METHOD AND DEVICE FOR MOLECULAR DEPOSITION IN CEMENTLINK MANUFACTURING

专利摘要:
The invention relates to a method and a device for separating mercury from the exhaust gases (1) in cement clinker production, with a preheating stage (2), a task for the raw materials required for cement clinker production (10), a rotary kiln (3) for firing the raw materials , at least one filter stage (8) for dedusting the exhaust gases (1) carried in the main stream, and at least one raw meal mill (6) for at least partially grinding the raw materials (10), wherein between the preheating stage (2) and the raw meal mill (6) or the at least one filter stage (8) is formed a circuit for the mercury in the exhaust gases (1). To achieve a good mercury removal at the same time low cost is provided that in a region of the main flow of the exhaust gases (1) with a temperature of at least 300 ° C, a branch of a partial flow (13) from 1 to 30 vol% of the exhaust gases (1) is provided , wherein in the partial stream (13) at least one separator (14) and then at least one stage (17) is arranged for mercury deposition.
公开号:AT511543A1
申请号:T7332011
申请日:2011-05-20
公开日:2012-12-15
发明作者:
申请人:Scheuch Gmbh；
IPC主号:

专利说明:

I ··················································································
The invention relates to a method for the separation of mercury from the exhaust gases in cement clinker production, wherein the raw materials required for cement clinker production are abandoned in a countercurrent principle against the direction of the exhaust gases in a preheating and fired in a rotary kiln, wherein the heating of the raw materials in the preheating the evaporated mercury is vaporized in the raw materials and the exhaust gases conducted in a main flow are at least partially used for grinding drying of the raw materials in at least one raw meal mill and dedusted in at least one filter stage, and at least the dust deposited in the at least one filter stage is partially abandoned together with the ground raw material in the preheating, so formed between the preheating and the raw meal mill or the at least one filter stage, a circuit for the mercury in the exhaust gases w ill.
Furthermore, the invention relates to a device for the separation of mercury from the exhaust gases in the cement clinker production, with a preheating, a task for the required for cement clinker production raw materials in countercurrent principle against the direction of the exhaust gases in the preheating stage, a rotary kiln for firing the raw materials, at least one filter stage for dedusting the exhaust gases conducted in a main flow before they escape into the atmosphere, and at least one raw meal mill for at least partial mill drying of the raw materials, wherein a circuit for the mercury in the exhaust gases is formed between the preheating stage and the raw meal mill or the at least one filter stage.
In cement clinker production, various raw materials, such as limestone and clay, are fired in a rotary kiln. In many of the raw materials used, mercury is contained, which evaporates during heating in the preheating stage and is bound to the dust when the exhaust gases cool down. Most of the mercury is returned to the cement clinker production process with the dust separated in a filter stage, with only a small proportion escaping into the atmosphere with the exhaust gas. The mercury load is mainly entered via the raw materials in the process, 2
a portion of the mercury entry can also be made via the fuels.
The present patent application is directed primarily to the cement clinker production, but can also be used in other thermal production processes in which a pronounced circulation behavior of some exhaust gas pollutants is observed.
In principle, it is possible to remove or reduce the mercury present in the raw materials before it is used for cement clinker production. This is done for example by a treatment of the raw materials with hot gases, whereby the mercury contained can be at least partially evaporated and then deposited in concentrated form. However, the required warming of the raw materials requires relatively much energy, which increases the overall cost and makes the process uneconomical at high material throughputs.
Also, solutions in which the entire exhaust stream of the rotary kiln in the cement clinker production using certain emission control method for mercury removal, such as activated carbon filter is cleaned, are economically unacceptable due to the large amounts of air and thus required system size.
The object of the present invention is therefore to provide an above-mentioned method and device for separating mercury from the waste gases in the cement clinker production, by which a sufficiently high reduction of mercury emissions is made possible. Furthermore, as little additional energy as possible and the lowest possible volume of exhaust gas to be cleaned should be required and thus the operation and installation should be as cost-effective as possible.
In procedural terms, this object is achieved in that a partial flow of 1 to 30, in particular 5 to 20 percent by volume of at least 300 ° C warm exhaust gases is diverted from the main stream of the exhaust gases, and the exhaust gases of this partial stream first
• I I * * • φ • φ φ * 3 dedusted and then its mercury is separated. According to the invention, it is thus provided that only a small proportion of the main stream of exhaust gases is branched off and fed to at least partial dedusting and subsequent mercury removal. It is also essential that this diversion of the partial flow of the exhaust gases takes place in a region of the process in which at least a majority of the recirculated mercury is present in gaseous form. This is the case at temperatures from about 300 ° C, since mercury and its compounds have relatively low boiling temperatures. Investigations show that in the upper part of the preheating stage at temperatures between 300 and 450 ° C at least 80% of the mercury are gaseous (oxidized or elemental). The higher the proportion of gaseous mercury, the lower the amounts of exhaust gas must be treated in the partial flow in order to relieve the main exhaust gas flow to the same extent. Due to the fact that only part of the total amount of exhaust gas produced in cement clinker production has to be treated, the filter stages and devices for separating the mercury provided for this purpose can be made smaller and thus require less energy during operation. In particular, at Abscheidegraden, for example, 20-80%, the subject method and the subject device will be particularly inexpensive executable. The partial flow of the exhaust gases thus contains at least one high-temperature dust separation and at least one mercury separation.
It is advantageous if the temperature of the exhaust gases of the partial flow is lowered before the deposition of mercury. The temperature reduction can be done, for example, in a quench by injecting water. The temperature reduction can also be combined with the mercury deposition.
According to a further feature of the invention, it is provided that the dust deposited in the partial flow is returned to the preheating stage for energy reasons.
Advantageously, the exhaust gases of the partial flow are also returned to the main flow of the exhaust gases. Thus, the mercury removal takes place in a bypass of the main flow of the discharge... ··································································································. »I · · * 4 ............ gas in which only a partial flow of the exhaust gases is conducted.
To improve the energy balance of the process, the heat of the exhaust gases of the substream may preferably be recovered after dedusting and the recovered heat may be supplied to the purified substream prior to being returned to the main exhaust stream. The recovery of the heat may be via conventional heat exchangers or the like. Alternatively, the recovered heat can also be used at another location or used for power generation.
The partial flow of the exhaust gases, as seen in the flow direction of the exhaust gases, preferably diverted from the main stream of exhaust gases after or in the preheating stage. In the preheating stage or in the flow direction of the exhaust gases seen behind the preheating stage, the exhaust gases usually have a temperature above 300 ° C, so that it can be ensured that a large part of the mercury in the system is present in gaseous form.
At least a part of the dust of the exhaust gases, which is deposited in the at least one filter stage, can be added to the branched partial flow of the exhaust gases.
For the separation of the mercury in the partial flow of the exhaust gases, a bag filter can be used. By appropriate reduction in temperature, the originally largely gaseous mercury is condensed and the resulting particles can be separated from the filter material of the bag filter. The particles with the mercury bound therein are discharged from the bag filter at regular intervals and deposited or returned to the cement clinker production process.
The rate of deposition of the baghouse filter can be improved by adding at least one additive, such as a reactant (e.g., polysulfides, bromides), to change the physical properties of the mercury or adsorbents (e.g., activated carbon) to bind the mercury. # ♦ ♦ · ····· * * «· · · · · · · · · · · · · · · · · · # t φ · · ·· · ·« 5
As an alternative to the bag filter, the mercury can also be separated by means of a scrubber from the exhaust gases of the partial flow, wherein as washing liquid in particular metal sulfide solutions, limestone suspensions or acid scrubbers are used in combination with organisulfide precipitants, so that the mercury is concentrated after treatment of the waste water of the scrubber. In particular, when the deposited mercury has to be dumped, it is advantageous if it is correspondingly highly concentrated by the sheath method.
As an alternative to the methods described above, the mercury can also be separated from the exhaust gases of the partial flow with the aid of a fixed bed or moving bed adsorber. With a moving bed adsorber, in principle higher degrees of separation can be achieved, and the utilization of the sorbents used is higher than in the case of flight flow processes.
It is particularly advantageous if, according to a further feature of the present invention, the concentration of mercury in the main stream of the exhaust gases is increased. As a result of the increase in the concentration of mercury in the main stream, the mercury concentration in the partial stream is subsequently increased, as a result of which the achievable separation rates of the partial stream purification can be correspondingly increased. The increase of
Mercury concentration in the main stream can be done in several ways.
For example, the concentration of mercury in the main stream of the exhaust gases can be increased by optimizing the at least one filter stage in the main stream of exhaust gases for separating mercury and at least partially feeding the mercury separated in the at least one filter stage to the preheating stage. Thus, the mass flow of recirculated mercury is increased accordingly.
An improvement of the mercury removal in the at least one filter stage of the main stream of the exhaust gases can be achieved by adding additives, such as bromides, chlorides or activated carbon, at a suitable point in the exhaust path of the rotary kiln. Such additives change the modification of the mercury or bind the mercury and thus have a particularly favorable effect on the precipitation of the mercury in the at least one filter stage.
A further improvement of the mercury removal in the at least one filter stage of the main stream of the exhaust gases can be achieved by lowering the temperature before the at least one filter stage. In this case, heat exchangers or evaporative coolers for lowering the temperature to 60 ° C to 140 ° C, preferably 80 ° C to 120 ° C, are particularly suitable. Due to the reduced vapor pressure, the deposition of mercury in the at least one filter stage can be increased.
Further improvements can be achieved by increasing the mercury removal in the at least one filter stage of the main stream of the exhaust gases by a catalyst arranged between the preheating stage and the raw meal mill or the at least one filter stage, which alters the chemical bonding of the mercury. In such catalysts (e.g., tungsten and vanadium catalysts), the mercury is oxidized.
Improvements are achieved by adding a reactant upstream of the catalyst to alter the chemical bonding of the mercury. Bromides or chlorides are particularly suitable for this purpose.
The object of the invention is also achieved by an above-mentioned device for the separation of mercury from the exhaust gases in cement clinker production, wherein in a region of the main flow of the exhaust gases, in which the exhaust gases have a temperature of at least 300 ° C, a branch of a partial flow of the first is provided to 30, in particular 5 to 20 percent by volume of the exhaust gases, wherein in the partial flow at least one separator for dedusting the exhaust gases of the partial flow and then at least one stage for the separation of mercury from the exhaust gases of the partial flow is arranged. For the possible embodiments and advantages of the device according to the invention reference is made to the above description of the method for the separation of mercury from the exhaust gases in the cement clinker production. * * ::
The present invention will be explained in more detail with reference to the accompanying drawings.
Show in it
1 is a block diagram of a cement clinker manufacturing apparatus according to the prior art;
Fig. 2 is a block diagram of an apparatus for cement clinker production with an embodiment of the process for mercury silver deposition; and
3 is a block diagram of a cement clinker manufacturing apparatus with another embodiment of a mercury removal method.
Fig. 1 shows a block diagram of a device for cement clinker production according to the prior art. The raw material 10 needed for cement clinker production is countercurrently, i. against the direction A of the exhaust gases 1, in a preheating stage 2, which usually consists of a plurality of superimposed cyclones, abandoned. The corresponding preheated raw material 10 passes from the preheating stage 2 in the rotary kiln 3, where the material is fired to cement clinker. By means of a corresponding cooling and discharge device 4, the cement clinker is discharged and conveyed into corresponding silos (not shown). Before the exhaust gases exit into the atmosphere, they are at least partially fed to a mill-drying mill 6 in a raw meal mill or are cooled in a cooling device 5, such as an evaporative cooler, and dedusted in a filter stage 8. After that, the exhaust gases 1 pass through a vent 9 into the atmosphere. The separated dust 12 from the filter stage 8 and the ground raw material 11 from the raw meal mill 6 are mixed in a silo 7 and placed together as raw material 10 in the preheating stage 2. Due to the nature of the countercurrent flow of material and exhaust gas flow, a cycle for the mercury contained in the exhaust gases 1 is formed between the preheating stage 2 and the raw meal mill 6 or the at least one filter stage 8 through the material recycling. The mercury mass flow, which is recirculated, amounts to a multiple of the mercury input mass flow from the fresh raw materials 10 and fuels.
2 shows the block diagram of a possible installation of an embodiment of the method for the separation of mercury from the exhaust gases in the cement clinker production with an optimization of the filter stage 8 in the cement production process of Fig. 1. According to the invention, a partial stream 13 is withdrawn from the exhaust gases 1. In the illustrated example, the branch of the partial flow 13 of the exhaust gases 1 after the preheating stage 2. The partial flow 13 of the exhaust gases 1 is at least partially dedusted in a separator 14 and the separated dust 15 is returned in the embodiment shown in the preheating stage 2. After flowing through a cooler 21, the partial flow 13 is then admixed with additives 16 and the mercury is separated off in a separation stage 17, which is designed, for example, as a bag filter. The deposited at the separation stage 17 pollutants are discharged via the line 18 from the system. The separation of mercury in the main stream of exhaust gases 1 in the filter stage 8 can be accomplished by adding additives at different locations 19a (e.g., bromides), 19b (e.g.
Sulfides), 19c (e.g., activated carbon), depending on the required reaction or adsorption temperature.
In Fig. 3, a further embodiment of the deposition of mercury from the exhaust gases 1 in the cement clinker production is shown. The partial stream 13 is withdrawn after the preheating stage 2 from the exhaust gases 1 at a temperature of about 300 ° C and dedusted in the separator 14 at temperatures above 300 ° C. The separated dust 15 is returned to the preheating stage 2. The at least partially dedusted substream 13 of the exhaust gases 1 is cooled by a heat exchanger 20 with the purified substream 13 and cooled in the cooler 21 to a temperature of 60 to 200 ° C, preferably 80 to 140 ° C. To the cooled substream 13 are added additives 16 (e.g., activated carbon) which chemically or physically bind the mercury. The now bound to particles mercury is deposited at the separation stage 17, for example, a bag filter. The mixture of partially unused additives 16 and separated mercury can be at least partially recycled via the connecting line 22 in the unpurified partial stream 13 of the exhaust gases 1 or discharged via line 18 from the system. The purified partial stream 13 is reheated via the heat exchanger 20 and returned to the line of the exhaust gases 1.
The essence of the present method and apparatus is that only a portion of the exhaust gases 1 are treated to reduce mercury emissions to the atmosphere. By combining the increase in mercury concentration in the recirculated dust and material streams in the cement clinker production process and the treatment of a partial flow of the exhaust gases relatively good deposition rates, for example, from 20 to 80% can be achieved at the same time low acquisition and operating costs.
The advantages of the method and the device according to the invention are that existing systems can be converted relatively easily, and a good energy balance can be achieved. In particular, during operation, the method and the device is much cheaper than previously known and used methods.

权利要求:
Claims (34)
[1]
+ * ··· 4 4 4 4 4 * · · # ··· · · · · 4 * 444 m 4 4 4 4 4 4 4 4 4 4 4 4 · «· 10 Claims: 1. A process for the separation of mercury From the exhaust gases {1) in the cement clinker production, wherein the raw materials required for cement clinker preparation (10) in a countercurrent principle against the direction (A) of the exhaust gases (1) in a preheating stage (2) and burned in a rotary kiln (3) in that the warming of the raw materials (10) in the preheating stage (2) evaporates the mercury bound in the raw materials (10) and at least partially circulates the exhaust gases (1) guided in a main stream to the mill drying of the raw materials ( 10) are used in at least one raw meal mill (6) and are dedusted in at least one filter stage (8), and the dust (12) deposited in the at least one filter stage (8) is at least partially together with the milled raw material (11) in the preheating stage ( 2) abandoned is formed so that between the preheating stage (2) and the raw meal mill (6) or the at least one filter stage (8) a circuit for the mercury in the exhaust gases (1), characterized in that from the main stream of the exhaust gases (1) a partial stream (13) of 1 to 30, in particular 5 to 20 percent by volume of at least 300 ° C warm exhaust gases (1) is branched off, and the exhaust gases (1) of this partial stream (13) first dedusted and then the mercury is deposited.
[2]
2. The method according to claim 1, characterized in that the temperature of the exhaust gases (1) of the partial flow (13) is lowered before the deposition of mercury.
[3]
3. The method according to claim 1 or 2, characterized in that in the partial stream (13) separated dust is returned to the preheating stage (2).
[4]
4. The method according to any one of claims 1 to 3, characterized in that the exhaust gases (1) of the partial flow (13) are recycled back into the main flow of the exhaust gases (1).
[5]
5. The method according to any one of claims 1 to 4, characterized in that the heat of the exhaust gases (1) of the partial flow (13) is preferably recovered after dedusting.

• · · · · · · * * ♦ · * * * * φ • · * * * 11
[6]
6. The method according to any one of claims 1 to 5, characterized in that the partial flow (13) of the exhaust gases (1), seen in the flow direction (A) of the exhaust gases (1}, after or in the preheating stage (2) from the Hauptström the Exhaust gases (1) is diverted.
[7]
7. The method according to any one of claims 1 to 6, characterized in that the diverted partial flow (13) of the exhaust gases (1) at least a portion of the dust (12) of the exhaust gases (1), which in the at least one filter stage (8) deposited will be added.
[8]
8. The method according to any one of claims 1 to 7, characterized in that the mercury with the aid of a bag filter from the exhaust gases (1) of the partial flow (13) is deposited.
[9]
9. The method according to claim 8, characterized in that prior to the mercury separation, an additive (1.6), for example a reagent for changing the physical properties of mercury or adsorbing substances for binding the mercury, is added.
[10]
10. The method according to any one of claims 1 to 7, characterized in that the mercury with the aid of a scrubber from the exhaust gases (1) of the partial flow (13) is deposited.
[11]
11. The method according to any one of claims 1 to 7, characterized in that the mercury with the aid of a fixed or Wanderbettadsorbers from the exhaust gases (1) of the partial flow (13) is deposited.
[12]
12. The method according to any one of claims 1 to 11, characterized in that the concentration of mercury in the main stream of the exhaust gases (1) is increased.
[13]
13. The method according to claim 12, characterized in that the concentration of mercury in the main stream of the exhaust gases (1) is increased by the fact that the at least one filter stage (8) in the main stream of the exhaust gases (1) for the deposition of mercury opti- • φ φ Φ φ * φ * «· * * * # # φ ·« «• • * φ« φ «« «* * * und und und und und und und Filter Filter Filter Filter Filter ) separated mercury is at least partially supplied to the preheating stage (2).
[14]
14. The method according to claim 13, characterized in that the mercury deposition in the at least one filter stage (8) of the main stream of exhaust gases (1) by addition of additives, such as bromides, chlorides or activated carbon, is increased.
[15]
15. The method according to claim 13, characterized in that the mercury deposition in the at least one filter stage (8) of the main flow of the exhaust gases (1) by lowering the temperature before the at least one filter stage (8) is increased.
[16]
16. The method according to claim 13, characterized in that the mercury deposition in the at least one filter stage (8) of the main stream of exhaust gases (1) by a between the preheating stage (2) and the raw meal mill {6) or the at least one filter stage {8} arranged catalyst, which changes the chemical bond of the mercury, is increased.
[17]
17. The method according to claim 16, characterized in that a reaction agent for changing the chemical bond of the mercury is added before the catalyst.
[18]
18. A device for separating mercury from the exhaust gases (1) in the cement clinker production, with a preheating stage (2), a task for the required for cement clinker production raw materials (10) in a countercurrent principle against the direction (A) of the exhaust gases (1) in the Preheating stage (2), a rotary kiln (3) for burning the raw materials (10), at least one filter stage (8) for dedusting the guided in a Hauptström exhaust gases (1) before leaving the atmosphere, and at least one raw meal mill (6) at least partial grinding drying of the raw materials (10), wherein between the preheating stage (2) and the raw meal mill (6) or the at least one filter stage (8) a circulation for the mercury in the exhaust gases (1) is formed, characterized in that a branch of a main flow of the exhaust gases (1), in which the exhaust gases (1) have a temperature of at least 300 ° C, a branch of a partial flow (13) • * * · · ··· * • · «· * · *· T * · · • m 4 m * · «·« «• · * · · · | 1 to 30, in particular 5 to 20 percent by volume of the exhaust gases (1) is provided, wherein in the partial flow (13) at least one separator (14) for dedusting the exhaust gases (1) of the partial flow (13) and thereafter at least a step (17) for separating the mercury from the exhaust gases (1) of the partial flow (13) is arranged.
[19]
19. The apparatus according to claim 18, characterized in that prior to the step (17) for mercury separation, a device for lowering the temperature in the partial flow (13), in particular a cooler (21), is arranged.
[20]
20. The apparatus of claim 18 or 19, characterized in that between the separator (14) for dedusting the exhaust gases (1) of the partial flow (13) and the preheating stage (2) a line for returning the separated dust (15) is arranged.
[21]
21. Device according to one of claims 18 to 20, characterized in that a compound of the partial flow (13) with the main flow of the exhaust gases (1) for returning the exhaust gases (1) of the partial flow (13) into the main flow of the exhaust gases (1). is provided.
[22]
22. Device according to one of claims 18 to 21, characterized in that in the partial stream (13), preferably after the separator (14) for dedusting the exhaust gases, a heat exchanger (20) for recovering the heat of the exhaust gases (1) of the partial flow ( 13) is arranged.
[23]
23. Device according to one of claims 18 to 22, characterized in that the branch of the partial flow (13) of the exhaust gases (1), seen in the flow direction (A) of the exhaust gases (1), after or in the preheating stage (2) is arranged ,
[24]
24. Device according to one of claims 18 to 23, characterized in that between the at least one filter stage (8) in the main stream of the exhaust gases (1) and the partial flow (13) a line for returning at least a portion of the in the at least one filter stage ( 8) deposited dust (12) of the exhaust gases (1) is arranged. • · · «* ·« «t« • · · < I * «··« Φ «» «« t «· I t« 4 • · · ♦ * · «| 9 »· 14 ............
[25]
25. Device according to one of claims 18 to 24, characterized in that the step (17) for the mercury deposition in the partial flow (13) is formed by a bag filter.
[26]
26. The device according to claim 25, characterized in that in front of the bag filter, a conduit for the addition of an additive (16), for example, a reagent for changing the physical properties of the mercury or adsorbent substances for binding the mercury is arranged.
[27]
27. Device according to one of claims 18 to 24, characterized in that the step (17) for the mercury deposition in the partial flow (13) of the exhaust gases (1) is formed by a scrubber.
[28]
28. Device according to one of claims 18 to 24, characterized in that the step (17) for the mercury deposition in the partial flow (13) of the exhaust gases (1) is formed by a fixed or Wanderbettadsorber.
[29]
29. Device according to one of claims 18 to 28, characterized in that a device for increasing the concentration of mercury in the main stream of the exhaust gases (1) is provided.
[30]
30. The apparatus of claim 29, characterized in that the at least one filter stage (8) in the main stream of the exhaust gases (1) is optimized for mercury deposition and the deposited mercury at least partially the preheating stage (2) can be fed.
[31]
31. The device according to claim 30, characterized in that at least one supply line (19a, 19b, 19c) for the addition of additives, such as bromides, chlorides or activated carbon, is provided.
[32]
32. Apparatus according to claim 30, characterized in that before the at least one filter stage (8) of the main flow of the exhaust gases (1) means for lowering the temperature of the exhaust gases is arranged. * · # ·· ··· «· ·
[33]
33. Apparatus according to claim 29, characterized in that in the main stream of the exhaust gases (1) between the preheating stage (2) and the raw meal mill (6) or the at least one filter stage (8) is provided a catalyst for changing the chemical bond of the mercury ,
[34]
34. Apparatus according to claim 33, characterized in that upstream of the catalyst, a supply line for a reagent for changing the chemical bond of the mercury is arranged.

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同族专利:

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公开号 | 公开日

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AT511543B1|2013-12-15|

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EP2709962B1|2017-04-05|

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法律状态:
2019-01-15| MM01| Lapse because of not paying annual fees|Effective date: 20180520 |

优先权:

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申请号 | 申请日 | 专利标题

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AT7332011A|AT511543B1|2011-05-20|2011-05-20|METHOD AND DEVICE FOR MOLECULAR DEPOSITION IN CEMENTLINK MANUFACTURING|AT7332011A| AT511543B1|2011-05-20|2011-05-20|METHOD AND DEVICE FOR MOLECULAR DEPOSITION IN CEMENTLINK MANUFACTURING|

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US14/119,001| US9051215B2|2011-05-20|2012-05-21|Method and device for removing mercury during the production of cement clinker|

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EP12726718.5A| EP2709962B1|2011-05-20|2012-05-21|Method and device for removing mercury during the production of cement clinker|

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PCT/AT2012/000138| WO2012159137A1|2011-05-20|2012-05-21|Method and device for removing mercury during the production of cement clinker|