EP0939288A1 - Condensation system - Google Patents

Abstract

The system receives turbine steam via one or more turbine steam ports (21) and has a cooling system for condenser coolant. The condenser system contains a surface condenser (30) and a mixture condenser (35) and the cooling system has two separate coolant circuits. The surface condenser coolant and the mixture condenser coolant pass through the coolant circuits separately.

Description

Technical field

The invention relates to a system for the condensation of turbine exhaust gas with a Condenser system and a cooling system, two in the condenser system different condensation principles are combined and two in the cooling system Cooling types, a circulation cooling or a circulation / continuous cooling, with the Capacitor system are connected.

State of the art

Various types are known among the condenser systems, such as, for example, water-cooled surface condensers and mixed or injection condensers. Water-cooled surface condensers are characterized by a large number of cooling pipes through which cooling water flows, into which the water is directed through large water chambers and on which the steam that flows from a turbine is deposited. With this type of condenser, however, the production of the cooling pipes and water chambers is complex. Surface condensers are now realized with continuous cooling or with circulation cooling, for example with a wet or dry cooling tower. In continuous cooling, the water of a natural body of water is used as a coolant for condensers in an open circuit. This type of cooling is used in locations where such fresh water is available in sufficient quantities at a reasonable cost. The effects on the environment such as the heating of river water must also be taken into account. Continuous cooling can only be used for those condensers such as surface condensers where the coolant does not come into direct contact with the turbine steam.
If fresh water is not available in sufficient quantities or if there is no cheap coolant due to environmental protection reasons, various recirculation systems with recooling of the coolant are used. In a circulation circuit, the coolant flows through the condenser system, in which it heats up due to the condensation of turbine exhaust steam, and is then fed to a cooling tower for recooling and finally pumped back to the condenser. A distinction is made between cooling towers and wet cooling towers, the coolant being cooled in the first in an open and air-accessible system and in the latter in a closed, air-inaccessible system. Wet cooling towers are efficient due to the favorable heat transfer between water and air, the heat transferred leads to evaporation of approx. 1 to 2% of the water flow. However, they have the well-known disadvantage that evaporation creates fog, freezing rain and shadows, which are becoming less and less accepted in residential and agricultural regions. Furthermore, the evaporated water must be replaced by fresh water. Dry cooling towers have the advantage of not causing such fog, but they are less powerful than wet cooling towers and require additional and complex cooling surfaces in the cooling tower.
Further cooling towers realized today are the wet-dry cooling towers, also known as hybrid cooling towers, as are described, for example, in DE 24 52 123 and in "Cutting the fog", The Chemical Engineer, October 29, 1992. These meet in particular the requirements of environmental protection and the reduction of water loss, avoiding fog, freezing rain and shadows caused by the fog. For this purpose, the cooling water of a surface condenser is cooled in two cycles, with a dry cooling tower part and with a wet cooling tower part. In dry cooling, the cooling water is led through finned heat exchange tubes, whereby the air in the dry part of the cooling tower is heated by convective heat transfer. With wet cooling, the air heats up in direct contact between air and water. Evaporation of the water increases the humidity and creates air saturated with water. This saturated air mixes with the warm, dry air of the dry part of the cooling tower, resulting in a humid air flow and no more fog. In order to reduce the humidity of the wet air to a practical value, approximately 20% of the heat has to be given off in dry cooling. The advantages of both cooling processes can be combined in the hybrid cooling towers, namely the high cooling capacity of the wet process and the absence of steam due to the dry process. The degree of hybridization can be varied depending on the weather by bypassing the cooling water between the dry and wet part to optimize the final humidity of the air mixture.
A condensation system, also called a Heller system, is, for example, in L. Heller and L. Forgo, "Operating experience and further development results with the Heller system for air condensation for power plants", Energietechnik 13, December 1963 or Grosse Kraftwerke , volume 3, Springer Publisher described in 1968. Here the turbine exhaust steam is condensed in a mixing condenser by its own condensate, of which part of the condensate is fed to the water-steam cycle and the remaining part to a cooling circuit with a dry cooling tower. One of the advantages of a mixed condenser over a surface condenser is its very low or even zero degree of roughness, which lowers the condenser pressure and increases the turbine output. Furthermore, this type of condenser is cheaper to manufacture, since the expensive tubing in the condenser and the water chambers are eliminated. After all, there are no water losses in the dry cooling tower. However, the system has the disadvantage that a complex heating surface is required in the dry cooling tower. In particular, this area is larger compared to a system with the same output with surface condenser and wet cooling tower, since the heat transfer to the air is poorer.

Presentation of the invention

It is the object of the invention to create a condensation system which is inexpensive to manufacture while maintaining the advantages of the systems mentioned and at the same time achieves a performance gain for the turbine by reducing the condenser pressure. This object is achieved by a condensation system according to the preamble of claim 1, which has a surface condenser and a mixed condenser in its condenser system, the two condensers working in combination and the condenser coolants passing through separate cooling circuits in the cooling system.
In a first embodiment, the two condensers of the system are housed in a single, common housing in which both types of condensation take place, those on the surface of cooling pipes and those on their own sprayed condensate. In a second embodiment, the two capacitors are each arranged in a separate, separate housing. The steam is fed to the housings of the surface condenser and the mixing condenser via a common turbine exhaust connection.
The condenser system is connected in two separate circulation circuits via circulation lines to a wet-dry or hybrid cooling tower, with the cooling water of the surface condenser in the wet part being evaporatively cooled by evaporation and the condensate of the mixing condenser in the dry part of the hybrid cooling tower.
The main advantage of this condensation system is the use of a mixed condenser as part of the condenser system together with a surface condenser instead of a single surface condenser. This system uses the opportunity to build a mixing condenser for the dry part of a hybrid cooling tower, where the coolant is inaccessible to the air. This results in savings in material and manufacturing costs. The total cost of a surface condenser is largely determined by the cost of tubing, support plates for the pipes and water chambers. By using a mixed condenser part in the system according to the invention, the tubular heating surface, support plates and water chambers can be reduced, for example, by up to 50%, whereby an estimated 35% of the total costs of the condenser system can be saved. The overall cost of the system can be further reduced by reducing the volume of the mixing condenser with the same output. This is possible if the condensate is not sprayed as drops in the mixing condenser but is distributed as a very thin and turbulent water film. The heat transfer on a film of this type achieves a multiple of the heat transfer on drops, so that the same performance can be achieved in a smaller volume. Finally, the use of a mixed capacitor has the advantage that the degree of roughness of the mixed capacitor part reaches zero. The reduction in the degree of roughness also causes a reduction in the condenser pressure, as a result of which the turbine gains power.
The advantages of a hybrid cooling tower with regard to the environment, such as the avoidance of fog, are retained in the condensation system according to the invention. The requirement of less fresh additional cooling water compared to pure wet cooling towers is also retained, since only part of the cooling water of the entire condenser system is cooled using the wet process.
A bypass between the wet and dry cooling circuit to regulate the humidity at the cooling tower outlet is not possible in this system. Such regulation is not necessary, however, because the heat flow from dry cooling can be up to 50% and the humidity of the exiting air mixture is far from the saturated area in all operating loads and seasons.

Brief description of the drawings

Figur 1: Ein Kondensationssystem mit einer Kondensatoranlage mit zwei kombinierten Kondensatortypen in einem einzigen Gehäuse angeordnet und mit einer Hybridkühlanlage geschaltet,

Figur 2: Eine Seitenansicht und eine Draufsicht eines Kondensationssystems mit einem Oberflächenkondensator und einem Mischkondensator in separaten Gehäusen angeordnet,

Figur 3: Eine Ansicht und eine Seitenansicht einer kombinierten Kondensatoranlage mit einem Entlüftungskondensator und internen Entgasern für Kühlkondensat und Zusatzwasser.

Show it:

FIG. 1: a condensation system with a condenser system with two combined condenser types arranged in a single housing and connected with a hybrid cooling system,

FIG. 2: a side view and a top view of a condensation system with a surface capacitor and a mixing capacitor arranged in separate housings,

Figure 3: A view and a side view of a combined condenser system with a vent condenser and internal degassers for cooling condensate and make-up water.

Way of carrying out the invention

In Figure 1 is a system for condensing the exhaust steam of a low pressure turbine 20 shown. This has a capacitor system 25 in which two capacitors, a surface capacitor 30 combined with a mixed capacitor 35 in one common housing with a common condensate collector (Hotwell) 31 are arranged. The steam from the low pressure turbine 20 flows over one Evaporating nozzle 21 in the housing of the condenser system 25. There it condenses in the surface condenser 30 on cooling tubes which are in tube bundle 1 are summarized, and in the mixing condenser 35 on sprayed condensate.

a) In der sogenannten Tischaufstellung ist die Kondensatoranlage unter der Turbine angeordnet und die Dampfströmung verläuft von der Turbine vertikal wie in Figur 1 und

• der Mischkondensator ist in zwei Teile aufgeteilt, die beidseitig des Oberflächenkondensators angeordnet sind, oder
• der Mischkondensator ist statt neben dem Oberflächenkondensator hinter diesem angeordnet.

b) In der sogenannten Bodenaufstellung (floor mounted) sind die Turbine und die Kondensatoranlage ebenerdig angeordnet und die Dampfströmung verläuft horizontal und seitlich von der Turbine weg oder in Richtung der Turbinenachse, und

• der Mischkondensator ist neben dem Oberflächenkondensator, oder
• hinter dem Oberflächenkondensator angeordnet.

According to the directions of the arrow, part of the steam flows into the flow passages and into the tube bundle 1 and another part around a flow guide plate 14 into the mixing condenser part 35. The plate 14 causes the steam in the region of the spray nozzles 2 of the mixing condenser 35 from below flows in counter-cross flow to spray the condensate. The deflection of the steam flow ideally causes a counterflow to the condensate flow, but also causes a pressure loss that should be minimized. In order to optimize the flow conditions in the mixing condenser while minimizing the pressure loss, the flow is guided, for example, by means of one or more oblique or curved plates.
These plates 14 have in particular the function of optimizing the degassing of the condensate in the mixing condenser. The falling condensate always loses oxygen and other gases during raining down. It is to be avoided that steam in the mixing condenser with a higher oxygen content comes into contact with the hotwell, since otherwise the oxygen gets into the hotwell and the oxygen content in the condensate increases. For this purpose, the sheets 14 are arranged such that the new exhaust steam flowing in from the turbine, which has a low oxygen content, is led directly down to the hotwell 31 and forms a cushion of new exhaust steam over the condensate surface in the hotwell 31, which does not yet come into contact with the condensate has come. The vapor with a higher oxygen content flows upwards from Hotwell 31. To further minimize contact between the hotwell and the steam in the mixing condenser, the hotwell 31 extends, for example, only over the bottom of the surface condenser and not over the bottom of the mixing condenser part. The plates 14 further cause the live steam flow to run counter-current to the condensate flow from as far down as possible.
By replacing part of the surface condenser with a mixing condenser, the support of the housing by the support plates of the tube bundle is eliminated. Measures to support the housing of the combined condenser system are, for example, pipes, anchors or sheets between the support plates and the condenser wall.
The combined condenser system 25 is connected via circulation lines 32, 33 to a hybrid cooling tower 40, in which the coolants of the condenser system are recooled. The cooling water for the surface condenser 30 reaches the tubes of the tube bundle 1 via water chambers (not shown). After flowing through the cooling tubes, it is passed via a circulation line 32 with the aid of a circulation pump 5 to the wet part 42 of the hybrid cooling tower 40, where it is sprayed by spray nozzles 44 via a filling or one Packing 3 is sprayed. Cool air flows according to the direction of the arrow through air filter 43 and filler 3, the water cooling, flowing into a collecting vessel and being pumped back to surface condenser 30 via pump 5.
The mixing condenser 35 has a plurality of spray nozzles 2 or spray valves which spray cooled condensate of feed water quality into the steam space. The steam from the turbine condenses here in direct contact with the cool condensate, whereby a degree of zero can be achieved in this process. The sprayed condensate falls together with the newly formed condensate into the collecting vessel 31. Two lines lead away from this, one to a feed water pump 10, which returns a portion of the condensate to the water-steam circuit according to the exhaust steam flow, the other to one Circulation pump 6, which leads the remaining large condensate flow into a closed cooling circuit that is not accessible to the air. Through the circulation pump 6, it is passed over the circulation line 33 through finned heat exchanger tubes 4, where it gives off convectively heat to the air, which flows according to the direction of the arrow through air filters 43 and the action of fans 45 or through natural drafts up past the tubes and mixes with the wet air from the wet cooling. After flowing through the heat exchanger tubes 4, the condensate returns to the mixing condenser 35 via the circulation line 33.
In a cooling circuit through a wet cooling tower, water is lost through evaporation. About 1 to 2% of the electricity to be cooled is lost. Replacing these amounts of water increases the salinity of the water. The addition of larger quantities of fresh make-up water and drainage of salt water on the one hand replaces the evaporated water and on the other hand stabilizes the salt content in the cooling circuit. For this purpose, two water pipes 12, 13 are arranged on the hybrid cooling tower 40, one serving for the supply of fresh water and the other for discharging the salty water. A quantity of fresh make-up water is added per circulation of cooling water of the surface condenser, which corresponds to approx. 5% of the cooling water quantity of the open circulation. In comparison, the amount of make-up water required for a condensation system with only a surface condenser and recooling through a wet cooling tower is up to 5% of the total amount. In the system according to the invention, this additional water quantity is reduced by half in accordance with the distribution of the condensation between surface and mixing condensers, since part of the condensation power is taken over by the mixing condenser and its cooling condensate flows in a closed, almost lossless circulation. In a further embodiment of the invention according to FIG. 2, the condensation system is designed in the same way as in FIG. 1, but with the difference that the surface condenser part and the mixed condenser part are separated by each being accommodated in its own housing. FIG. 2 shows this embodiment using the example of a cylindrical surface condenser 30 and a mixing condenser 35, which are connected to the turbine 20 via an evaporation nozzle. Instead of one mixing capacitor, several mixing capacitors can also be arranged, as shown in the top view.
In the figures, only two possible versions of the combination of a surface and a mixing capacitor are shown. Other conceivable arrangements are, for example:

a) In the so-called table installation, the condenser system is arranged under the turbine and the steam flow runs vertically from the turbine as in FIGS. 1 and

• the mixing capacitor is divided into two parts, which are arranged on both sides of the surface capacitor, or
• the mixing capacitor is arranged behind the surface capacitor instead of the latter.

b) In the so-called floor installation, the turbine and the condenser system are arranged at ground level and the steam flow runs horizontally and laterally away from the turbine or in the direction of the turbine axis, and

• the mixing capacitor is next to the surface capacitor, or
• arranged behind the surface capacitor.

In a variant, the mixed condenser part of the combined condenser system according to the invention is connected to a dry cooling tower and the surface condenser part is connected to continuous cooling with cooling water from a natural body of water.
In a further variant, the surface condenser part is connected to a separate wet cooling tower and the mixed condenser part is connected to a separate dry cooling tower. The exhaust air from the two cooling towers is brought together and mixed via pipes, which reduces the moisture and avoids fog.
In order to achieve the lowest possible pressure in the condenser system and to increase the performance of the turbine, the condensate is freed of non-condensable gases (air) as far as possible. In surface condensers, this is achieved, for example, as shown in FIG. 1, by collecting the steam-air mixture in air coolers 7 in a low-pressure zone of each tube bundle 1 and sucking it away via suction pipes, not shown.
In the mixing condenser part, according to FIG. 3, non-condensable gases are removed from the condenser housing through a number of vent pipes 36, 37, 17 via a vent condenser 15. In the embodiment according to FIG. 3, the mixing condenser 35 is equipped with an internal degasser 23. This is arranged in the mixing condenser 35 in a kind of cabin, which is formed by flat partition walls 24 and the housing wall of the mixing condenser 35, the rear partition wall being indicated by a dashed line. The partition walls 24, which can also be cylindrical, extend downward from the ceiling of the mixing condenser space, but do not extend all the way to the floor of the space, so that steam can flow into the cabin from below. The degasser 23 has spray nozzles 26 from which a partial flow of the cooling condensate is sprayed via a packing or internals 34. Another degasser 28 for make-up water, which is added to the water-steam cycle to compensate for losses due to process steam removal, is formed like a degasser 23 by partitions in a kind of cabin and has spray nozzles that spray cooling condensate through a packing or internals 34. In both degassers 23, 28, the steam flows from below in countercurrent to the condensate flow. In a variant, the steam flows through an opening in the upper region of the partition walls 24 from below and upwards in the same counter-current to the condensate flow. In this case, the vent is arranged between the two cocurrent and countercurrent columns, as is known from EP 0 461 515. The make-up water can also be introduced into the degasser 23, so that only one degasser is built in the mixing condenser space.

In the embodiment of the condenser system 25 with separate condenser housings according to FIG. 2, the mixed condenser 35 likewise has an internal degasser 23. The degasser 23 and the packing 34 arranged therein are preferably cylindrical. The degassing takes place in a manner similar to that in FIG. 3. A steam line leads from the surface condenser 30 to the degasser 23, whereby the steam flows in countercurrent to the condensate flow. The condensate is conducted via a connecting line 46 from the degasser 23 to the hotwell 31 of the surface condenser 30. An additional water degasser can, for example, be integrated in the second mixing condenser room.
In Figure 3, the vapor-air mixture of the mixing condenser and its internal degasser is supplied to the venting condenser 15. This is attached to the mixing capacitor 35, but can also be integrated within the housing. The steam-air mixture flows via several different lines into the venting condenser 15, via line 17 from the additional water degasser 28, via line 36 of the mixing condenser and via line 37 from the degasser 23 of the mixing condenser. The majority of the steam is deposited there on condensate, which is sprayed by spray nozzles 18. The spray nozzles 18 are fed via a line 9 with bypass condensate from the circulation line of the dry cooling 33. The non-condensable gases are sucked away by a steam / gas mixture from the venting condenser 15 via a suction pipe 8. The level of the condensate level in the vent condenser is held by a siphon that leads from the vent condenser into the mixing condenser.
The resulting condensate from both condensers runs down into a condensate collecting vessel 31, of which it is supplied partly to the cooling circuit via the circulation pump 6 and partly to the water-steam circuit (not shown) via the feed water pump 10. The Hotwell 31 has a weir 39 for the purpose of separating the high-quality condensate from the surface condenser 30 and the degasser 23 for the water-steam circuit and the condensate of inferior quality from the mixing condenser and additional water degasser. The level of the condensate for the water-steam circuit is regulated by a conventional control valve (not shown) after the pump 10 and by an overflow option into or out of the condensate of the mixing condenser and additional water degasser. There is an overflow possibility between the condensate of the mixing condenser and that of the surface condenser with degasser 23 and openings in the upper area of the weir 39 which allow the condensate to pass.

As is known, the return of hot condensate in Surface condensers first place the condensate in an expansion vessel or Flashbox relaxes, in which the steam that forms rises during the Condensate falls down. In a mixing capacitor is compared to one Surface capacitor more free space available. According to a special one Embodiment of the invention, the mixing capacitor 35 in Figure 2 has an internal Flashbox 50 with a flat or curved baffle. Steam flows in along this sheet, is distributed in the condenser 35 and condenses sprayed condensate while condensate runs down into the collecting vessel 31.

Reference list

1

Tube bundle

2nd

Spray nozzles, spray valves

3rd

Filling, packing

4th

Heat exchanger tubes

5

Circulation pump for wet cooling

6

Circulation pump for dry cooling

7

Air cooler

8th

Suction line

9

Condensate supply line to the venting condenser

10th

Feed water pump

11

Exhaust air

12th

Additional water pipe for cooling water

13

Water drainage

14

Flow guide plate

15

Vent condenser

17th

Vent line for make-up water degasser

18th

Breather condenser spray nozzle

19th

Supply

20th

turbine

21

Evaporating nozzle

23

internal degasser

24th

Degasser partition

25th

Condenser system

26

Spray nozzles of the mixing condenser

28

Make-up water degasser

30th

Surface capacitor

31

Condensate collector (Hotwell)

32

Circulation line of wet cooling

33

Circulation line of dry cooling

34

Pack, internals

35

Mixing condenser

36

Vent line of the mixed condensate.

37

Vent line the degasser

39

Weir

40

Hybrid cooling tower

41

Dry section

42

Wet part

43

Air filter

44

Spray nozzles

45

fan

46

Connecting line to the Hotwell

47

Steam pipe to Degasser

50

Flashbox

Claims (10)

Condensation system for condensing turbine exhaust steam, which is conducted via one or more turbine exhaust ports (21) to a condenser system (25) and with a cooling system for condenser coolant,
characterized in that
the condenser system (25) has a surface condenser (30) and a mixing condenser (35) and the cooling system has two separate coolant circuits, the coolants in the surface condenser (30) and the mixing condenser (35) passing through the coolant circuits separately. Condensation system according to claim 1,
characterized in that
the surface condenser (30) and the mixing condenser (35) are arranged in a common condenser housing and the turbine exhaust nozzle (21) leads to the common condenser housing. Condensation system according to claim 1,
characterized in that
the surface condenser (30) and the mixing condenser (35) are each arranged in their own condenser housing and the steam is led to the surface condenser (30) and the mixing condenser (35) via a common or two separate turbine evaporation nozzles (21). Condensation system according to claim 2 or 3,
characterized in that
the condenser system (25) is connected in two circulation circuits via circulation lines (32, 33) to a wet-dry cooling tower (40), the coolant of the surface condenser (30) in the wet part (42) of the wet-dry cooling tower (40) and the coolant of the mixing condenser (35) is recooled in the dry section (41) of the wet-dry cooling tower (40). Condensation system according to claim 2 or 3,
characterized in that
the surface condenser (30) of the condenser system (25) is connected in a continuous circuit with a natural body of water and the mixed condenser (35) is connected in a circulation circuit with a dry cooling tower. Condensation system according to claim 2 or 3,
characterized in that
Flow guide plates (14) are arranged in the condenser housing for the mixing condenser (35), through which new exhaust steam flowing in directly from the turbine is guided over the hotwell (31) and a cushion is formed over the hotwell (31) from this new exhaust steam and the Steam flow in counter-cross flow to the condensate flow of the mixing condenser (35). Condensation system according to claim 1,
characterized in that
the mixing condenser (35) has a venting condenser (15) which is attached to the mixing condenser (35) or is integrated in the mixing condenser space. Condensation system according to claim 1,
characterized in that
the mixing condenser (35) has an internal degasser (23) with internals or a packing (34) for degassing condensate and increasing the water quality in the water-steam circuit, the steam flow running in countercurrent or countercurrent to the condensate. Condensation system according to claim 1,
characterized in that
the mixing condenser (35) has an internal make-up water degasser (28) with internals or a packing (34) for degassing make-up water for the water-steam cycle, the steam flow running in countercurrent or countercurrent to the condensate. Condensation system according to claim 1,
characterized in that
the mixing condenser (35) has an internal expansion vessel (50) with a baffle.

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