DE19926918A1 - Steam boiler has combustion chamber, heat exchangers, front and back tower, and main body - Google Patents

Abstract

The steam boiler (1) has a combustion chamber (3) and several heat-exchanger packs (5). The steam boiler consists of a front (2) and back (4)tower containing the combustion chamber and heat-exchanger packs respectively, with at least one super-heater stage (6). The two towers are joined at their bottom end by a horizontal body. The flow direction (14) in the steam boiler is from the front tower,, from top to bottom, via the body (13) and to the rear body from the bottom upwards.

Description

TECHNICAL AREA

The invention is a steam boiler Steam power plant with a combustion chamber and several heat exchangers Packages.

STATE OF THE ART

Generally there are two different types of steam boilers for Steam power plants known. On the one hand there is the tower boiler. The Tower boiler consists of a single, very high tower. The burners which produce hot flue gas by burning a fuel, are located in the lower part of the tower. The hot flue gas flows in the tower at several heat exchanger packages (superheater, Reheater, economizer) over to the top. These heat exchangers Depending on the design of the steam power plant, packages can be made with different Pressure stages (superheater, medium-pressure reheater, Low pressure reheater). The superheater and  Intermediate superheater stages follow one another according to the height of the tower. At the top of the tower boiler before the flue gas leaves the tower usually arranged an economizer.

The classic two-pass boiler is also known. The two-pass boiler also consists of the components of a combustion chamber Heat exchanger packages with various superheater and Reheater stages and an economizer. The burner of the boiler are located in the lower part of the boiler. The hot flue gas flows upwards like the tower boiler, but it is divided into a second one redirected train directed below. On its way, the flue gas is sent to the different stages of the heat exchanger packages and on the economizer passed by. The two-train boiler is also different Superheater and reheater stages on the way of the flue gas arranged one after the other.

Both the tower boiler and the two-pass boiler have the Disadvantage that the steam lines, which connect the boiler with the Connect steam turbine are very long. This is due to the fact that the Superheater and reheater exits compared to the steam turbine in are arranged relatively high. Through the massive elaboration of the However, steam pipes are necessarily very expensive. This The disadvantage is particularly serious when high steam parameters (pressure, Temperature), so that high-alloy nickel steels are used have to.

PRESENTATION OF THE INVENTION

The aim of the invention is to overcome the disadvantages mentioned above and to construct a steam boiler which is characterized by a reduced height of the Steam leaks a reduction in the length of the steam lines, which the Connect the steam boiler to a steam turbine.

According to the invention, this is the case with a steam boiler of the preamble of Claim 1 achieved in that the steam boiler from two towers consists of a front tower and a rear tower, the front  Tower as the combustion chamber and the rear tower with the heat exchanger Packages with at least one superheater stage for the generation of Steam is equipped, the two towers over a hull are connected and the direction of flow in the boiler from the front Tower, from top to bottom, over the fuselage and to the rear tower, from bottom up, is.

An advantage of this invention is that the amount of steam exits compared to the height of the steam turbine and thus the length of the Steam lines reduced to a necessary minimum and so the costs be minimized. The reduced height of the boiler has another advantage with the fact that the boiler frame is also small, minimizing costs can be designed. Another advantage of the invention Steam boiler is that all end heat exchanger packages which are installed in the rear boiler to generate superheated steam, are arranged in parallel in the flue gas flow and separated by partitions are. This ensures a minimum outlet height for all end heat exchangers. Packages reached. This has the further advantage of being all available Superheater and reheater stages in the zone with the same high Flue gas temperature can be placed and temperatures of steam in all superheater stages independently of one another can be set / reached.

The other design options are the subject of the dependent Expectations.

BRIEF DESCRIPTION OF THE DRAWINGS

Show it

Fig. 1 is a schematic front view of a steam boiler according to the invention with a connected steam turbine and

Fig. 2 is a schematic horizontal section along the line II-II in Fig. 1 of a steam boiler according to the invention with a connected steam turbine.

Only the elements essential to the invention are shown. Same Elements are identified in the same way in different drawings.

WAY OF CARRYING OUT THE INVENTION

In Fig. 1 is a front view of an inventive steam boiler 1 is shown schematically. Such a steam boiler 1 is used in steam power plants to generate steam and usually consists of a combustion chamber in which a fuel is burned and a heat exchanger part in which the heat from the flue gas is transferred to water / steam.

The steam boiler 1 according to the invention consists of two towers 2 , 4 , a front tower 2 and a rear tower 4 , which are connected by a horizontally arranged fuselage 13 . The front tower 2 is equipped with a combustion chamber 3 , in which a fuel is burned in the usual way and not described here in detail. Only the input of a fuel / air mixture in the upper region of the front tower 2 is indicated schematically in FIG. 1.

The rear tower 4 is equipped with several heat exchanger packages 5 . An economizer 10 is arranged above the heat exchanger packages 5 in the upper region of the rear tower 4 . The heat exchanger packages 5 shown in FIG. 1 have different superheater stages 6 , 7 , 8 , which are, however, not visible in FIG. 1 and are explained in more detail in FIG. 2. These superheater stages 6 , 7 , 8 are separated from one another by partitions 9, also not shown in FIG. 1. Flaps 15 are installed in the upper area of the rear tower 4 , each regulating the volume flow of the flue gas in a channel created by the partition walls 9 . In FIG. 1 is also the direction of flow 14, which prevails in the steam boiler 1 shown. By a suction blower, which is not shown in Figure 1, a flow from top to bottom by the front tower 2 through the hull 13 and generated by the rear tower 4 from bottom to top, so that the combustion chamber 3 is first flowed through and hot flue gas is generated therein. The hot flue gas then passes through the fuselage 13 to the heat exchanger packages (superheater and reheater) 5 and the economizer 10 . It then leaves the steam boiler 1 through the flaps 15 . In FIG. 2, the superheater 6, reheater 7 and 8 are connected via final superheater steam lines 11 to a steam turbine 12. The steam turbine 12 is only shown schematically in FIG. 1.

FIG. 2 shows a hortizonal section II-II of FIG. 1 through the steam boiler 1 according to the invention. The front and rear towers 2 , 4 and the fuselage 13 are shown again . The heat exchanger packages 5 of the rear tower 4 contain different superheater stages 6 , 7 , 8 , which are separated from one another by partitions 9 . In FIG. 2, three superheater stages 6, 7, 8 are shown: a superheater stage 6, an intermediate-stage reheater 7 and a low-pressure reheater stage 8. These different stages overheat water vapor at different pressures. They are connected to the steam turbine 12 via the live steam lines 11 in such a way that the water vapor is introduced at various points in the steam turbine 12 in accordance with the pressure. In FIG. 2, a high-pressure 16, medium pressure 17 and a low pressure stage 18 is shown on the steam turbine 12.

The number of superheater stages 6 , 7 , 8 is only shown here by way of example and can vary. It depends on the design of the power plant and thus on the special application. The individual vertical flow channels, which are created by the partitions 9 in the rear tower 4 , are limited by the flaps 15 (shown in FIG. 1). The flaps 15 allow the volume flow of the flue gas in the flow channels of the rear tower 4 to be individually regulated in order to supply more or less flue gas and thus also more or less heat to a specific superheater stage.

The steam boiler 1 according to the invention constructed in this way has numerous advantages. Due to the construction in two towers 2 , 4 and the inverse flow guide, the boiler connections of the steam lines 11 , which connect the heat exchanger packages 5 and the steam turbine 12 , are located approximately at the height of the steam turbine 12 . This advantageously minimizes the length of the live steam lines in a cost-saving manner. Because all live steam collectors can be attached to the rear of the convectively heated tower 4 , the arrangement of the steam turbine 12 along the rear wall of the boiler results in particularly short steam lines 11 . The parallel arrangement of the various superheater stages 6 , 7 , 8 in the zone of the flue gas with the hottest temperature and the regulation of the volume flow of the flue gas in the flow channels of the rear tower 4 created by the partitions 9 have further advantages. It is improved in all stages of the superheater 6 , 7 , 8 to generate water vapor at a certain temperature and a certain pressure, since the superheater stages 6 , 7 , 8 no longer depend on one another, as is known from the prior art, and the supplied amount of heat can be controlled individually with a certain volume flow of the flue gas.

REFERENCE SIGN LIST

1

Steam boiler

2nd

Front tower

3rd

Combustion chamber

4th

Rear tower

5

Heat exchanger packages

6

Superheater stage

7

Reheater stage

8th

Reheater stage

9

Partitions

10th

Economizer

11

Steam pipes

12th

Steam turbine

13

hull

14

Flow direction

15

flap

16

High pressure stage of the steam turbine

12th

17th

Medium pressure stage of the steam turbine

12th

18th

Low pressure stage of the steam turbine

12th

Claims (5)

1. Steam boiler ( 1 ) of a steam power plant with a combustion chamber ( 3 ) and several heat exchanger packages ( 5 ), characterized in that

• - The steam boiler ( 1 ) consists of two towers ( 2 , 4 ), a front tower ( 2 ) and a rear tower ( 4 ), the front tower ( 2 ) as a combustion chamber ( 3 ) and the rear tower ( 4 ) with the heat exchanger packages ( 5 ) are equipped with at least one superheater stage ( 6 ) for generating water vapor,
• - The two towers ( 2 , 4 ) are connected at their lower end via a horizontally arranged hull ( 13 ) and
• - The direction of flow ( 14 ) in the steam boiler ( 1 ) from the front tower ( 2 ), from top to bottom, over the fuselage ( 13 ) and to the rear tower ( 4 ), from bottom to top.

2. Steam boiler ( 1 ) according to claim 1, characterized in that the heat exchanger packages ( 5 ) of the rear tower ( 4 ) consist of at least two superheater stages, namely a superheater stage ( 6 ) and at least one intermediate superheater stage ( 7 , 8 ). 3. Steam boiler ( 1 ) according to claim 2, characterized in that the superheaters / reheaters ( 6 , 7 , 8 ) of the rear tower ( 4 ) are arranged in parallel next to one another and are separated from one another by partition walls ( 9 ). 4. Steam boiler ( 1 ) according to claim 3, characterized in that the side by side by partitions ( 9 ) separated superheater / reheater ( 6 , 7 , 8 ) at the upper end of the rear tower ( 4 ) equipped with the volume flow regulating flaps ( 15 ) are. 5. Steam boiler ( 1 ) according to claim 3, characterized in that the rear tower ( 4 ) has an economizer ( 10 ) in the upper region after the heat exchanger packages ( 5 ).