JP3232219U - Exhaust gas purification system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an exhaust gas purification system for purifying exhaust gas in a ship. An exhaust gas purification system 1 communicates with a scrubber arranged so as to wash an exhaust gas EG with a scrubber liquid SF circulated through the scrubber 7 and a scrubber for cooling the scrubber liquid circulated through the scrubber. A first heat exchanger 3 is provided. Further, the exhaust gas purification system sends the scrubber liquid to the scrubber and receives the scrubber liquid from the circulation tank 5 and the circulation tank 5 which is arranged in communication with the scrubber to receive the scrubber liquid from the scrubber. A purification unit 11 is provided which is arranged in communication with the circulation tank to separate the fraction SF1 and the second fraction SF2, and the second fraction is more contaminated than the first fraction. It further comprises a heating device 9 that heats the scrubber liquid after it has left the circulation tank 5 and before it is received by the purification unit. [Selection diagram] Fig. 1

Description

The present invention relates to an exhaust gas purification system for purifying in-ship exhaust gas, for example, from a marine engine, burner, or boiler.

Large vessels are typically driven by engines powered by sulfur-containing fuels. Combustion of such fuels forms exhaust gases containing _{sulfur oxides (SO X).} Exhaust fumes typically also contain particulate matter such as soot, oil, and heavy metals, as well as nitrogen oxides (NO _X). To reduce the impact of exhaust gas on the environment, exhaust gas should be purified before it is released into the atmosphere. For example, the exhaust gas can pass through the scrubber and be washed with the scrubber solution, whereby pollutants in the exhaust gas are trapped in the scrubber solution.

The scrubber may be a so-called open-loop scrubber, and the scrubber liquid may be seawater. The natural alkalinity of seawater is used to wash away sulfur oxides from exhaust fumes. Then, before the sea water is discharged directly back to the sea, in order to absorb the SO _X and particulate matter from the exhaust gas, the seawater is fed through the scrubber from the sea.

Alternatively, the scrubber uses fresh water or seawater that circulates in combination with an alkaline agent such as sodium hydroxide (NaOH) or sodium carbonate (Na ₂ CO _{3) as the scrubber solution, and sulfur oxides and particulate matter from the exhaust gas.} It may be a so-called closed loop scrubber that washes off. In such scrubbers, the amount of hydrous sulfite, sulfate, and particulate matter in circulating fresh or seawater gradually increases. Therefore, in order to control the quality of circulating freshwater or seawater, a small amount of circulating freshwater or seawater may be replaced occasionally or continuously with clean freshwater or seawater, and a small amount of circulating freshwater or seawater may occasionally or continuously. It may be stored on the ship or discharged out of the ship after purification of particulate matter.

When hot exhaust gas comes into contact with the scrubber liquid inside the scrubber, the exhaust gas is cooled and a large amount of water contained in the scrubber liquid evaporates. This evaporated water, along with the exhaust fumes, can leave the scrubber and come into contact with the surrounding air conditions, creating unwanted visible plumes. According to a known solution to this problem, the exhaust gas containing evaporated water is heated before it is released from the vessel to obscure the plume. However, the equipment used for this heating is large and expensive. Equipment also consumes large amounts of energy that are negative from an environmental point of view.

An object of the present invention is to provide an exhaust gas purification system for purifying exhaust gas in a ship, which solves the above-mentioned problems at least in part. The basic concept of the present invention is to cool the exhaust gas inside the scrubber and reduce the amount of evaporated water that leaves the scrubber together with the exhaust gas. The exhaust gas system according to the present invention is specified in the accompanying claims and the discussion below.

The exhaust gas purification system according to the present invention is arranged to purify the exhaust gas in the ship. The exhaust gas purification system comprises a scrubber arranged to clean the exhaust gas with a scrubber fluid circulated through the scrubber. The exhaust gas purification system further comprises a first heat exchanger, a circulation tank, and a purification unit. The first heat exchanger is arranged in communication with the scrubber to cool the scrubber liquid circulating through the scrubber. The circulation tank is arranged in communication with the scrubber to send the scrubber liquid to the scrubber and receive the scrubber liquid from the scrubber. The purification unit receives the scrubber liquid from the circulation tank and is arranged in communication with the circulation tank to separate the scrubber liquid into the first fraction and the second fraction. The second fraction is more contaminated than the first fraction, i.e. contains more particulate matter. The exhaust gas purification system is characterized in that it further comprises a heating device. The heating device is arranged in communication with the circulation tank and the purification unit to heat the scrubber liquid after it leaves the circulation tank and before it is received by the purification unit.

The exhaust gas purification system can be arranged to purify the exhaust gas from a ship engine mounted on a ship, a ship burner mounted on a ship, or a ship boiler mounted on a ship.

Throughout this text, it should be emphasized that "communicate" and "communicate" mean "direct or indirect communication" and "direct or indirect communication," respectively. Similarly, throughout this text, "receive", "send", etc. mean "directly or indirectly receive" and "directly or indirectly send", respectively.

This scrubber is a so-called closed loop scrubber because the scrubber liquid circulates through the scrubber of the exhaust gas purification system of the present invention through the circulation tank. As previously mentioned, closed-loop scrubbers typically operate with freshwater and / or seawater scrubber solutions mixed with suitable alkaline agents.

Purification units can be arranged to receive a constant or intermittent flow of scrubber fluid from the circulation tank, which may change over time.

The purification unit can include one or more separators and / or filters, such as a centrifuge and / or decanter, such as a fast separator, and / or a thin film filter.

As described above, in the exhaust gas purification system according to the present invention, the cooling of the exhaust gas is enhanced in order to reduce the amount of water in the scrubber liquid evaporated inside the scrubber. Such increased exhaust gas cooling is achieved by increasing the cooling of the scrubber fluid circulated through the scrubber by the first heat exchanger. Of course, depending on the surrounding air conditions that are spreading, exhaust fumes containing more water vapor will typically produce a more visible plume when leaving the vessel than exhaust fumes containing less water vapor. It will be created. By reducing the amount of water evaporated inside the scrubber, the amount of water vapor leaving the vessel along with the exhaust fumes is reduced, which can reduce the visible plume from the vessel.

As described as an introduction, closed-loop scrubbers may require replacement of the scrubber fluid to control the quality of the circulating scrubber fluid. The scrubber fluid to be replaced can be purified from the particulate matter and then discharged to the sea or storage tank, depending on the prevailing situation. In order to drain, the scrubber may need to meet certain criteria, for example, the scrubber may not have too low a pH value and / or too high a turbidity value. During the treatment period of the scrubber solution in the purification unit, the solubility of the alkaline agent decreases as the temperature of the scrubber solution decreases, depending on which alkaline agent is contained in the scrubber solution, resulting in particulate matter. The non-degradable alkaline agent can be removed together with. Naturally, this is a waste of unused chemicals. In addition, depending on which alkaline agent is contained in the scrubber solution, the alkaline agent may cause a high turbidity value in the scrubber solution, which may prevent the scrubber solution from being discharged. is there.

The replacement scrubber fluid is purified in that the exhaust gas purification system according to the present invention comprises a heating device for heating the scrubber fluid after it has left the circulation tank and before it is received by the purification unit. Can be heated before being processed by the unit. Heating the scrubber solution can improve the solubility of the alkaline agent, which prevents the alkaline agent from reaching a more contaminated second fraction and wasting it. As an addition / alternative, heating the scrubber solution can reduce the turbidity value of the scrubber solution, which can allow the discharge of a cleaner first fraction of the scrubber solution.

The exhaust gas purification system can further be provided with means for supplying the alkaline agent to the scrubber liquid. Thereby, the alkaline agent can be replenished when it is suitable for optimizing the efficiency of the exhaust gas purification system. For example, the means for supplying the alkaline agent to the scrubber liquid can be placed upstream of the circulation tank and downstream of the scrubber. That is, the alkaline agent can be replenished.

The alkaline agent can include different chemicals, for example magnesium oxide or magnesium carbonate. According to one embodiment of the present invention, the alkaline agent comprises magnesium hydroxide which has the advantage that the crystallinity of the sulfate formed in the scrubber solution is relatively low even when the temperature of the scrubber solution is low.

The means for supplying the alkaline agent to the scrubber liquid can include a source of the alkaline agent and a pump for pumping the alkaline agent from the source into the scrubber liquid. The source of the alkaline agent may simply be a container containing the alkaline agent. The pump may be a screw pump capable of reducing corrosion due to some wear of the alkaline agent. In addition, screw pumps are relatively resistant to clogging.

The exhaust gas purification system may further include a measuring device arranged to measure the value of the properties of the scrubber fluid, the value of which may be lower, equal to or higher than a predetermined value. The handling of the scrubber fluid may depend on the output of the measuring device.

The measuring device can be arranged in communication with the heating device and the purification unit to measure the value of the property of the scrubber liquid after the scrubber liquid has been heated by the heating device and before being received by the purification unit. The handling of a cleaner first fraction of the scrubber solution may depend on the output of the measuring device.

The measuring device may include a mass flow meter, the characteristic of which may be the density of the scrubber fluid. The density of the scrubber solution depends on the salt content of the scrubber solution.

The mass flow meter may be of any suitable type. According to one embodiment of the present invention, the mass flow meter is a mass flow meter having the advantage of being an in-line mass flow meter.

Alternatively or additionally, the measuring device may include a conductivity sensor, the characteristic of which may be the conductivity of the scrubber fluid. The conductivity of the scrubber solution depends on the salt content of the scrubber solution.

The purification unit communicates with the circulation tank to send at least some, or part, of the first fraction of the scrubber liquid to the circulation tank if the value of the property is lower than the predetermined value. You can do it. If the value is relatively low, the salt content of the scrubber fluid may be relatively low and the discharge of a cleaner first fraction of the scrubber fluid is not required for proper operation of the exhaust gas purification system. In some cases. Purification units can be arranged to deliver a constant or intermittent flow of scrubber fluid to the circulation tank, the flow of which may change over time.

The exhaust gas purification system may further include a water analysis unit arranged to determine a number of one or more of the parameter values of the first fraction of the scrubber fluid. The handling of a cleaner first fraction of the scrubber solution may depend on the output of the water analysis unit. The parameter values determined by the water analysis unit may be, for example, the turbidity, pH, and PAH concentration of the first fraction of the scrubber solution.

The purification unit is to send at least some, or part, of the first fraction of the scrubber fluid to the circulation tank if at least one of the parameter values exceeds or is equal to their respective limits. , May communicate with the circulation tank. This can prevent the discharge of the first fraction of the scrubber solution if certain criteria are not met, i.e. if the first fraction is not clean enough, which is an environmental point of view. It is beneficial from. Purification units can be arranged to deliver a constant or intermittent flow of scrubber fluid to the circulation tank, the flow of which may change over time.

Therefore, the purification unit will put the scrubber fluid in the circulation tank if the value of the property is lower than the predetermined value and / or if at least one of the parameter values exceeds or is equal to their respective limits. It can be arranged to send at least some of the first fraction.

As mentioned above, the exhaust gas purification system may further comprise a water analysis unit arranged to determine a number of one or more of the parameter values of the first fraction of the scrubber fluid. Further, the exhaust gas purification system has a first fraction of the scrubber solution when each of the parameter values is lower than the respective limit value and / or the value of the characteristic is equal to or more than the predetermined value. It can be arranged to eject at least some, or part of, of. For example, the first fraction of scrubber fluid can be drained out of the vessel or into a temporary storage tank for later draining out of the vessel. The discharged liquid can be replaced with an unused scrubber liquid. Thereby, the salt content of the scrubber liquid circulating through the scrubber can be kept sufficiently low for proper operation of the exhaust gas purification system.

The heating device for heating the scrubber liquid before it is received by the purification unit can include a second heat exchanger.

The first and second heat exchangers may be of any suitable type, such as flat plate heat exchangers or tubular and outer iron heat exchangers. Further, the first heat exchanger and the second heat exchanger may be of the same type or of different types.

Yet other objectives, features, aspects and advantages of the present invention will be apparent from the detailed description and drawings below.

The present invention will now be described in more detail with reference to the accompanying schematic.

It is a block diagram which schematically illustrates the exhaust gas purification system according to this invention.

Figure 1 shows the first flat plate heat exchanger 3, the circulation tank 5, the scrubber 7, the heating device 9 in the form of the second flat plate heat exchanger 9', the purification unit 11, the water analysis unit 13, and the Koriori mass flow meter 15. Illustrates an exhaust gas purification system 1 comprising a measurement device 15 in the form of', and here means 17 for supplying an alkaline agent which is magnesium hydroxide. Further, the means 17 for supplying the alkaline agent comprises a source 19 of the alkaline agent, which is magnesium hydroxide here, more specifically a container containing the alkaline agent, and a screw pump 21. The exhaust gas purification system 1 is configured to purify the exhaust gas EG from the marine diesel engine 23 mounted on a ship (not shown).

Inside the scrubber 7 functioning in a conventional manner, which is not described further herein, the exhaust gas EG is washed with the scrubber solution SF in the form of fresh water mixed with magnesium hydroxide. Therefore, the scrubber 7 includes an exhaust gas inlet 25 for receiving the exhaust gas EG from the engine 23, and an exhaust gas outlet 27 for releasing the washed exhaust gas EGW. The scrubber liquid SF is sent from the circulation tank 5 to the scrubber 7, and to absorb pollutants from the exhaust gas EG, it passes through the scrubber 7 to clean the exhaust gas EG, returns to the circulation tank 5, and then returns to the scrubber 7. And so on.

The exhaust gas EG emitted from the engine 23 is very hot and is placed upstream of the scrubber 7 and downstream of the circulation tank 5, that is, in the middle of the circulation tank 5 to the scrubber 7, in order to maintain a suitable temperature for the scrubber liquid SF. The exhaust gas EG is cooled by seawater in the first flat plate heat exchanger 3. Since the exhaust gas EG has a high temperature, the water contained in the scrubber liquid SF evaporates when the scrubber liquid comes into contact with the exhaust gas EG inside the scrubber 7. The formed water vapor exits the scrubber 7 and is discharged from the ship through the chimney together with the purified exhaust gas EGW. To reduce the visible plume formed by this moist and purified exhaust as the exhaust gas is released into the atmosphere, the scrubber fluid SF recirculated through the scrubber 7 is the first plate. The heat exchanger 3 cools it more than the conventional one. As a result, less water evaporates inside the scrubber, which results in less moist, purified exhaust, resulting in a less visible plume.

As the scrubber fluid SF is recirculated through the scrubber 7, the scrubber fluid SF becomes more and more contaminated. To ensure the efficient operation of the scrubber 7, the scrubber fluid must not be over-contaminated. Therefore, some of the scrubber liquid SF is continuously pumped from the circulation tank 5 to the purification unit 11 to be purified. The purification unit 11 is a high speed separator arranged to separate the contaminated scrubber liquid into a cleaner first fraction SF1 and a more contaminated second fraction SF2. The second fraction SF2 is sent to sludge tank 29 for later discharge. In order to secure a sufficient amount of scrubber liquid in the circulation tank 5, the circulation tank 5 is replenished with the scrubber liquid to make up for the scrubber liquid discharged by the pump. This replenishment can include adding clean fresh water from the outside of the exhaust gas purification system 1. In that case, the scrubber fluid replenishment will typically also include the supply of magnesium hydroxide to the scrubber fluid in order to maintain the scrubber fluid properties suitable for proper operation of the exhaust gas purification system 1. .. The magnesium hydroxide is then pumped from the source 19 into the scrubber fluid by the screw pump 21. Magnesium hydroxide is supplied downstream of scrubber 7 and upstream of circulation tank 5. The scrubber fluid replenishment may be "internal" as an alternative / addition, in which case the cleaner first fraction SF1 of the scrubber fluid SF is sent back from the purification unit 11 to the circulation tank 5. This will be discussed further below.

As described above, the use of magnesium hydroxide as the alkaline agent makes it possible to cool the scrubber liquid circulated through the scrubber more than before without causing the problem of crystallinity. However, the relatively low solubility of magnesium hydroxide in water may result in a scrubber solution containing non-degradable magnesium hydroxide. To avoid such non-degradable magnesium hydroxide being sent to the purification unit 11 to reach the more contaminated second fraction SF2 of the scrubber liquid SF, which is then discarded, by the purification unit 11. The scrubber liquid to be processed is arranged upstream of the purification unit 11 and downstream of the circulation tank 5, that is, heat recovery of the ship in the second heat exchanger 9'in the middle of the purification unit 11 from the circulation tank 5. Heated by water from the system. By this heating, the non-degradable magnesium hydroxide in the scrubber solution dissolves instead to reach the cleaner first fraction SF1 of the scrubber solution SF. This cleaner first fraction SF1 can be sent back to the circulation tank 5 as previously mentioned.

As mentioned above, the more contaminated second fraction SF2 of the scrubber liquid SF is sent to the sludge tank 29. What happens to the cleaner first fraction SF1 depends on different factors, for example, the characteristics of the cleaner first fraction SF1. When the scrubber solution is recirculated through the scrubber, the amount of sulfate in the scrubber solution gradually increases. The salt content of the circulating scrubber fluid should not be too high to ensure proper operation of the exhaust gas purification system 1. For this purpose, the density of the scrubber liquid SF processed by the purification unit 11 is arranged upstream of the purification unit 11 and downstream of the second plate heat exchanger 9', that is, the second plate heat exchanger 9'. Measured by the Koriori mass flow meter 15'in the middle of the purification unit 11. If the density is above a predetermined value, the salt content in the scrubber solution is very high, so the cleaner first fraction SF1 of the scrubber solution depends on its further properties, the exhaust gas purification system. Should be flushed or drained from 1. However, if the density is lower than a predetermined value, the first fraction SF1 of the scrubber fluid SF does not need to be flushed and the first fraction SF1 instead replenishes the "inside" of the scrubber fluid. It is returned to the circulation tank 5 and sent.

The flushing or discharging of the first fraction SF1 from the exhaust gas purification system 1 is performed only if the density of the scrubber liquid is sufficiently high and the first fraction SF1 of the scrubber liquid SF meets certain criteria. It is said. The latter is inspected by a water analysis unit 13 located downstream of the purification unit 11 and upstream of the circulation tank 5. The water analysis unit 13 is arranged to determine the turbidity value, pH value, and PAH (polycyclic aromatic hydrocarbon) concentration of the first fraction SF1 of the scrubber solution SF. If one or more of the turbidity, pH, and PAH concentrations are above their respective limits, eg, 25 NTU, 6.5, and 2250 ppb, respectively, the first fraction SF1 of the scrubber solution SF is flushed out. Instead, the first fraction SF1 is supplied back to the circulation tank 5 with "internal" replenishment of the scrubber fluid. However, if the turbidity, pH, and PAH values are all below their respective limits and the scrubber fluid density is high enough, the first fraction is prohibited from being discharged offboard, or, for example, offboard. If there is a vessel in the area to be drained, it will be flushed or discharged from the exhaust gas purification system 1 into a temporary storage tank (not shown) for later discharge.

Thus, the scrubber fluid circulated through the scrubber is cooled to, for example, 6 ° C. above normal to reduce the visible plume from the ship's chimney. Magnesium hydroxide is used as the alkaline agent to allow such a low scrubber solution temperature without disturbing the crystallinity. In order to prevent undecomposed magnesium hydroxide from reaching the waste fraction, the second fraction SF2, from the purification unit, the scrubber solution processed in the purification unit is subjected to a second fraction before being sent to the purification unit. It is heated to, for example, 35 ° C by a flat plate heat exchanger. In addition to melting the non-degradable magnesium hydroxide in the scrubber solution processed by the purification unit, heating the scrubber solution reduces the turbidity of the scrubber solution, and thus the first fraction SF1 of the scrubber solution, resulting in the scrubber. It is easier to obtain a turbidity value low enough to allow the outflow or drainage of the first fraction of the liquid.

As mentioned earlier, the scrubber fluid circulating through the scrubber can be cooled by seawater, which must be naturally sufficiently cold to allow it to cool more than before. As also mentioned earlier, the visibility of the plume depends on the ambient air conditions, for example when the ambient temperature is low, the plume is typically more visible. Low seawater temperatures are usually associated with low ambient temperatures, which means that the exhaust gas purification system above is most effective when it is most needed.

The components of the exhaust gas purification system mentioned above are connected by suitable piping to allow them to communicate in the manner specified above. In addition, the exhaust gas system described above may include additional components such as pumps, valves, sensors, additional water analysis units, control units, switching modules, etc. that allow the system to function properly. As an example, the exhaust gas system may include a pH meter or sensor between the scrubber and the circulation tank to measure the pH of the scrubber fluid. The pH meter can communicate with the supply means 17 to supply magnesium hydroxide to the scrubber solution at the appropriate time. The supply means 17 can also operate / or depending on the sulfur dioxide / carbon dioxide ratio of the purified exhaust gas.

The embodiments described above of the present invention should be understood merely as an example. Those skilled in the art will appreciate that the embodiments discussed can be varied in many ways without departing from the concept of the present invention.

As an example, the exhaust gas purification system can operate with an alkaline agent other than magnesium hydroxide, magnesium oxide. In addition, other chemicals other than alkaline agents, such as coagulants or coagulants to improve the efficiency of the purification unit 11, can be added to the scrubber solution for optimal operation of the exhaust gas purification system.

The supply means 17 for supplying magnesium hydroxide to the scrubber liquid does not need to be located upstream of the circulation tank 5 and downstream of the scrubber 11, but somewhere else, for example, directly connected to the circulation tank 5. Can be placed.

In the embodiment described above, the handling of the first fraction of the scrubber solution depends on the density of the scrubber solution after heating and the turbidity, pH and PAH concentrations of the first fraction of the scrubber solution. To do. In alternative embodiments, the handling of the first fraction of the scrubber solution may depend on just one or two of these parameters, additional parameters, and / or other parameters.

The scrubber solution need not contain fresh water and an alkaline agent, but may instead contain seawater and an alkaline agent or a combination thereof.

The flow of scrubber fluid from the circulation tank to the purification unit need not be continuous, it may be intermittent and can only be done at regular intervals or at appropriate times.

The first plate heat exchanger 3 does not need to be located upstream of the scrubber or in front of the scrubber and downstream of the circulation tank or after the circulation tank, but instead can be located downstream of the scrubber and upstream of the circulation tank. ..

The heating device 9 does not have to have the shape of the second flat plate heat exchanger 9'and may have any shape. For example, the heating device 9 may instead / additionally be equipped with an electric heater.

The scrubber liquid treated in the purification unit 11 does not need to be heated by water from the ship's heat recovery system, but can be heated by hot water or steam from any suitable source.

The measuring device 15 does not have to have the shape of the Coriolis mass flow meter 15'and can have any shape. For example, the measuring device 15 may optionally / additionally include a conductivity sensor.

It should be emphasized that details not relevant to the present invention are omitted and that the figures are merely schematic and not drawn in proportion to their actual size.

1 Exhaust gas purification system
3 1st flat plate heat exchanger, 1st PHE
5 Circulation tank
7 scrubber
9 heating device, second PHE
9'Second flat plate heat exchanger, second PHE
11 Purification unit
13 Water analysis unit
15 Measuring device
15'Coriolis mass flow meter
17 Means for supplying alkaline agents, means of supply
19 Source of alkaline agent, source of alkalinity, source
21 screw pump
23 Marine diesel engine, engine
25 Exhaust gas inlet
27 Exhaust gas outlet
29 sludge tank

Claims (15)

An exhaust gas purification system (1) for purifying the exhaust gas (EG) in a ship.
A scrubber (7) arranged to wash the exhaust gas (EG) with a scrubber liquid (SF) circulated through the scrubber (7).
A first heat exchanger (3) arranged in communication with the scrubber (7) to cool the scrubber liquid (SF) circulating through the scrubber (7).
A circulation tank (5) arranged in communication with the scrubber (7) to send the scrubber liquid (SF) to the scrubber (7) and receive the scrubber liquid (SF) from the scrubber (7).
The circulation tank (SF) receives the scrubber liquid (SF) from the circulation tank (5), and separates the scrubber liquid (SF) into a first fraction (SF1) and a second fraction (SF2). Purification unit (11) arranged in communication with 5), wherein the second fraction (SF2) is more contaminated than the first fraction (SF1). With and
The circulation tank (5) and the purification to heat the scrubber liquid (SF) after the scrubber liquid (SF) exits the circulation tank (5) and before it is received by the purification unit (11). An exhaust gas purification system (1), further comprising a heating device (9) that is arranged in communication with the unit (11). The exhaust gas purification system (1) according to claim 1, further comprising a means (17) for supplying an alkaline agent to the scrubber liquid (SF). The exhaust gas purification system (1) according to claim 1 or 2, wherein the alkaline agent contains magnesium hydroxide. The means (17) for supplying the alkaline agent to the scrubber liquid (SF) is the source (19) of the alkaline agent and the alkaline agent from the source (19) to the scrubber liquid (SF). The exhaust gas purification system (1) according to claim 2 or 3, comprising a pump (21) for pumping. The exhaust gas purification system (1) according to claim 4, wherein the pump (21) is a screw pump. Any one of claims 1-5, further comprising a measuring device (15) arranged to measure the value of the properties of the scrubber solution (SF), which may be lower, equal, or higher than a predetermined value. Exhaust gas purification system described in Section (1). The measurement to measure the value of the property of the scrubber liquid (SF) after the scrubber liquid (SF) has been heated by the heating device (9) and before being received by the purification unit (11). The exhaust gas purification system (1) according to claim 6, wherein the device (15) is arranged in communication with the heating device (9) and the purification unit (11). The exhaust gas purification system (1) according to claim 6 or 7, wherein the measuring device (15) comprises a mass flow meter (15') and the characteristic is the density of the scrubber liquid (SF). The exhaust gas purification system (1) according to claim 8, wherein the mass flow meter (15') is a mass flow meter. The exhaust gas purification system (1) according to claim 6 or 7, wherein the measuring device (15) includes a conductivity sensor and the characteristic is the conductivity of the scrubber liquid (SF). If the value of the property is lower than the predetermined value, then at least some of the first fraction (SF1) of the scrubber solution (SF) is sent to the circulation tank (5). The exhaust gas purification system (1) according to any one of claims 6 to 10, wherein the purification unit (11) communicates with the circulation tank (5). Claims 1 to 11 further include a water analysis unit (13) arranged to determine a number of one or more of the parameter values of the first fraction (SF1) of the scrubber solution (SF). The exhaust gas purification system according to any one of the paragraphs (1). To send at least some of the first fraction (SF1) of the scrubber solution (SF) to the circulation tank (5) if at least one of the parameter values is greater than or equal to their respective limits. The exhaust gas purification system (1) according to claim 12, wherein the purification unit (11) communicates with the circulation tank (5). Further comprising a water analysis unit (13) arranged to determine a number of one or more of the parameter values of the first fraction (SF1) of the scrubber solution (SF), each of the parameter values. If it is lower than each limit value and / or if the value of the property is greater than or equal to the predetermined value, at least some of the first fraction (SF1) of the scrubber solution (SF) is discharged. The exhaust gas purification system (1) according to any one of claims 6 to 11, which is arranged so as to be used. The exhaust gas purification system (1) according to any one of claims 1 to 14, wherein the heating device (9) comprises a second heat exchanger (9').

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