WO1995025880A1 - Process for operating a waste heat steam generator and waste heat steam generator so operated - Google Patents

Abstract

In a process for operating a waste heat steam generator (14), in particular for a gas and steam turbine plant (1), supply water (FW') is pre-heated and the pre-heated supply water (FW) is evaporated at the same time as the steam is overheated by heat transfer or heat exchange with a heat transfer medium (A) (flue gas) in a first or high pressure stage of a water-steam circuit (12). In order to simplify the process while achieving a high efficiency, steam from at least a second pressure stage is exclusively generated by expanding a partial stream (t1) of pre-heated supply water (FW). In a waste heat steam generator (14) so operated with a plurality of heating surfaces (20 to 28) connected to the water-steam circuit (12) of a steam turbine (10), an expanding container (40, 50) connected to the water-steam circuit is provided for the second and all other pressure stages.

Description

description

Method for operating a heat recovery steam generator and heat recovery steam generator operating thereafter

The invention relates to a method for operating a heat recovery steam generator, in particular for a gas and steam turbine installation, in which, in a first pressure stage of a water-steam cycle, both preheating of feed water and evaporation of the preheated feed water and overheating of the Steam takes place by heat transfer or heat exchange with a working medium containing heat (flue gas). The invention is further directed to a heat recovery steam generator operating according to this method.

Such a heat recovery steam generator is usually part of a gas and steam turbine system, in which the heat contained in the relaxed working fluid from the gas turbine is used to generate steam for the steam turbine. The heat transfer takes place by means of a number of heating surfaces, which are arranged in the heat recovery steam generator in the form of tubes or tube bundles. These in turn are connected to the water-steam cycle of the steam turbine. The water-steam cycle comprises one or more pressure stages. Each pressure stage usually has a preheating, an evaporator and a superheater heating surface. A circuit with a first or high pressure stage and with a second or low pressure stage - a so-called two-pressure process - is known from EP 0 523 466 AI. A circuit with three pressure stages and Z ischen superheating - a so-called three-pressure process with intermediate superheating - is known from EP 0 523 467 AI. In addition, a medium pressure stage is provided which represents the second pressure stage in the three-pressure process, so that the low pressure stage represents the third pressure stage. In such multi-pressure processes in gas and steam turbine systems, which are becoming more and more widespread due to the high economic efficiency, the circuit of the heat recovery steam generator and the water-steam cycle is becoming increasingly complex. In a circuit with three pressure stages and reheating of the waste heat steam generator, there are a large number of heating surfaces, for example eleven or more heating surfaces, with three evaporator systems and one steam drum each. This requires a correspondingly large number of collectors and distributors for the tube bundles of the heating surfaces as well as a large number of tube connection systems, so that the plant engineering outlay is particularly high. The resulting complicated operation is not only uneconomical, but in particular also affects the reliability and availability of such systems.

When operating the evaporator systems in natural circulation, the number of active components, for example pumps, can be reduced in comparison to the forced circulation or forced circulation. However, the number of distributors and collectors increases

Preheaters or top heaters continue to turn on if several heating surfaces are arranged in parallel on the flue gas side and the tube bundles of the respective heating surfaces are to be connected in series on the water / steam side. Therefore, in spite of the comparatively higher cost-effectiveness of the three-pressure process, a decision was often made in favor of a two-pressure process, since the latter appears to be simpler to set up and operate. The efficient three-pressure process with intermediate superheating has so far only been used with large power units, since the increase in costs compared to a one-pressure or two-pressure process has less effect here because of the comparatively high circuit complexity.

The invention is therefore based on the object of specifying a method for operating a heat recovery steam generator, in particular for a gas and steam turbine installation, with which a high degree of efficiency can be achieved with little outlay in terms of process technology. is enough. In the case of a waste heat steam generator, this is to be achieved by a reduced technical outlay compared to the prior art.

With regard to the method, this object is achieved according to the invention in that steam of at least one second pressure stage is generated exclusively by relaxing a partial stream of the preheated feed water.

The invention is based on the consideration that, compared to the previous heat recovery steam generators, significantly fewer heating surface packages or tube bundles are used. In other words, the number of heating surfaces should be as small as possible, irrespective of the number of pressure stages, that is to say regardless of whether a one-pressure, two-pressure or three-pressure circuit is selected.

In an advantageous further development, the steam of the second pressure stage generated by expansion is superheated by heat exchange with water from the water-steam cycle. Alternatively, superheating takes place by throttling the steam to a reduced pressure level. According to a further alternative, the steam generated by expansion is overheated by heat exchange with the flue gas.

In the case of two or more pressure stages, the steam generated in the first pressure stage and subsequently partially expanded in a first or high-pressure part of the steam turbine is advantageously overheated again by heat exchange with the flue gas from the gas turbine within the waste heat steam generator

(Reheating). In this case, this partially relaxed steam is expediently admixed with the steam generated in the second pressure stage before it is overheated again and is fed together with this to the intermediate superheating.

In a three-pressure process, the steam is advantageously also exclusively from the third or low-pressure stage Relaxation of water generated at a higher pressure level. For this purpose, the water formed during the expansion of the partial flow of the preheated feed water is expediently expanded from the second pressure stage to the pressure level corresponding to the third pressure stage. As in the second pressure stage, the low-pressure steam is overheated by heat exchange with water from the water-steam cycle, by throttling or by heat exchange with the flue gas.

The water which is still hot in the third pressure stage during the expansion is advantageously used for heating the feed water. The feed water is expediently heated by heat exchange with the water from the third pressure stage, the latter being cooled. The cooled water from the third pressure stage is then mixed into the feed water.

The temperature of the preheated feed water is expediently set by changing the partial stream withdrawn for the second pressure stage. The temperature of the feed water after preheating or before being introduced into the evaporator system of the first pressure stage can be regulated in a simple manner via this removal.

With regard to the waste heat steam generator, in which a number of heating surfaces of a first pressure stage are arranged in a water-steam circuit of the steam turbine, the stated object is achieved according to the invention in that a steam is generated in a second pressure stage to generate steam -Circuit-switched first expansion tank is provided for relaxing feed water preheated in the first pressure stage, the steam generation in the second pressure stage taking place exclusively by expansion.

Within the first or high-pressure stage, the preheating and evaporation of the feed water and the superheating of the steam take place as in the previous way by means of a preheating, an evaporator or a superheater heating surface. These are arranged one behind the other within the heat recovery steam generator in the direction of flow of the flue gas from the gas turbine and connected in series within the water-steam cycle. The flue gas flow and the water-steam cycle are linked in countercurrent.

The waste heat steam generator also advantageously comprises a reheater heating surface which is connected to the steam turbine both on the inlet side and on the outlet side. In an expedient embodiment, this intermediate superheater heating surface is connected on the input side to a steam outlet of the first expansion tank. In this connection there is advantageously a heat exchanger for overheating the steam of the second pressure stage.

To generate steam of a third pressure stage, a second expansion tank connected to the first expansion tank is advantageously provided, the steam of the third pressure stage likewise being generated exclusively by expansion.

The second expansion tank is expediently connected via its steam outlet to an inlet of the steam turbine and via its water outlet to a condenser connected downstream of the steam turbine. In the connection on the steam side, a heat exchanger is expediently provided for overheating the steam flowing out of the second expansion tank, which is connected into the water-steam circuit between the first and the second expansion tank.

For preheating the condensate or feed water emerging from the condenser connected downstream of the steam turbine, the second expansion tank is connected to the condenser on the water side via a heat exchanger or via a mixing device. The advantages achieved by the invention are, in particular, that starting from a first or high-pressure stage due to the generation of steam at each further pressure stage solely by relieving water from the pressure stage with the respectively higher pressure level, a particularly simple construction of the Heat recovery steam generator is possible. In this case, only three heating surfaces are required within the heat recovery steam generator, regardless of the number of pressure stages, and four when using an intermediate superheater, so that the heat recovery steam generator regardless of whether an input

Pressure, two-pressure or three-pressure circuit is provided, is constructed practically the same.

While no circulation pump is required for an evaporator system of such a heat recovery steam generator operated in natural circulation, only a circulation pump system is required for forced circulation, which is expediently designed to be redundant. In addition, only a feed water line to the heat recovery steam generator and a water-steam separation drum for the evaporator system of the first pressure stage are required, so that the control and control engineering effort when operating a gas and steam turbine system with such a heat recovery steam generator is particularly low.

Embodiments of the invention are explained in more detail with reference to a drawing. In it show:

FIG. 1 in a three-pressure circuit, a gas and steam turbine system with a heat recovery steam generator and with two expansion tanks and with one heat exchanger each in a high-pressure drum and in one of the expansion tanks,

FIG. 2 shows a circuit according to FIG. 1 with a steam superheater in a partial power line leading to an expansion tank, 3 shows a circuit according to FIG. 1 with an exhaust gas-heated superheater and overheating by throttling, and

4 shows a circuit according to FIG. 1 without superheater and with a mixing preheater.

Corresponding parts are provided with the same reference symbols in all figures.

A gas and steam turbine system according to Figures 1 to 4 comprises a gas turbine system la and a steam turbine system Ib. The gas turbine system 1 a comprises a gas turbine 2 with an air compressor 3 coupled thereto and a combustion chamber 4 connected upstream of the gas turbine 2 and which is connected to a fresh air line 5 of the air compressor 3. A fuel line 6 opens into the combustion chamber 4 of the gas turbine 2. The gas turbine 2 and the air compressor 3 as well as a generator 7 sit on a common shaft 8.

The steam turbine system 1b comprises a steam turbine 10 with a coupled generator 11 and, in a water-steam circuit 12, a capacitor 13 connected downstream of the steam turbine 10 and a waste heat steam generator 14.

The steam turbine 10 consists of a high-pressure part 10a and a medium-pressure part 10b and a low-pressure part 10c, which drive the generator 11 via a common shaft 15.

In order to supply working fluid A or flue gas relaxed in the gas turbine 2 into the heat recovery steam generator 14, an exhaust gas line 17 is connected to an inlet 14a of the heat recovery steam generator 14. The relaxed working medium A from the gas turbine 2 leaves the heat recovery steam generator 14 via its outlet 14b in the direction of a chimney (not shown). In a first pressure stage or high-pressure stage of the water-steam circuit 12, the heat recovery steam generator 14 comprises a high-pressure preheater or economizer 20 as heating surfaces and a high-pressure evaporator 22 and a high-pressure superheater 24. The high-pressure superheater 24 is over a live steam line 26 is connected to the high pressure part 10a of the steam turbine. The high-pressure part 10a is connected on the output side to the medium-pressure part 10b of the steam turbine 10 via an intermediate superheater 28 which is arranged within the waste heat steam generator 14 in the region of the high-pressure superheater 24. The medium pressure part 10b is connected to the low pressure part 10c of the steam turbine 10 via a mixing point 29. The low-pressure part 10c is connected on the outlet side to the capacitor 13 via a steam line 30.

The capacitor 13 is connected to the economizer 20 via a feed water line 32.

The economizer 20 is connected on the output side via a motor-driven valve 34 to a high-pressure drum 36 of the high-pressure stage. The high-pressure evaporator 22 and the high-pressure superheater 24 are connected to this drum 36.

The economizer 20 of the high-pressure stage is also connected on the output side to a first relaxation tank or medium-pressure relaxing device 40 via a partial flow line 38. A motor-driven valve 42 is connected to the partial flow line 38. A steam line 44 connects an outlet 46 on the steam side of the first expansion tank 40 to a mixing point 48 provided on the inlet side of the reheater 28.

The first flash tank 40 is connected to a second flash tank or low-pressure tensioner 50. For this purpose, a water-side outlet 52 of the first expansion tank 40 is connected to the second via a hot water line 54, into which a motor-driven valve 56 is connected Relaxation tank 50 connected. The second expansion tank 50 is connected to the feed water line 32 via a water line 58. The second expansion tank 50 is also connected to the low-pressure part 10c of the steam turbine via a steam line 60 connected to the mixing point -29.

The water-steam circuit 12 shown in FIGS. 1 to 4 is constructed from three pressure stages. However, it can also be constructed from only two pressure stages. In this case, the second flash tank 50 is omitted. The first flash tank 40 is then connected to the feed water line 32 on the water side, for example via a throttle.

When the gas and steam turbine system la, lb is in operation, the combustion chamber 4 is supplied with liquid or gaseous fuel B, for example natural gas or heating oil, via the fuel line 6. The fuel B is burned in the combustion chamber 4 with compressed fresh air L from the air compressor 3 in order to produce the working medium A ″ for the gas turbine 2. The hot and high-pressure working medium A or flue gas which is produced during the combustion is burned in the Gas turbine 2 relaxes and drives it and the air compressor 3 and the generator 7. The relaxed working medium A emerging from the gas turbine 2 is introduced into the waste heat steam generator 14 via the exhaust gas line 17 and is generated there in the first pressure stage of high-pressure steam used for the steam turbine 10. For this purpose, the flue gas stream and the water-steam circuit 12 are linked in countercurrent within the waste heat steam generator 14.

The partially expanded steam emerging from the high-pressure part 10a of the steam turbine 10 is overheated again in the reheater 28 and supplied to the medium-pressure part 10b of the steam turbine 10 in the superheated state. The steam expanded to low pressure in the medium pressure part 10b is in the low-pressure part 10c completely relaxed and fed to the condenser 13 via the steam line 30. The steam condenses there. The condensate or feed water FW is conveyed via a condensate pump 62 and a feed water pump 63 into the economizer 20 of the first or high pressure stage and is preheated there. A portion of the preheated feed water FW 'flows into the high pressure drum 36.

A partial flow t ^ of the preheated feed water FW 'flows via the partial flow line 38 into the first expansion tank 40. There, the partial flow t ^ of the preheated feed water FW' is expanded, with steam or medium pressure steam at medium pressure and at medium pressure ¬ of water or boiling water. The medium pressure steam is fed to the reheater 28 via the steam line 44. The medium-pressure water is fed via the hot water line 54 to the second expansion tank 50, where it is converted into low-pressure steam or low-pressure steam and water under low pressure. The low-pressure steam is fed to the low-pressure part 10c of the steam turbine via the steam line 60. The low pressure water from the second expansion tank 50 is mixed via the water line 58 with the feed water FW to be preheated.

While in the first pressure stage or high pressure stage the steam is generated in a manner known per se within the heat recovery steam generator 14 by heat exchange on the heating surfaces 20, 22 and 24, the medium pressure steam of the second or medium pressure stage is obtained exclusively by releasing the partial flow ti of the preheated feed water FW ' generated from the high pressure stage. Likewise, the low-pressure steam of the third or low-pressure stage is generated exclusively by releasing the water formed during the expansion of the partial flow t ^. While the production of medium or low pressure steam takes place by releasing hot water from the economizer 20, there are various possibilities for overheating the medium pressure steam and the low pressure steam. For example, the medium-pressure steam and the low-pressure steam are overheated by heat exchange with water from the water-steam circuit 12, which is warmer at the corresponding point than the respective steam.

So according to your embodiment according to Figure 1 for

Overheating of the medium pressure steam of the second pressure stage, a heat exchanger 70 is provided which is switched into the steam line 44 and is arranged within the high pressure drum 36. For the overheating of the low pressure steam of the third pressure stage, a heat exchanger 72 is provided, which is connected to the steam line 60 and arranged within the first expansion tank 50.

According to the exemplary embodiment according to FIG. 2, a heat exchanger 70 ', which is also arranged in the steam line 44 and is connected to the partial flow line 38, is provided for the overheating of the medium-pressure steam. A heat exchanger 72 ', which is also arranged in the steam line 60 and is connected to the hot water line 54, is provided for overheating the low-pressure steam.

According to the exemplary embodiment according to FIG. 3, the medium-pressure steam is superheated by heat exchange with the flue gas A from the gas turbine 2. For this purpose, a superheater heating surface 74 arranged inside the steam generator in the area of the economizer 20 is provided in the steam line 44. The low pressure steam is overheated by throttling the low pressure steam generated within the second expansion tank 50. For this purpose, a throttle device 76 is provided in the steam line 60. In the exemplary embodiment according to FIG. 4, the medium pressure steam from the first expansion tank 40 and the low pressure steam from the second expansion tank 50 are fed directly to the reheater 28 or the low pressure part 10c of the steam turbine 10.

In the exemplary embodiments according to FIGS. 1 to 3, the water flowing out of the second expansion tank 50 is mixed into the feed water FW to be preheated via a heat exchanger 80

Water line 58 and on the other hand switched into the feed water line 32. The water from the second expansion tank 50 that cools within the heat exchanger 80 is fed to the feed water FW flowing out of the condenser 13 on the suction side of the feed water pump 63 coupled to the condensate pump 62 via a motor 82. The condensate pump 62 and the feed water pump 63 form a combined unit together with a motor 82 common to them. Between the heat exchanger 80 and the feed water pump 63 - on the suction side thereof - a motor-operated valve 84 is connected into the water line 58. Another valve 86 is connected between the feed water pump 63 - on its pressure side - and the heat exchanger 80 into the feed water line 32.

In the exemplary embodiment according to FIG. 4, the water line 58 of the second expansion tank 50 is connected to a feed water tank or mixing preheater 90. The water accumulating within the feed water tank 90 is converted into water and steam in a relaxation bottle 92, the steam being fed back to the feed water tank 90. The second flash tank 50 is connected to the flash bottle 92 via a throttle 94.

The temperature T of the preheated feed water FW 'can be changed by changing the partial flow t] _, that is, by changing the per unit time via the partial flow line 38 in the voltage container 40 guided feed water quantity, can be set. If, for example, when the gas turbine 2 is operated with heating oil, an increased heat recovery steam generator or boiler inlet temperature is required for preheating the feed water FW compared to natural gas operation, a comparatively high partial flow t 1 of preheated feed water FW 'is taken from the high-pressure preheater or economizer 20. The result of this is that a comparatively large amount of return water from the expansion tanks 40, 50 is available for preheating the feed water. As a result, the temperature T at the outlet of the economizer 20 drops further compared to the natural gas operation of the gas turbine 2.

Claims

claims

1. A method for operating a heat recovery steam generator (14), in particular for a gas and steam turbine plant (1), wherein in a first pressure stage (20 to 24) of a water-steam circuit (12) both preheating feed water (FW) and the evaporation of the preheated feed water (FW *) and an overheating of the steam by heat exchange with a heat-containing working medium (A) (flue gas), characterized ^'in that steam at least a second pressure stage (40) exclusively by relaxing a partial flow (t ^) of the preheated feed water (FW) is generated.

2. The method of claim 1, d a d u r c h g e k e n n ¬ z e i c h n e t that the steam generated by expansion of the second pressure stage (40) is overheated, the superheating of this steam takes place:

a) by heat exchange with water of the water-steam cycle (12), or

b) by heat exchange with the working fluid (A), or

c) by throttling to a reduced pressure level.

3. The method of claim 1 or 2, so that the steam generated in the first pressure stage (20 to 24) is partially relaxed in a steam turbine (10) and then together with that in the second

Pressure stage (40) generated steam is reheated by heat exchange with the working means (A).

4. The method according to any one of claims 1 to 3, since - characterized in that steam one third pressure stage (50) is generated by releasing the water formed during the expansion of the partial flow (t ^).

5. The method according to any one of claims 1 to 4, so that the feed water (FW) to be preheated is heated by heat exchange with water which is generated during the relaxation of the partial stream (t ^).

6. The method according to any one of claims 1 to 5, since ¬ characterized in that the preheating feed water (FW) during the relaxation of the Teil¬ stream (t _] _) resulting water is mixed.

7. The method according to any one of claims 1 to 6, since ¬ characterized in that the temperature (T) of the preheated feed water (FW ¹ ) is adjusted by changing the partial flow (t] _).

8. heat recovery steam generator, in particular for carrying out the method according to any one of claims 1 to 7, characterized in that in order to generate steam a second pressure stage in the water-steam circuit (12) switched first expansion tank (40) for Ent¬ to relax in preheated feed water (FW ¹ ) is provided in the first pressure stage, steam generation in the second pressure stage taking place exclusively by expansion.

9. waste heat steam generator according to claim 8, g e k e n n - z e i c h n e t by an intermediate superheater (28) which is connected on the input side to a steam outlet (46) of the first expansion tank (40).

10. Heat recovery steam generator according to claim 8, characterized in that the first expansion tank (40) on the steam side is connected via a heat exchanger (70; 70 ') to the reheater (28).

11. heat recovery steam generator according to one of claims 8 to 10, d a d u r c h g e k e n e z e i c h n e t that for generating steam of a third pressure stage, a second connected to the first expansion tank (40). Expansion tank (50) is provided, the steam of the third pressure stage being generated exclusively by expansion.

12. Heat recovery steam generator according to one of claims 8 to 11, d a d u r c h g e k e n n e e c h n e t that the second expansion tank (50) on the steam side with the steam turbine (10) and on the water side with one of the steam turbine (10) downstream capacitor (13) is connected.

13. Heat recovery steam generator according to claim 12, so that the second expansion tank (50) is connected on the steam side to the steam turbine (10) via a heat exchanger (72; 72 ').

14. Heat recovery steam generator according to claim 12 or 13, so that the second expansion tank (50) is connected on the water side via a heat exchanger (80) or via a mixing device (90) to the condenser (13).