DE19612186A1 - Method of drying crude lignite, with fluidised bed dryer - Google Patents

Abstract

The precrushed crude lignite is exposed to fluidised bed drying, and vapour is extracted. Part, in compacted form, is used for the indirect heat of drying and condensed; the other part is returned in eddy form to the fluidised bed dryer, where the condensate resulting from the indirect heating is cooled. Bleeder steam (9,9') is used for the indirect heating of the fluidised bed drying (24). The vapour condensate (17) extracted from the indirect heating is cooled by heat exchange (19) with water from the water-steam circulation of the steam turbine power unit process.

Description

The invention relates to a method for drying raw lignite, in which the possibly pre-comminuted raw lignite one Fluid bed drying undergoes from the fluid bed drying drawn vapors are dedusted, a subset of the dedusted vapors compacted for indirect heating of the drying and used be condensed and another subset of the vapors into the Fluid bed drying can be returned as a fluidizing medium and in the the vapor condensate drawn off from the indirect heating is cooled.

From DE-Z "brown coal" 6/1994, pp. 4-11 and from DE 36 44 806 C2 such a method is known in which the vapor condensate for preheating the possibly pre-shredded raw lignite before it is fed into the Fluid bed dryer is used. This will make the drying process in addition, part of the heat contained in the vapor condensate is supplied. The coal preheater developed for preheating is a large volume and thus relatively expensive component. Because of the large amount of space required Conveyors for feeding the brown coal preheater and the conveyors for Entry of the preheated coal into the fluidized bed dryer for a larger one Height must be designed and / or the bunkers and the outside coaling must be put on a higher level. The generic method with Vapor compression and utilization of the vapor condensate for preheating raw lignite is known as the WTA process.

The so-called DWT process was also used to dry raw lignite developed in which the brown coal in an indirectly heated  Fluid bed dryer is dried. The heating is done by Heat exchanger internals in fluidized bed drying, that of heating steam are flowed through, which condenses in the built-in heating surfaces. The The bed is also fluidized by a part of the DWT process the expelled vapors, which are recirculated by a circulation fan. The main stream of vapors is condensed in a vapor condenser which e.g. B. can be part of a heating network.

It is the object of the present invention, a generic Specify a process in which, on the one hand, the coal preheater in failure can come and on the other hand that still contained in the vapor condensate Heat can be exploited.

This object is achieved in that when the Drying process in a steam turbine power plant process in addition to compressed vapors steam for indirect heating of the Fluid bed drying is used and the cooling of the indirect Heating of the vapor condensate removed by heat exchange with water from the water-steam cycle of the steam turbine power plant process he follows.

According to the invention is applied by the compressed vapors Drying heat supplemented by the heat of the tap steam, d. H. the Balance is achieved by continuously adding heating steam from the Steam turbine process closed. Under tap steam is in the the following description and in the claims understood a steam, either directly from the steam turbine or from a steam rail of the Power plant has been removed, in other words: there will be steam fed to the steam turbine process.

The use of the sensible heat in the vapor condensate at the dryer outlet takes place through their transfer into the water-steam cycle.

The compressed vapors and the bleed steam preferably flow separate heat exchanger internals in the fluidized bed drying, so that Tap steam condensate can be used separately from the vapor condensate can.  

But it is also conceivable that a mixture of vapor and tapping steam the same heat exchanger internals in fluidized bed drying flows through.

When using a vapor-steam mixture, it makes sense to use sliding tapping the tapping steam with already compressed vapors Mix.

When tapping the tap steam, however, it is advisable to in Depending on the load, the bleed steam with not yet compressed or to mix with condensed vapors.

The vapor condensate is preferably cooled in one Low pressure preheater of the water-steam circuit connected in parallel Vapor condensate cooler.

However, it is also conceivable that the cooling of the vapor condensate at least one in line with at least one low pressure preheater switched vapor condensate cooler.

When separate heat exchanger internals are supplied with bleed steam the tapped steam condensate can be fed into a feed water tank or it becomes the main condensate stream of the water-steam cycle fed.

The vapor compression and the build-up of the delivery pressure for the delivery of the fluidizing medium for fluidized bed drying can take place in parallel.

However, it is also possible to first apply a vapor stream to the delivery pressure bring for the promotion of the vortex medium and then a partial flow of this to compress for heating.

The invention is also directed to a plant for drying Raw lignite according to claims 13-15, which is used to carry out the method according to the invention is suitable.  

The invention will now be explained in more detail with reference to the accompanying figures. Show it:

Fig. 1 is a process with separate guide and a Wärmtauschereinbauten Brüdenkondensatkühler in parallel to a low-pressure,

Fig. 2 shows a process procedure similar to Fig. 1 with recycling of the Anzapfdampfkondensats in a feedwater tank,

Fig. 3 shows a process procedure similar to Fig. 1 associated with recycling of the Anzapfdampfkondensats into a low-pressure condensate cooler,

Fig. 4 shows a process with a multistage Brüdenkon condensate cooler, which is in the main condensate stream, and

Fig. 5 shows a process in which bleed steam and compressed vapors in a mixture flow through the same heat exchanger internals in the fluidized bed dryer.

Referring to FIG. 1, the drying unit 1 is associated with a steam turbine power plant 2, which is operated with the dried brown coal TBK. For the sake of simplicity, only one condensate pump 3 , two low-pressure preheaters 4 and 5 connected in series, a medium-pressure turbine 6 and a low-pressure turbine 7 are shown on the same shaft for the sake of simplicity. The low-pressure preheater 4 is supplied with tapped steam from the low-pressure turbine 7 and the low-pressure preheater 5 from a line 9 with tapped steam from the medium-pressure turbine 6 via a tap line 8 .

Raw lignite RBK is fed to the fluidized bed dryer 10 of the drying plant 1 via line 11 . When the system is operating, the vapors B are fed via line 12 to a fine dust separator 13 (for example an electrostatic filter or bag filter), in which dust-like dry brown coal STBK is separated. After the fine dust separator, a subset of the vapors is compressed via a line 14 , in which a vapor compressor 15 is located, and heat exchanger internals 16 are fed in, in which the compressed vapors condense, giving off their heat to the raw lignite located in the fluidized bed dryer. The condensate is drawn off via line 17 and - as indicated at 18 - degassed. The degassed condensate is fed to a vapor condensate cooler 19 and subcooled vapor condensate is removed therefrom. The vapor condensate cooler is connected in parallel with the first low-pressure preheater 4 by means of a condensate line 20 .

It is possible to feed a portion of the vapor condensate via line 21 into the vapor compressor 15 or into the line 14 after the vapor compressor.

Another dedusted vapor partial stream is fed via line 22 by means of a circulation blower 22 'arranged therein to a fluidization device 23 in the fluidized bed dryer.

In the fluid bed dryer further heat exchanger internals 24 are arranged, which are applied from line 9 via a line 9 'zoom out bleeder steam. The steam condensed in the heat exchanger internals 24 is fed via line 25 with condensate pump 26 into the main condensate line 27 , in which the two low-pressure preheaters 4 and 5 are arranged. The feed preferably takes place between the two low-pressure preheaters 4 and 5 .

From the line 25 , part of the condensate can be injected via line 28 into the bleed steam line 9 'branched off from line 9 in order to effect steam conditioning.

As mentioned in the introduction, it is also possible to use a Circulation blower between fine dust separator and the branch point to arrange and the circulation blower a vapor compressor to connect.

In the process procedure shown in FIG. 2, the recirculation of the condensate from the heat exchanger 24 is performed without internals condensate pump in a feedwater tank 29, which is fed via the line 9 bled steam from the intermediate pressure turbine 6. Only a low-pressure preheater 4 is shown, which is heated by the low-pressure turbine via line 8 . Pre-heated water drawn off from the feed water tank 29 is fed via line 30 to the high-pressure preheaters, not shown.

In the process procedure shown in FIG. 3 to the low-pressure economizer 5 is assigned a condensate cooler 31, through which flows the main condensate. The condensate cooler 31 is acted upon by the condensate from the heat exchanger internals 24 which is introduced via line 25 . The condensate, which has given up its heat, then flows out via line 32 to the low-pressure preheater 4 .

In the process procedure shown in FIG. 4, the vapor condensate from the heat exchanger internals 16 flows after degassing in a first Brüdenkondensatkühler 33, then via line 34 to a second condensate cooler 35 and is then discharged as a sub-cooled vapor condensate. In the main condensate line 27 there is a first low-pressure preheater 36 on the pressure side of the condensate pump 3 , then the vapor condensate cooler 35 , another low-pressure preheater 37 and then the vapor condensate cooler 33 and then the low-pressure preheater 5 acted on by line 9 with bleed steam from the medium-pressure turbine 6 . The low-pressure preheaters 36 and 37 are supplied with tap steam of different tap levels from the low-pressure turbine 7 via lines 38 and 39 , respectively.

In the process procedure shown in FIG. 5, in deviation from the process control according to Fig. 1 of the 'branched off for heating the fluidized bed dryer 10 from the line 9 via line 9 steam does not separate heat exchanger baffles 24, but heat exchanger internals 40 fed, under interference in the Line 14 on the pressure side of the vapor compressor 15 . The mixed condensate from the heat exchanger internals 40 is cooled as in the process according to FIG. 1.

The broken-line bleed line 41 and the broken-line line 42 are intended to indicate that in the case of a fixed bleed it makes sense to admix the bleed steam introduced at low loads upstream of the vapor compressor 15 and at higher loads on the pressure side of the vapor compressor 15 in order to provide protection against Build up excess pressure. The valves required for this are not shown in FIG. 5 for the sake of simplicity.

The vapor losses occurring in the process are indicated by 12 'in the figures. The majority of the dried lignite TBK is withdrawn from the fluidized bed dryer 10 , as is shown schematically in the figures.

Claims (15)

1. A process for drying raw lignite, in which the possibly pre-comminuted raw lignite is subjected to fluidized-bed drying, vapors drawn off from the fluidized-bed drying are dedusted, a partial amount of the dedusted vapors are used for indirect heating of the drying and are condensed and another partial amount of the vapors be returned to the fluidized bed drying as a fluidizing medium and in which the vapor condensate drawn off from the indirect heating is cooled, characterized in that, in addition to the compressed vapor ( 15, 14 ,) when the drying process is incorporated into a steam turbine power plant process ( 3 , 4 , 5 , 6 , 7 ) ) Tap steam ( 9 , 9 ') for the indirect heating of the fluidized bed drying ( 24 ; 40 ) is used and the cooling of the vapor condensate ( 17 ) drawn off from the indirect heating by heat exchange ( 19 ; 33 , 35 ) with water from the water vapor Cycle of Steam turbine power plant process takes place. 2. The method according to claim 1, characterized in that the compressed vapors ( 17 ) and the bleed steam ( 9 ') flow through separate heat exchanger internals ( 16 ; 24 ) in the fluidized bed drying ( 10 ) so that the bleed steam condensate ( 25 ) separated from the vapor condensate ( 17 ) can be used. 3. The method according to claim 1, characterized in that a mixture of vapor ( 14 ) and bleed steam ( 9 ') flows through the same heat exchanger internals ( 40 ) in the fluidized bed drying. 4. The method according to any one of claims 1-3, characterized in that with sliding tapping the Tapping steam is mixed with already compressed vapors. 5. The method according to at least one of claims 1-3, characterized in that when tapping the Tap steam depending on the load of tap steam with still is not compressed or mixed with compressed vapors. 6. The method according to at least one of claims 1-5, characterized in that the cooling of the vapor condensate ( 17 ) in a low pressure preheater ( 4 ) of the water-steam circuit connected in parallel vapor condensate cooler ( 19 ). 7. The method according to at least one of claims 1-5, characterized in that the cooling of the vapor condensate ( 17 ) in at least one in series with at least one low pressure preheater ( 36 ; 37 ) connected vapor condensate cooler ( 33 ; 35 ). 8. The method according to at least one of claims 1-7, characterized in that when separate heat exchanger internals ( 24 ) with tap steam ( 9 '), the tap steam condensate ( 25 ) is guided into a feed water tank ( 29 ). 9. The method according to at least one of claims 1-7, characterized in that when separate heat exchanger internals ( 24 ) with tap steam ( 9 '), the tap steam condensate ( 25 ) is fed to the main condensate stream ( 27 ) of the water-steam circuit. 10. The method according to at least one of claims 1-9, characterized in that the vapor compression ( 15 ) and the build-up of the delivery pressure ( 22 ') for the promotion of the fluidizing medium for fluidized bed drying ( 10 ) takes place in parallel. 11. The method according to at least one of claims 1-9, characterized in that first a vapor stream is brought to the delivery pressure ( 22 ') for the promotion of the fluidizing medium and then a partial stream thereof is compressed for heating. 12. The method according to at least one of claims 1-11, characterized in that as bleed steam Turbine tapping steam or steam from a steam rail of the Steam turbine process is used. 13. Plant for drying raw lignite with a fluidized bed dryer including heat exchanger internals through which a heating medium flows to transfer heat to the raw coal with condensation of the heating medium and a fluidizing device for fluidizing the coal, with a dedusting device downstream of the fluidized bed dryer, one downstream of the dedusting device and with the heat exchanger internals associated vapor compressor, with a vapor for fluidization demanding fan and a connected to the condensate removal of the heat exchanger internals Brüdenkondensatkühler, characterized in that, with involvement of the drying process in a steam turbine power plant additionally bled (9 ') heat exchange baffles (24; 40) in the fluidized bed dryer (10) can be supplied and the vapor condensate cooler is a cooler ( 19 ; 33 , 35 ) which is switched into the water-steam circuit. 14. Plant according to claim 13, characterized in that in the fluidized bed dryer ( 10 ) separate heat exchanger internals ( 16 , 24 ) are arranged, of which one ( 16 ) with compressed vapors ( 14 ) and the other ( 24 ) with bleed steam ( 9 ') Are acted upon. 15. Plant according to claim 13, characterized in that in the fluidized bed dryer ( 10 ) heat exchanger internals ( 40 ) are arranged which can be acted upon with a mixture of compressed vapors ( 14 ) and bleed steam ( 9 ').