DE4327476A1 - Method for operating a fossil-fuel-fired steam generator and steam-generating plant for carrying out the method - Google Patents

Abstract

In a method for operating a fossil-fuel-fired steam generator with heating of air, employed as combustion air, by the waste gases of the steam generator and preheating of the feed-water for the steam generator by exhaust or intermediate steam, it is proposed according to the invention, in order to reduce the waste-gas losses, in particular in the case of brown-coal-fired boilers, that heat from air heated in addition to the combustion air by the waste gases of the steam generator be transmitted to the feed-water, the additional air being heated together with the combustion air or separately from it. <IMAGE>

Description

The invention relates to a method for operating a fossil fuel fired steam generator with Heating of air used as combustion air by the exhaust gases from the steam generator and preheating the Feed water for the steam generator by waste or Intermediate steam.

In conventional steam generators, the exhaust gas Fresh air heat exchanger, which is generally the is the last secondary heating surface on the exhaust gas side, the heating the amount of air required for combustion. The for the The amount of air required for combustion is not sufficient in all Cases from which the flue gases on the through the Preset sulfur dew point or water dew point Cooling limit temperature, so that a correspondingly high Exhaust gas loss is generated.

A steam generator with air preheating is shown in Figure 1 of the Essay "Special features of the thermal calculation of heat recovery steam generators "from DE-Z VGB Kraftwerkstechnik 72 (1992), No. 1, pages 29-32 known. The steam generation plant created there points not just one fueled with fossil fuels  Main steam generator, but also one one Gas turbine downstream heat recovery steam generator, the last heating surface on the flue gas side serves to Pre-warm feedwater preheater strand, where the heating surface in the steam generator of an LP preheating stage is connected in parallel.

It is also known (see yearbook of Dampferzeugungstechnik Band 1, 5th edition, 1985/86, pages 471-472), air preheater with hot air return too operate, with some of the heated in the air preheater Air does not burn the combustion chamber of the Steam generator fed, but to the input of the Air preheater recycled upstream fresh fan is there to increase the temperature of the fresh air drawn in increase.

It is the object of the present invention generic method so that the Exhaust gas losses, especially with those fired with brown coal Boilers, be reduced.

This object is achieved in that heat from additional to the combustion air through the exhaust gases from the steam generator heated air is transferred to the feed water, whereby the additional air together with the combustion air or heated separately from it.

The flue gas therefore causes a larger amount of air than that Air required for combustion heated so that the Heat of the steam generator exhaust gas is essentially complete can be exploited.

After the transfer of heat to the feed water can at least part of the additional air as hot air be returned. However, it is also possible that the by transferring heat to the feed water  completely or partially cooled additional air to the Environment is dissipated.

If the feed water preheating in a manner known per se into an LP feed water preheating and a subsequent HD Feed water preheating is divided, it makes sense but also more expensive in terms of equipment, as much heat as possible from the heated air to the feed water in the area of Transfer HD feed water preheating because it is so precious Steam taps on the downstream of the steam generator Steam turbine can be reduced. Apparently less It is expensive when heat from the heated additional Transfer air in the area of LP feed water preheating becomes. It is also conceivable - and in the description of the figures shown -, heat both in the area of HD Feed water preheating as well as in the area of LP To transfer feed water preheating.

It is not only possible that flue gas is close to or to cool down to sulfur dew point, but also to the Water dew point if the appropriate Flue gas duct areas are protected against corrosion by z. B. rubberized flue gas ducts are used behind the e-filter. The common heating of the combustion air and the Additional air then takes place in two stages, with the exhaust gas preferably after in the flow direction of the exhaust gas seen the first heat exchanger stage is dedusted.

The HP and / or LP feed water preheating with steam usually takes place in several stages. It is then preferred provided that the transfer of heat from the heated Air in the feed water in series with at least a steam-heated preheating stage or in parallel at least one steam-heated preheating stage.

The invention is also directed to a Steam generating plant with a steam generator, at least an air downstream of the steam generator  Steam generator exhaust gas heat exchanger for heating over a fresh fan brought in fresh air and one Strand for preheating the steam generator Feed water.

According to the invention it is provided that Feed water preheating line at least one air-water Heat exchanger is arranged, which is in an air Steam generator exhaust gas heat exchanger of heated air is acted upon.

Further sub-claims are directed to preferred ones Embodiments of the invention Steam generating plant.

Several embodiments of the method according to the invention and the steam generating plant according to the invention should now will be explained in more detail with reference to the accompanying figures. Show it:

Fig. 1 is a system for joint heating of the combustion air and the additional air and

Fig. 2 shows a system for separate heating of the combustion air and the additional air.

A steam generator 1 is fired with brown coal 2 . The steam generator exhaust gas 3 flows through an air preheater 4 , which is preferably designed as a rotary heat exchanger, and is then dedusted in an electrostatic filter 5 . Fresh air 6 is fed to the air preheater via a fresh fan 7 and heated therein. A partial flow 6 a of the heated fresh air is fed to the steam generator 1 as combustion air.

The feed water 8 (condensate from the steam turbine, not shown) is fed to the steam generator 1 and initially subjected to a multi-stage LP preheating 9 . The preheating takes place in a steam-heated preheater 10 , an air preheater 11 and a steam-heated preheater 12 . The feed water preheated in this way is fed to a mixing preheater 13 , which also serves as a feed water container, and is subjected to a multi-stage HP preheating 15 with a steam-heated preheater 16 , an air preheater 10 and a subsequent steam-heated preheater 18 by means of a feed water pump 14 . In the embodiment shown, the air-feed water heat exchangers are in series with the steam-heated preheaters. However, it is also possible to connect them in parallel to steam-heated preheaters, e.g. B. to switch the air-water heat exchanger in the LP line parallel to the second steam-heated preheater. The two air-supply water heat exchanger 17 and 11 are successively from the part stream 6 b of the light exiting the air preheater 4 airflow 6 applied. After the heat has been given off, the cooled air stream 6 b can be released into the environment in whole or in part, depending on the position of the flaps 19 and 20 , or can be returned in whole or in part as hot air to the intake side of the fresh fan 7 . In a conventional boiler fired with brown coal, in which the fresh air flow 6 is only the size of the partial flow 6 a, z. B. the temperature of the incoming exhaust gas at 336 ° C behind the air preheater 4 at 170 ° C, although z. B. the flue gas temperature in the air preheater specified by the sulfur dew point is approx. 150 ° C. A boiler efficiency corresponding to 17 ° K flue gas temperature is therefore not used here. Due to the increased air exposure of the air preheater to the partial flow 6 b, the flue gas 3 can be extracted from heat corresponding to at least part of this temperature difference and transferred to the feed water, so that the exhaust gas leaves the air preheater at approximately 150 ° C. and the boiler efficiency is increased.

If cooling down to the vicinity of the water dew point is desired, the second air preheater 21 shown in FIG. 1 can be used, which is connected downstream of the e-filter 5 on the flue gas side and upstream of the air preheater 4 on the air side.

In the embodiment shown in FIG. 2, the combustion air required for the combustion is heated only in the air preheater 4 , while the additional air is heated in an air preheater 22 , which in turn is connected downstream of the air preheater 4 or the e-filter 5 , on the air side, however, is arranged in a separate air duct 23 , which in turn can preferably be at least partially configured as a circuit. For this reason, the flaps 19 and 20 have been retained in FIG .

The air preheater 11 is switched on in this air duct 23 and in the LP preheater duct 9 . In the embodiment shown, an additional HP feed water preheater 24 is switched on in the HP preheating line 15 , if this is necessary. A separate blower 25 is provided for supplying air to the preheater 22 separately from the fresh fan 7 . The arrangement according to FIG. 2 is particularly suitable for retrofitting existing steam generator systems, the air preheater 4 of which is designed only for the amount of combustion air required.

In addition to the control valves and are any other necessary Control and measuring devices not shown, because their Arrangement and its operation in the context of professional action lie.

Claims (14)

1. A method for operating a fossil fuel-fired steam generator with heating air used as combustion air by the exhaust gases of the steam generator and preheating the feed water for the steam generator by exhaust or intermediate steam, characterized in that heat from in addition to the combustion air by the exhaust gases of the steam generator heated air is transferred to the feed water, the additional air being heated together with the combustion air or separately from it. 2. The method according to claim 1, characterized, that after the transfer of heat to the feed water at least part of the additional air as hot air is returned. 3. The method according to claim 1 or 2, characterized, that by the transfer of heat to the Feed water cooled additional air entirely or is partially discharged to the environment. 4. The method according to at least one of claims 1-3, characterized, that heat from the heated additional air  Feed water in the area of HD feed water preheating is transmitted. 5. The method according to at least one of claims 1-4, characterized, that heat from the heated additional air in Range of LP feed water preheating is transferred. 6. The method according to at least one of claims 1-5, characterized, that the common warming of the air in two stages he follows. 7. The method according to at least one of claims 1-6, characterized, that the HD and / or the LP feed water preheating takes place in several stages and the transfer of heat from of the heated air into the feed water in series with at least one steam-heated preheating stage or parallel to at least one steam-heated Preheating takes place. 8. Steam generator system with a steam generator, with the steam generator downstream air-steam generator exhaust gas heat exchanger for heating fresh air supplied via a fresh fan and a line for preheating the feed water to be supplied to the steam generator, in particular for carrying out the method according to at least one of claims 1-7 , characterized in that in the feed water preheating line ( 9 ; 15 ) at least one air-water heat exchanger ( 11 ; 17 ) is arranged, which can be acted upon by air heated in an air-steam generator exhaust gas heat exchanger ( 4 ; 21 ; 22 ). 9. Steam generator system according to claim 8, characterized in that the air-steam generator exhaust gas heat exchanger ( 11 ; 17 ; 22 ) and the fresh fan ( 7 ) is associated with a hot air return ( 6 b, 20 ; 23 , 25 ) and that the air - Water heat exchanger ( 17 ; 11 ) in the hot air return ( 6 b; 23 ) is arranged. 10. Steam generation system according to claim 8 or 9, characterized in that an air-water heat exchanger ( 15 ) is arranged in the HP preheating line. 11. Steam generation system according to at least one of claims 8-11, characterized in that an air-water heat exchanger ( 11 ) is arranged in the LP preheating line ( 9 ). 12. Steam generation system according to at least one of claims 8-11, characterized in that the air-flue gas heat exchanger ( 4 ) on the flue gas side, an E-filter ( 5 ) and a further air-flue gas heat exchanger ( 21 ; 22 ) are connected downstream. 13. Steam generation system according to at least one of claims 8-12, characterized in that the further air-exhaust gas heat exchanger ( 21 ) is connected upstream of the first air-exhaust gas heat exchanger air ( 4 ) on the air side. 14. Steam generation system according to at least one of claims 8-12, characterized in that the further air-exhaust gas heat exchanger ( 22 ) is arranged on the air side in a separate air duct ( 23 , 25 ).