DE202017106122U1 - Separation system of a flue gas desulphurisation plant of a ship - Google Patents

Abstract

Separation system (100) of a flue gas desulphurisation system of a ship for separating drops (11) from a flue gas which flows in a flow direction (R) and preferably through a vertical outlet (10) of a chimney (S), preferably with a vertically upward flow component .
with at least one lamella (1) which is elongate in a longitudinal direction (L) and whose longitudinal direction (L) is oriented transversely or obliquely to the flow direction (R),
the lamella (1) comprising at least one chamber (2) with an opening (2a) extending in the longitudinal direction (L),
wherein in each case the opening (2a) on one of the flow direction (R) facing side of the lamella (1) is arranged.

Description

The invention relates to a separation system of a flue gas desulphurisation plant of a ship. On the one hand, this separation system should ensure that ships equipped with this system meet the requirements of the new emission regulations at sea. On the other hand, this separation system should overcome the known problem of chimney rain (heavy drop ejection from a wet chimney). In addition, this separation system, taking into account the operational experience of recent decades, the pollution of the droplet (the flue gas flow direction) following components reduce, if possible minimize.

Flue gases from diesel-fueled marine engines are desulphurized predominantly by the wet scrubbing process for exit from a chimney. For this purpose, the sulfur-containing flue gas is passed through a container which is located in the flue gas flow direction in front of the chimney. In this container, the sulfur-containing flue gas is sprayed with seawater (suspension solution) and the SO _{2 contained} in the flue gas bound in the spray droplets of this suspension solution. While, in particular, the larger spray droplets, due to gravity, collect in a sump arranged below the inlet to wastewater, which can be purified in further process steps, smaller of these spray droplets are entrained by the gas stream.

It is an object of the invention to reduce the amount of entrained drops.

Since the new valid or planned emission regulations provide for a considerable reduction of the solids content in the flue gas, in other words a reduction of fine dust, it is a further object of the invention to improve the separation efficiency.

State of the art

Modern separation systems for flue gas desulphurisation are today installed in the upper area (also called "laundry head") of a container to which flue gas ducts or a chimney connect in the flue gas flow direction. These separation systems are regularly subjected to a vertically upward flowing flue gas. It has been found that this arrangement is the preferred configuration for both cost and operational reasons.

The separation system separates the droplets and optionally also dry solids from the flue gas stream, in which it deflects the latter several times in the separation system by means of flow resistances. The drops and the dry solids are exposed to centrifugal forces. You can not follow the flue gas in its path, but bounce on the flow resistance, which cause the diversion of the flue gas flow and also referred to as a "baffle". The drops are thereby deposited on these baffles and thus removed from the flue gas stream. Due to gravity, the drops and optionally also the solids fall down into the container and thereby pass back into the gas stream or into the sump.

In the prior art, the separation systems regularly comprise packages of plate-like and bent deflecting bodies. These regularly rigidly suspended diverters are usually configured so that channels are formed, through which the flue gas flows. The aim of this configuration is, on the one hand, to cause a strong diversion of the flue gas and, on the other hand, to minimize "obstruction" of the flue gas path due to flow resistance.

The baffles or deflection bodies are generally also called "lamellas", the impact bodies correspond to "lamellar separators" or else only "lamellas". The common slats of the different manufacturers differ in terms of geometry, the slat spacings, the deflection and the design ("roof", "flat" or "horizontal").

It is an experience from conventional power plants that a so-called chimney rain can occur when the flue gases are directed into the chimney after the flue gas desulphurisation plant (REA). This chimney rain consists of large drops with considerable solids content (ash) and is acidic (slight acidity). It is, on the one hand, a consequence of the condensation of droplets from the saturated flue gas, which cools on the way through the chimney and is reflected in the chimney walls. There they are demolished by the flue gas flow and discharged from the chimney.

To avoid this, it is known in power plants to use a reheating. This heats the flue gas and thereby evaporates residual droplets in the flue gas and avoids condensations of the saturated gas.

On the other hand, the chimney rain is also caused by a breakthrough from the separation system. Cracking means that the droplets leave the separation system downstream, either because the separation system is not working (contamination, incorrect configuration or excessive Flue gas velocity), or because the washing of lamellae creates a break through of washing drops and breaks through the separation system.

In the case of diesel-powered marine engines, the drops of chimney rain on the one hand are rather acidic, as sulfuric acid is in them, on the other hand, these drops have a high solids content. The sulfuric acid comes from the combustion process in the diesel engine. Sulfur-containing diesel was burned and, accordingly, the content of SO ₂ and some SO ₃ in the flue gas is relatively high. The liquid is a dilute sulfuric acid and accordingly highly aggressive and corrosive. The solid, since the accumulated solids enter the liquid during washing and then run off in the majority, is also entrained to a small extent. On the one hand, these drops, which then fly out of the chimney and enter the environment, lead to clearly visible contamination on the ship's walls and surfaces. On the other hand, the drops are so sour and aggressive that they decompose and corrode the ship's paint and then steel. Both effects are negative for the ship. Pollution is very negative and disturbing especially on ships with passenger traffic. Worse still, the corrosive and corrosive effects of dilute sulfuric acid are feared on ships.

Acid chimney rain is therefore negative and dangerous for the ship.

It could be shown in experiments that the strength of the chimney rain largely depends on the washing cycles of the lamellae and in particular on the washing of the lamellae last in the direction of the flue gas flow. It could be determined that switching off this washing system meant that the previous strong chimney rain fell to a barely perceptible level.

This finding is also in accordance with the measurements of the crack behind the slats. It was found that during washing, the last fins in the flue gas flow direction ruptured up to 100 times the amount of liquid, compared to operation without washing. In particular, it was also found that the size of the drops increased significantly during washing. It was particularly large drops carried away.

The effect on the chimney rain can thus be explained both by the cleaning of the liquid volume and by the size of the drops. Small drops that either break through the separator system during normal operation (without washing) or small drops (which are formed by condensation in the chimney) do not occur as chimney rain, because they usually evaporate before they reach the bottom. On the other hand, large drops, either produced by washing the slats or by condensation on the chimney, are large enough to reach the bottom. They rain down on the surfaces below or behind the chimney, where they lead to corrosion due to their acidity and contamination due to the solids bound.

In addition, the drops fall during washing because of their amount and are therefore perceived. Individual drops are ignored and not perceived. Large drops are noticeable.

Analysis of the operating situation

The connection between the process of washing the slats and the occurrence of the chimney rain was not recognized for a long time. The occurrence of chimney rain was attributed to a "bad" deposition and fought as such. In many cases, a "bad" separation was in part the cause of the occurrence of chimney rain. Dewatering systems are sometimes performed so poorly or operated so unfavorably that they only partially work and cause significant emissions.

An important reason for the poor separation efficiency is the frequent contamination of the lamellae. This pollution is caused in particular by poor combustion of the diesel oils in the machines. It oily constituents are not burned and carried as oily soot or Öltröpfen with the flue gas. You can then precipitate on the lamellar surfaces and oil them.

A oily slat, however, only works very limited. The oil prevents the build-up of a water film on the lamellar surface. However, this film of water is very important because it absorbs and binds the approaching drops. On the other hand, if the drop to be deposited hits a surface which has become oily, it will burst and be thrown back into the flue gas stream, instead of being deposited in the water film or on the surface of the lamella. It creates so-called secondary spray. The just deposited drops are thus thrown back into the flue gas and continue to fly.

So an oily contamination leads to the fact that the corresponding lamella does not work properly anymore. The drops are distributed but not separated.

Another important aspect is that the space available on many ships to install a REA is very limited. On a ship, everything is very crowded - all space is reserved for cargo or passengers and the necessary functions are realized in a minimum of space.

task

It is an object of the invention to provide a separation system that minimizes the impact of the drops on surfaces to effect deposition. It is a further object of the invention to provide a separation system in which, on the other hand, the lamellae can be regularly pulled and cleaned during operation. In addition, the configuration of the separation system should preferably be such that only a minimum of space is used and that the amount of chimney rain is reduced and minimized as far as possible to an unavoidable level.

A precipitator, whose effect is based on the impact of the drops - a baffle or a lamella - will also quickly accumulate oily components on the surface under the given ambient conditions, which then prevent the build-up of an approaching drop of absorbing water film. This significantly affects the separation function. The basic principle of the impact drop is (as already mentioned) that form water films on the baffles, which ensure that the drops do not sputter on impact and continue to fly as a reduced spray, but that the amount of liquid drops absorbed by the water film and is bound - if possible without the secondary spray. A lubricated separator can not train this water film, it does not work because of that. So it must be found an alternative solution that makes the water film is no longer necessary. If the spraying drops then spray, this must be done in a preferably pressure-reduced or even unpressurized room so that the secondary drops are not re-entered into the gas flow.

These baffles or lamellae should preferably be easy to pull and ideally also during operation, so that they can be exchanged and / or cleaned. By this cleaning, the oiling can be reduced and preferably also kept at about a minimum value. Therefore, the negative influence of the oil reduction for the deposition can be reduced and, ideally, reduced to a minimum.

The replacement of the fins should preferably be done during operation in order to avoid downtime of the diesel engine can. The cleaning of the slats can then take place offline. In this case, the separation system is preferably to be designed so that this replacement can be carried out without risk to the personnel during operation.

It is also an object of the invention to keep the REA as small as possible. Small means in this case that the height of the entire system is minimized. The height of ships is limited, and the chimney can not protrude arbitrarily high out of the ship. It is therefore necessary to keep the height necessary for the separation system as small as possible, preferably to minimize.

Finally, the problem of chimney rain should be minimized. The formation of drops of dilute sulfuric acid, which can lead to chimney rain, is - as already explained - the result of the installation of a REA. The chimney rain has essentially the following three causes:

Malfunction of the slats

When a slat stops working properly, more and more liquid is carried into the chimney and ejected. A bad or a oily slat are therefore a source of chimney rain.

Washing the slats

A lamella must be washed regularly to remove fine ash or other solids that, on the one hand, clog the separation system over time and, on the other hand, form deposits on the lamellae which progressively worsen deposition. The washing, however, leads in the side effect to a short-term considerable ejection of liquid in the form of chimney rain.

condensation layer

The clean gas that arises after passing through the REA is known to be a saturated gas with a high temperature, for example, 50 ° C to 65 ° C. Even in a very short compared to power ship chimney it comes to the chimney walls to condensate because the chimney wall regularly 20 ° C to 50 ° C colder than the flue gas. The condensate is - if a sufficient amount of which has formed - demolished from the clean gas and ejected in the form of chimney rain from the chimney.

These three types of formation lead to sulfuric acid containing chimney rain, the Corrosive accordingly. The separation system according to the invention should preferably reduce all three types of origin, minimizing as far as possible.

Inventive solution

At least partially, the above objects are achieved by the inventive deposition system. Characterized in that the inventive deposition system at least one longitudinally elongated blade whose longitudinal direction is aligned transversely or obliquely to the flow direction of the flue gas, comprising a chamber having an opening extending in the longitudinal direction, wherein the opening on a side facing the flow direction the lamella is arranged, at least a portion of the entrained by the gas stream drops and spray drops is passed directly into this chamber. In the chamber, these drops collide against the walls of the chamber, but this does not result in the formation of secondary spray, unlike a blade known in the art, which can be entrained by the gas flow, since no gas flow flows within the chamber. In other words, due to the inventive design of the blade, the impact is removed from the gas path to prevent the formation and removal of the secondary spray.

In order to further increase the separation efficiency with the aim of avoiding or at least reducing chimney rain, a preferred embodiment of the separation system has one or a plurality of modules, each module comprising at least one, preferably a plurality of lamellae.

In the sense of highest possible separation efficiency, it is then particularly preferred for the module or modules to be designed and arranged in such a way that they respectively define an inflow area which faces the flow direction. In other words, the gas flow is preferably directed to the inflow surface.

Particularly preferred is a development of the separation system according to the invention, in which the module or modules are arranged such that the inflow surface extends transversely or obliquely to the flow direction.

1. a) Der Verzicht auf das regelmäßige Waschen während des Betriebs verringert oder eliminiert eine der Hauptquellen des Schornsteinregens.
2. b) Ferner wird die Abscheidefunktion einer Lamelle deutlich verbessert, weil der negative Einfluss in der Verölung erheblich reduziert wird.

In a very particularly preferred embodiment of the separation system according to the invention, the at least one lamella, in contrast to the prior art is not installed in a container of REA, through which the flue gas flows before exiting in flue gas ducts or in a chimney, but in the chimney. As a result, on the one hand, the overall height of the container is significantly shortened, for example by 1,000 to 2,000 mm, which meets the desire to reduce the space requirements of the REA to minimize possible. The installation in the chimney also makes it possible to replace the slats during operation. Because it is not completely avoidable with a lamella exchange that leaks occur and flue gas can escape. This is a significant problem for personnel, especially when the work has to be done in a closed room where the container is located. However, a shift into the chimney shifts the area in which it is necessary to replace the lamellae into the open area, and the work generally takes place outdoors under the action of wind. Wind action means that due to the apparent wind acting on the ship (vector addition of true wind and wind) any escaping flue gas is transported away immediately and thus it represents no or at least a considerably lower risk for the staff. Since the lamellae can thus be replaced more often, the residual problem of oiling and soiling is reduced. The lamellae can be removed at shorter intervals and replaced with reserve louvers (new and / or cleaned). Then the removed fins can be cleaned, for example, mechanically and / or chemically with cleaning agents. Due to this "offline cleaning" the following advantages are achieved:

1. a) The absence of regular washing during operation reduces or eliminates one of the main sources of chimney rain.
2. b) Furthermore, the separation function of a lamella is significantly improved because the negative influence in the oiling is significantly reduced.

Furthermore, it is considerably preferred if, in the separation system according to the invention, the at least one lamella is arranged in the vicinity of the outlet opening of the chimney. This solves the problem of condensate ejection. The condensates formed in the wet chimney are carried with the flue gas to the separator and separated there before the flue gas emerges from the chimney.

In addition, the cross section of the chimney near the outlet can be made significantly larger than the cross section of the chimney. The flue gas velocity is thereby reduced and there is a lower pressure drop in the separator and the separation efficiency is improved.

1. a) Ein Flächenprofil, mit um vorzugsweise flache Winkel in abwechselndem Sinn abgewinkelten Bereichen, und
2. b) zumindest ein erstes und ein zweites Längsprofil mit jeweils einem Mittelbereich und zwei sich an gegenüberliegenden Rändern des Mittelbereichs anschließenden Randbereichen, die jeweils in einem äußeren Rand enden, die - vorzugsweise - dem Flächenprofil entsprechend, abgewinkelt sind, wobei zumindest das erste und das zweite Längsprofil mit jeweils ihrem Mittelbereich an jeweils einem Bereich des Flächenprofils derart versetzt befestigt sind, dass die Randbereiche eines Längsprofils zu vorzugsweise parallel verlaufenden Bereichen des Flächenprofils mit einem Abstand beabstandet sind, und zumindest der äußere Rand eines der Randbereiche des ersten Längsprofils zum äußeren Rand eines Randbereichs des zweiten Längsprofils einen Abstand aufweist, sodass zwischen den Bereichen des Flächenprofils und den Randbereichen eine Kammer und zwischen den beiden äußeren Rändern der Randbereiche die Öffnung ausgebildet ist.

Surprisingly, it has been shown that a lamella in terms of reduction or even Avoidance of chimney rain is particularly effective, which includes:

1. a) A surface profile, with preferably flat angles angled in alternate sense areas, and
2. b) at least a first and a second longitudinal profile, each having a central region and two adjoining edges of the central region edge regions, each terminating in an outer edge, which - preferably - the surface profile are angled, wherein at least the first and the second Longitudinal profile, each with its central region are fixed offset in each case to an area of the surface profile such that the edge regions of a longitudinal profile to preferably parallel portions of the surface profile are spaced at a distance, and at least the outer edge of one of the edge regions of the first longitudinal profile to the outer edge of an edge region of the second longitudinal profile has a distance, so that between the regions of the surface profile and the edge regions, a chamber and between the two outer edges of the edge regions, the opening is formed.

The special function of this chamber separator is that the drops do not bounce in the flue gas flow against a resistance but rather fly into the chamber and there bounce in the space against the plates. The result of this is that the secondary drops produced by the impact are not thrown back into the flue gas flow, but remain in the chamber and separate there. It lacks the sweeping gas flow, which could cause a transfer of the secondary drops.

The negative function of oiling is largely eliminated. The oiling leads to the fact that no film of water can form on the surface, which could absorb the impacting drops. This leads to the significantly increased deposition of secondary drops. In the chamber, this does not matter, because the receiving gas flow is missing. The secondary drops are either carried away by the following drops or they precipitate out by gravity - but usually do not get back into the gas stream.

Particularly preferably, at least two longitudinal profiles are attached to such a lamella on both sides of the surface profile.

The separation system can be further improved and the cleaning cycle can be extended by placing a roller separator in the head of the REA tank. On the one hand, this roller separator has the function of reducing the amount of drops in the flue gas and, on the other hand, of intercepting and binding oily components before they reach the actual separator.

• 1 eine geschnittene Seitenansicht eines zum Stand der Technik gehörende Abscheidesystems;
• 2 eine bei diesem verwendete Lamelle in einer perspektivischen Ansicht;
• 3 eine bei einem erfindungsgemäßen Abscheidesystem verwendete Lamelle, wiederrum in einer perspektivischen Darstellung;
• 4 ein Modul, welches eine Mehrzahl von Lamellen der in 3 dargestellten Art umfasst;
• 5 ein erstes Ausführungsbeispiel eines erfindungsgemäßen Abscheidesystems in einer geschnittenen Seitenansicht sowie
• 6 ein weiteres Ausführungsbeispiel eines erfindungsgemäßen Abscheidesystems in einer 5 entsprechenden Ansicht.

In the drawing, a belonging to the prior art separation system, an embodiment of a slat used in a separation system according to the invention and two embodiments of the separation system according to the invention - purely schematically - graphically gargestellt. He show:

• 1 a sectional side view of a belonging to the prior art separation system;
• 2 a blade used in this in a perspective view;
• 3 a lamella used in a deposition system according to the invention, again in a perspective view;
• 4 a module comprising a plurality of fins of the in 3 includes the type shown;
• 5 a first embodiment of a separation system according to the invention in a sectional side view and
• 6 a further embodiment of a separation system according to the invention in one 5 corresponding view.

This in 1 shown, belonging to the prior art separation system comprises a container 7 through which a flue gas stream 9 in the flow direction R , that is passed from bottom to top. For this purpose, the container 7 a side inlet e on. Below the side inlet e includes the container 7 a swamp T , which serves to catch liquid. At the deepest point of the swamp T is an outlet U provided, through which the collected liquid can be drained and optionally fed to a further use or cleaning. In the container 7 the flue gas flows through a spray arrangement 5 with which in the flue gas liquid in the form of a spray for binding SO ₂ or SO ₃ and washing out of solids is supplied. Drops are formed which have absorbed SO ₂ or SO ₃ as well as the solids. They are washed out by means of droplet separators arranged downstream of the spray arrangement in the flow direction of the flue gas. They fall in large part due to gravity in the container 7 down and gather in the swamp T , A small part, however, is with the flue gas in an upwards to the container 7 adjoining chimney S entrained and occurs at least partially through the chimney opening 10 out. For example, moisture content, pollutant content etc. in the chimney is a test port 8th provided that allows the insertion or connection of appropriate measuring equipment or probes.

There are known from the prior art dropletizers, which consist of a plurality of laterally juxtaposed layers of Abscheiderlamellen, for example - as in 2 shown schematically - consist of curved layers of flat material. Several layers of lamellae can be summarized by not shown in the drawing side walls to Abscheidepaketen and summarized with adjacent Abscheidepaketen to roof or V-shaped or too flat modules.

It has been found that it can come to the use of such fins for cleaning exhaust gases from marine diesel to unwanted chimney rain, because the drops can not be deposited on the oily surface, but are thrown back into the secondary gas in the gas flow. In order to reduce the occurrence of chimney rain, an inventive separation system comprises a lamella 1 that has at least one chamber 2 with a longitudinal direction L the slat extending opening 2a includes. An embodiment of such a blade is in 3 shown. It includes a surface profile 14 with preferably angled flat in an alternate sense angled areas 15 , At least a first and a second longitudinal profile 16 . 17 each with a central area 18 and two border areas adjoining opposite edges of the central area 19 . 19 ' , each in an outer edge 20 . 20 ' Ends which are angled in accordance with the surface profile are each with their middle region 18 at one area each 15 of the surface profile 14 fixed so offset, that the edge areas 19 . 19 ' a longitudinal profile to parallel areas 15 of the surface profile 14 with a distance D are spaced. At least the outer edge 20 ' one of the border areas 19 of the first longitudinal profile 16 points to the outer distance 20 a border area 19 of the second longitudinal profile 17 a distance A on, so between the areas 15 of the surface profile 14 and the two border areas 19 ' . 19 the chamber 2 and between the two outer edges 20 ' . 20 the border areas 19 ' . 19 the opening 2a is trained. On both sides of the surface profile 14 are each two longitudinal profiles 16 . 17 attached. It has been shown that a separator with such a lamella substantially reduces the formation of chimney rain. This can be explained by the fact that at least some of the drops do not bounce off outer surfaces and form a secondary spray, but into the chamber 2 does not enter and in a rebound of walls of the chambers forming secondary spray mist not in the flue gas stream 9 arrives.

As in 4 shown, may be a plurality of lamellae 1 be combined by a preferably parallel to each other and further preferably equidistant arrangement to form a module, preferably such that the module can be arranged in the separation system such that it has an inflow surface F forms, transversely or obliquely to the flow direction R runs.

At an in 5 schematically illustrated, the first embodiment of a separation system according to the invention 100 is in contrast to the prior art, the mist eliminator 6 not inside the container 7 arranged but in the chimney S himself and here near his outlet 10 , The spray arrangement 5 is located near the top of the container 5 , In the 4 illustrated a plurality of fins 1 comprehensive modules 13 are arranged flat such that the inflow surface F transverse to the flow direction of the flue gas R runs.

For fastening the modules 13 in the chimney S is an interchange 21 provided, which is designed such that the modules 13 are interchangeable during operation of the ship's diesel. This interchangeability during operation is particularly possible because the modules are arranged within the chimney, so possibly during the change process in the field of interchangeability 21 escaping gases go directly into the open air.

At an in 6 illustrated, the second embodiment of the separation system according to the invention 200 are different from the first embodiment of the separation system according to the invention 100 the modules 13 arranged such that they - with respect to the flow direction of the flue gas - with a respective adjacent module form the shape of a V or an inverted V ("roof shape"). The inflow surfaces F the modules 13 thus run obliquely to the flow direction of the flue gas R , Further, in the upper area of the container 7 , also referred to as "absorber head", a multi-layer roller separator 22 arranged. It has the function, on the one hand to reduce the amount of drops in the flue gas and on the other hand absorb and bind oily components, before these modules 13 to reach. With the help of the roller separator, the separation efficiency of the separation system can be further improved and the cleaning cycles can be extended. Otherwise, this second embodiment corresponds to the separation system 200 essentially the first embodiment, so reference is made to the description thereof.

LIST OF REFERENCE NUMBERS

100, 200

Separating

1

lamella

2

chamber

2a

Opening of the chamber

3

chimney outlet

4

exchange possibility

5

sprayer

6

Droplet

7

container

8th

test port

9

Flue gas stream

10

chimney outlet

11

drops

12

opening

13

module

14

surface profile

15

Area of the area profile

16

first longitudinal profile

17

second longitudinal profile

18

the central region

19, 19 '

border areas

20, 20 '

edge

21

change mount

22

Rollenabscheider

A

distance

D

distance

e

inlet

F

inflow area

L

Longitudinal separator

R

Flow direction flue gas

S

chimney

T

swamp

U

outlet

Claims (10)

Separation system (100) of a flue gas desulphurisation system of a ship for separating drops (11) from a flue gas which flows in a flow direction (R) and preferably through a vertical outlet (10) of a chimney (S), preferably with a vertically upward flow component . with at least one lamella (1) which is elongate in a longitudinal direction (L) and whose longitudinal direction (L) is oriented transversely or obliquely to the flow direction (R), the lamella (1) comprising at least one chamber (2) with an opening (2a) extending in the longitudinal direction (L), wherein in each case the opening (2a) on one of the flow direction (R) facing side of the lamella (1) is arranged. Separating system after Claim 1 , characterized in that it comprises one or more modules (13), wherein the one or more modules (13) have at least one lamella (1). Separating system after Claim 2 , characterized in that the module or modules (13) each define an inflow surface (F), which faces the flow direction define. Separating system after Claim 3 , characterized in that the one or more modules (13) are arranged such that the inflow surface (F) transversely or obliquely to the flow direction (R). Separation system according to one of Claims 1 to 4 , characterized in that the at least one lamella (1) is arranged in the chimney. Separating system after Claim 5 , characterized in that the at least one lamella (1) in the vicinity of the outlet opening (10) of the chimney is arranged, and this outlet opening preferably has a relation to the chimney enlarged cross-section Separation system according to one of Claims 1 to 6 , characterized in that at least one, preferably all slats (1) are arranged interchangeably from the outside. Separation system according to one of Claims 1 to 7 , characterized in that the lamella (1) comprises a) a surface profile (14) with preferably flat angles angled in alternate sense areas (15), and b) at least a first and a second longitudinal profile (16,17), respectively a central region (18) and two adjoining edges at opposite edges of the central region (19, 19 '), each in an outer edge (20, 20') terminate, which - preferably - the surface profile according to angled, wherein at least the first and the second longitudinal profile (16, 17), each with its central region (18) on in each case an area (15) of the Surface profiles (14) are mounted offset in such a way that the edge regions (19, 19 ') of a longitudinal profile (16, 17) to preferably parallel portions (15) of the surface profile (14) with a distance (D) are spaced, and at least the outer edge (20 ') of one of the edge regions (19') of the first longitudinal profile (16) to the outer edge (20) of an edge region (19) of the second longitudinal profile (17) has a distance (A), so that between the regions (15 ) of the surface profile (14) and the two edge regions (19 ', 19), a chamber (2) and between the two outer edges (20', 20) of the edge regions (19 ', 19), the opening (2a) is formed. Separating system after Claim 8 , characterized in that on both sides of the surface profile (14) in each case at least two longitudinal profiles (16, 17) are attached. Separation system according to one of Claims 1 to 8th , characterized in that the flue gas desulfurization comprises a chimney (S) in the flow direction (R) of the flue gas upstream container (7), and in that a preferably multi-layer roller separator (22) is provided in the container.

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