cooling device 7 trained or from the said roof cooling device 7 can be formed, cooled to a condensation of steam on the roof inside 25i to reach. Advantageously, the other roof is also 25 a dewater collector 12 assigned over the roof 25 Collected condensate can be fed back in a similar manner.

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• DD 216527 [0005]
• DE 10333009 [0005]
• DE 8028136 [0005]

Claims (12)

Device for recovering the cooling fluid emerging from a cooling tower in the form of vapor, characterized by being located above the upper, open end of the cooling tower ( 1 ) exciting roof ( 2 ) for capturing the from the cooling tower ( 1 ) exiting steam. Device according to the preceding claim, wherein the roof ( 2 ) is dome-shaped or hat-shaped and from a raised roof area ( 3 ) to all lateral roof edge areas ( 4 ) decreases. Device according to one of the preceding claims, wherein the roof ( 2 ) the upper opening cross-section ( 5 ) of the cooling tower ( 1 ) completely covered and between the edge of the roof ( 4 ) and the upper edge of the cooling tower ( 1 ), preferably circulating, air outlet gap ( 6 ) is provided. Device according to one of the preceding claims, wherein the roof ( 2 ) a roof cooling device ( 7 ) for cooling the roof inside ( 2i ) is assigned to a steam condensing temperature. Device according to the preceding claim, wherein the roof cooling device ( 7 ) a cooling fluid circuit ( 8th ), which is connected to that in the cooling tower ( 1 ) is connectable such that from the cooling tower ( 1 ), in particular one at the bottom of the cooling tower ( 1 ) arranged cooling water basin ( 9 ), Cooling fluid removed and through / over the roof ( 2 ) and back into the cooling tower ( 1 ) is returned. Device according to one of the preceding claims, wherein the roof ( 2 ) is designed as a foil or membrane construction, the at least one air chamber ( 10 ) by which a cooling air blower ( 11 ) Cooling air for cooling the roof ( 2 ) is circulatable. Device according to one of the preceding claims, wherein the roof ( 2 ) a condensate collector ( 12 ) for collecting at the roof inside ( 2i ) is associated with forming condensation water. Apparatus according to the preceding claim, wherein the dewater collector ( 12 ) one at the lower edge of the roof ( 4 ) arranged collecting trough ( 13 ) via a gutter drain ( 14 ) with the cooling fluid tank ( 9 ) of the cooling tower ( 1 ) connected is. Device according to one of the preceding claims, wherein the roof ( 2 ) on the outside with a reflection layer, preferably in the form of a mirror coating ( 15 ) is provided. Cooling device comprising a cooling tower ( 1 ) and a device for recovering the from the cooling tower ( 1 ) in the form of steam exiting cooling fluid according to any one of the preceding claims. Cooling device according to the preceding claim, wherein the roof ( 2 ) on the cooling tower ( 1 ) is stored. Cooling device according to one of the two preceding claims, wherein in the region of the upper cooling tower end an air flow generator ( 22 ) for the discharge of the cooling tower ( 1 ) exiting steam in the roof ( 2 ) spanned roof interior is provided.

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