EP2423465A2 - Method for operating a steam turbine power plant and device for generating steam - Google Patents

Abstract

The method involves firing a steam generator (4) with brown coal. The brown coal is subjected to indirect drying in a fluidized bed dryer (8). The fluidized bed dryer is partially heated with steam from a water vapor circuit of the steam generator. Energy of vapor (1) resulting from drying process of the brown coal is partially utilized for preliminary heating of combustion air. The energy of the vapor is coupled into the combustion air by a heat exchanger. An independent claim is also included for a device for producing steam.

Description

Method for operating a steam turbine power plant and device for generating steam

The invention relates to a method for operating a steam turbine power plant with a lignite-fired steam generator, in which the brown coal is first subjected to indirect drying in a fluidized bed dryer, wherein the fluidized bed dryer is at least partially heated with steam from the water-steam cycle of the steam generator.

A method of the type mentioned is, for example, from DE 103 19 477 A1 known.

The invention further relates to a device for producing steam, comprising at least one dryer for predrying lignite wet brown coal, at least one lignite fired steam boiler, at least one steam generator downstream steam turbine, at least one feedwater supply to the steam generator, a device for feedwater preheating and at least one air preheater for the combustion air.

As is well known, the burning of lignite is so special in that the lignite wet lignite contains up to 65% water, which in comparison to the generation of electricity from coal higher specific CO ₂ emissions arise in the production of electricity from lignite. By appropriate drying of the lignite before burning in the steam generator of a power plant, a significant increase in the efficiency can be achieved, whereby the specific CO ₂ emission is reduced.

The lignite brown coal has a water content of 45 to 65%, which is reduced by drying to about 10 to 25%. The so-called WTA process (fluidized-bed drying with internal waste heat utilization) has proven to be a particularly effective drying process. With such a drying method, which for example from the DE 195 18 644 C2 is known, the efficiency of a lignite power plant can be about 4 up to 5 percentage points over conventional lignite-fired power plant technology. In fluidized-bed drying, pre-ground raw lignite is introduced into the stationary fluidized bed of a dryer which operates at a slight overpressure. In the dryer / reactor heating coils are arranged, the heating steam condenses at a temperature level of about 130 ° C. The leaked from the raw lignite coal during drying in the fluidized bed drying plant water is slightly superheated and vapor before as a separate stream, which is referred to as vapors. Part of the vapor is returned to the dryer via a blower to fluidize the fluidized bed.

In the DE 195 18 644 C2 For example, it is proposed to compress a partial stream of the vapor and to supply the heat exchanger as a heating medium so that the vapor condenses at least partially, so that for the desired drying of the fuel in part the heat of vaporization of the vapor can be exploited.

With such an arrangement or such a procedure, a stronger energetic use of emerging from the dryer vapor is possible, so that the overall efficiency of the power plant is increased and the emissions are reduced.

Alternatively, it is possible to use the energy of the vapor for feedwater pre-heating. This process variant is for example in the DE 103 19 477 A1 described. According to the method described therein, it is provided that the energy of the resulting from the drying of lignite vapor is used for multi-stage preheating the cold feed water from the water-steam cycle.

The preheating of the feedwater in the water-steam cycle, however, does not allow full utilization of the heat of vapor, since the feed water is not a sufficiently large heat sink. In the DE 103 19 477 A1 It is proposed to compress a partial flow of the vapor and preheat with the compressed vapor feed water at a higher temperature level.

Even with this variant of the energetic use of the vapor part of the heat content of the vapor is not optimally used.

The invention is therefore based on the object with respect to a method and a device of the type mentioned with respect. To improve the energetic use of the resulting in the drying of the vapor.

The object is initially achieved by a method for operating a steam turbine power plant with a lignite-fired steam generator, in which the brown coal is first subjected to indirect drying in a fluidized bed dryer, wherein the fluidized bed dryer at least partially heated with steam from the water-steam cycle of the steam generator is, wherein the method according to the invention is characterized in that the energy of the resulting from the drying of lignite vapor is at least partially used for preheating the combustion air.

It is basically practice to raise the temperature of the combustion air to a higher level with a regenerative air preheat, with a view to the carnotization of the power plant process. In any case, it makes sense and is desirable to couple so much heat into the combustion air that the air temperature before combustion chamber inlet corresponds approximately to the flue gas temperature downstream of the economizer minus gravitational factor. However, since a classic regenerative air preheater - hereinafter referred to simply as Luvo - has a large lower Graderigkeit and thus generates large Exergieverluste, it is useful and expedient to preheat the fresh air supplied to the Luvo means of a heat exchanger. If in the following text with reference to the parts of the steam turbine power plant of "behind" or "before" the speech, this statement always refers to the flow direction of the considered in the respective process branch material.

For such a preheating of the combustion air is usually from the prior art energy either in the form of low-temperature heat taken from the water-steam cycle or from the flue gas leaving the luff.

The procedure of the invention has the advantage that the amount of heat that has been coupled into the combustion air, no longer needs to be decoupled from the flue gas via the windward. It is thus shifted a certain amount of heat from a low to a higher temperature level, which is then made available to the water-steam cycle. Luvo in the context of the invention is not necessarily to be understood as a regenerative heat exchanger, but this may for example also be a flue gas heated Luvo.

With the invention, therefore, two advantages are equally achieved, namely on the one hand, the higher energy use of the vapor by heat exchange with a larger temperature sink and a shift in the sense of usability released amount of heat to a higher temperature level, which can ultimately be used in the feedwater supply.

In an advantageous variant of the invention, the coupling of the energy of the vapor in the combustion air by means of at least one heat exchanger, which is connected upstream of a heated with flue gas Luvo. This is done in particular by means of a condensation heat exchanger. In a further variant of the method it is provided that the windward additional heat from the already partially cooled by means of the windward flow of flue gas is abandoned.

In this case, the heat from the flue gas behind the air preheater can be coupled out by means of a heat transfer medium, for example by means of water.

In a particularly advantageous variant of the method according to the invention, it is provided that at least one partial stream of the vapor after being drawn off from the fluidized-bed dryer is compressed in a vapor compressor and fed to at least one condensation heat exchanger. So, in addition, the free Expected condensation heat of the vapor used. The compression increases the temperature level at which the vapors condense, thus a higher air preheating can be achieved. In this case, such amounts of energy can be coupled into the combustion air, that under certain circumstances a decoupling of heat from the flue gas for the purpose of combustion air preheating is completely unnecessary.

Conveniently, a partial flow of the flue gas is branched off in front of the air preheater and used to preheat the boiler feed water, with the bridging of the air preheater.

In a particularly advantageous variant of the method according to the invention it is provided that as much flue gas is diverted in front of the air preheater, as corresponds to the injected from the vapor into the combustion air energy.

It is particularly advantageous if the coupling of the energy of the vapor into the combustion air takes place in several stages, wherein a partial amount of the vapor is compressed in a vapor compressor and condensed in a condensation heat exchanger.

The object underlying the invention is further achieved by a device for generating steam, comprising at least one dryer for predrying lignite wet lignite, at least one fired with the pre-dried lignite steam boiler, at least one steam generator downstream steam turbine, at least one feedwater supply to the steam generator, at least a device for feedwater preheating and at least one air preheater for the combustion air, wherein the device according to the invention is characterized in that the air preheater in the fresh air supply at least one heat exchanger is connected upstream, which is connected to the vapor outlet of the dryer.

Conveniently, the dryer is designed as a fluidized bed dryer.

It will be apparent to those skilled in the art that the dryer does not necessarily have to be formed as a fluidized bed dryer, but drying can also take place in other indirectly heated reactors in which high-energy vapors / swaths obtained.

In an advantageous variant of the device according to the invention it is provided that the guided to the air preheater flue gas line is provided with a branch bypassing the air preheater, which is connected to the feedwater preheating.

In this way, the energy injected from the dryer into the combustion air can be completely "shifted" into the feedwater preheat.

Behind the air preheater, at least one further flue gas cooler may be provided, which cooperates with the combustion air supply in front of the air preheater.

According to a particularly advantageous embodiment of the device according to the invention it is provided that at least one vapor compressor is provided, which is connected upstream of at least one condensation heat exchanger in the combustion air supply in front of the air preheater.

The air preheater is expediently designed as a regenerative air preheater.

The invention will be explained below with reference to the accompanying figures with reference to two variants of the method.

Figur 1

das Verfahrensschema einer ersten Verschaltungsvariante der Einrichtung der Erfindung, und

Figur 2

das Verfahrensschema einer zweiten Verschaltungsvariante der Einrichtung der Erfindung.

Show it:

FIG. 1

the process scheme of a first Verschaltungsvariante the device of the invention, and

FIG. 2

the process scheme of a second Verschaltungsvariante the device of the invention.

In the figures, parts of a steam turbine power plant and their interconnection are shown schematically, for simplification reasons, essentially only the mass flows vapor 1, combustion air 2 and flue gas 3 are shown. The water-steam cycle of the steam turbine power plant is shown only partially and greatly simplified.

The reference numeral 4 designates the steam generator of the steam turbine power plant. The steam generator 4 is designed as a lignite-fired boiler. In this water is evaporated in a known manner and expanded in a downstream steam turbine 5. The steam turbine 5 comprises a high-pressure part, a medium-pressure part and a low-pressure part, which are not designated more precisely in the process diagram. The steam turbine 5 drives a generator 6, which in turn feeds electrical energy into a power grid.

The steam turbine 5 is followed by a condenser 7, in which the low-pressure steam is condensed.

By means of the boiler feed water pump, the condensate is returned to the steam generator 4.

The steam generator 4 is charged with dry lignite as fuel, which was subjected to indirect drying in a fluidized bed dryer 8. The fluidized-bed dryer 8 is heated with steam from the low-pressure part of the steam turbine 5. Part of the resulting in the drying of brown coal vapor 1 is first dedusted in a dust collector 9 and fed back to the fluidized bed dryer 8 with a fan 10 as a fluidizing agent. Further partial streams of the vapor 1 are, as will be described below, used to preheat the combustion air 2.

The combustion air 2 is supplied in a known manner to a regenerative air preheater 11, in which the combustion air is preheated in countercurrent with the flue gas 3.

As in both the process scheme according to FIG. 1 as well as in the process scheme according to FIG. 2 is provided, a partial flow of the flue gas 3 is passed over a bypass line 12 to the air preheater 11. This first passes through a first high-pressure air bypass economizer 13 (HD-Lubeco) and then via a low-pressure air bypass economizer 14 (ND Lubeco), which are connected in series with respect to the flue gas stream 3. The heat content of the flue gas 3 is coupled via the HD Lubeco 13 in the high pressure part of the feedwater circuit, the remaining heat of the flue gas is coupled in the next stage in the low pressure part of the boiler feedwater cycle.

In the flow direction behind the air preheater 11 and the economizers 13, 14 is in the in FIG. 1 a further flue gas cooler 15 is provided, which emits its heat load via a water / air preheater 16 provided in the combustion air supply. The flue gas cooler 15 and the water / air preheater 16 communicate with each other via water as the heat transfer medium in a closed circuit.

At an assumed ambient temperature of about 10 ° C, the combustion air 2 passes in the process variant 1 according to FIG. 1 at a temperature of about 10 ° C in a Brüdenluftvorwärmer 17, where it is heated to about 95 ° C. The Brüdenluftvorwärmer 17 is acted upon by a partial flow of the vapor 1 from the fluidized bed dryer 8. The vapor / air preheater 17 is downstream of the water / air preheater 16, viewed in the flow direction of the combustion air 2, in which the combustion air 2 can be raised to a temperature of about 140 ° C. The combustion air 2 then flows through the regenerative air preheater 11, where it is heated in countercurrent with the about 360 ° C hot flue gas to about 330 ° C. The flue gas, which with 360 ° C in enters the air preheater 11, this can leave, for example, at about 160 ° C.

In practice, the air preheating with the Brüdenwärme is expected indirectly, d. H. via another heat exchanger with water circuit (or other liquid). The reason for this is that high volume flows occur both in the vapor and in the air. Since the fluidized bed drying is located remotely, corresponding systems for the high volume flows would have to be provided for direct air preheating over the distance. By indirect preheating these can be made considerably smaller.

At the in FIG. 2 As shown, a partial flow of the dust separator 9 of the fluidized bed dryer 8 leaving vapor 1 is fed to a vapor compressor 18, which is followed by a second Brüdenluftvorwärmer 19.

A first partial stream of the vapor 1 is fed to the vapor air preheater 17, this is upstream of the condensation heat exchanger 19 in the flow direction of the combustion air 2. In this way, the energy of the vapor 1 is coupled in several stages in the combustion air 2, wherein in the condensation heat exchanger 19 in addition a further part of the released heat of condensation of the vapor 1 is used. As a result, the air compared to the method accordingly FIG. 1 be preheated to a higher temperature.

At the in FIG. 2 method variant shown, it is possible to couple the majority of the energy of the vapor 1 in the combustion air 2, so that all of this heat can be coupled by means of the HD-Lubeco 13 and the LP Lubeco 14 in the boiler feed water.

The downstream in the flue gas flow flue gas cooler 20 may also couple the decoupled from the flue gas heat quantity in the boiler feed water.

With 21 a flue gas desulfurization system is called, this downstream can be a cooling tower 22, which serves primarily to cool the condensate from the condenser 7. In the cooling tower 22, a flue gas inlet from the flue gas desulfurization 21 take place.

LIST OF REFERENCE NUMBERS

1

vapors

2

combustion air

3

flue gas

4

steam generator

5

steam turbine

6

generator

7

capacitor

8th

Fluidized bed dryer

9

dust collector

10

fan

11

Air preheater (Luvo)

12

bypass line

13

High pressure air bypass economizer (HD-Lubeco)

14

Low Pressure Air Bypass Economizer (ND-Lubeco)

15

Flue gas cooler

16

Water / air preheater

17

Brüdenluftvorwärmer

18

Vapor

19

Brüdenluftvorwärmer

20

Flue gas cooler

21

flue gas desulphurisation

22

cooling tower

Claims (14)

Method for operating a steam turbine power plant with a lignite-fired steam generator, wherein the brown coal is first subjected to indirect drying, preferably in a fluidized bed dryer, wherein the fluidized bed dryer is at least partially heated with steam from the water-steam cycle of the steam generator, characterized in that the energy of the vapor arising from the drying of the lignite is at least partially used for preheating the combustion air. A method according to claim 1, characterized in that the coupling of the energy of the vapor into the combustion air by means of at least one heat exchanger takes place, which is connected upstream of a flue gas heated air preheater. Method according to one of claims 1 or 2, characterized in that the combustion air is additionally abandoned before the air preheater heat from the already partially cooled by the air preheater flue gas stream. A method according to claim 3, characterized in that the heat is decoupled from the flue gas behind the air preheater by means of a heat transfer medium. Method according to one of claims 1 or 2, characterized in that at least a partial stream of the vapor after deduction from the fluidized bed dryer is compressed in a vapor compressor and fed to at least one condensation heat exchanger. Method according to one of claims 1 to 5, characterized in that a partial flow of the flue gas is branched off in front of the air preheater and used to preheat the boiler feed water. A method according to claim 6, characterized in that as much flue gas is diverted in front of the air preheater, as corresponds to the injected from the vapor into the combustion air energy. Method according to one of the preceding claims, characterized in that the coupling of the energy of the vapor into the combustion air takes place in several stages, wherein at least a portion of the vapor is compressed in a vapor compressor and condensed in a condensation heat exchanger. Apparatus for producing steam, comprising at least one dryer for predrying lignite wet brown coal, at least one steam turbine downstream of the steam generator, at least one feedwater supply to the steam generator, at least one feedwater preheating device and at least one air preheater for the combustion air, characterized in that the air preheater is preceded by at least one heat exchanger which is connected to the vapor outlet of the dryer. Device according to claim 9, characterized in that the dryer is designed as a fluidized bed dryer. Device according to one of claims 9 or 10, characterized in that the guided to the air preheater flue gas line is provided with a bypass of the air preheater, which is connected to the feedwater preheating. Device according to one of claims 9 to 11, characterized in that at least one further flue gas cooler is provided in the flue gas stream behind the air preheater, which cooperates with the combustion air supply in front of the air preheater. Device according to one of claims 9 to 12, characterized by at least one vapor compressor, which is connected upstream of at least one condensation heat exchanger in the combustion air supply in front of the air preheater. Device according to one of claims 9 to 14, characterized in that the air preheater is designed as a regenerative air preheater.

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