Granular material for absorption of harmful gases and process for production thereof

Abstract

A granular sorption material including a plurality of porous granules formed by buildup agglomeration for separation, especially absorption, of harmful gases, especially of SO.sub.X and/or HCl, from offgases of thermal processes. The granules containing greater than 80% by weight, and preferably greater than 95% by weight, of Ca(OH).sub.2 and/or CaCO.sub.3 based on the dry mass. The granules having a dry apparent density ρ, determined by means of an apparent density pycnometer, of 0.5 to 1.2 kg/dm.sup.3, preferably 0.7 to 1.1 kg/dm.sup.3, and/or a porosity of 45% to 73% by volume, preferably 55% to 65% by volume, and have especially been increased in porosity. A process for producing the granular sorption material, in which pores are introduced into the granules by means of a porosity agent during the production.

Claims

1. A granular sorption material comprising a plurality of buildup-agglomerated, porous granules for separation of harmful gases from offgases of thermal processes, the granules containing greater than 80% by weight of Ca(OH).sub.2 and/or CaCO.sub.3 based on the dry mass, the granules having a dry apparent density ρ, determined by means of an apparent density pycnometer, of 0.5 to 1.2 kg/dm.sup.3.

2. The granular sorption material according to claim 1, wherein the granular sorption material has a water content of 0.5 to 10 wt. % as determined by DIN EN 459-2.

3. The granular sorption material according to claim 1, wherein the granular sorption material has a specific surface, measured by BET, of 10 to 60 m.sup.2/g.

4. The granular sorption material according to claim 1, wherein the granular sorption material has a grain size distribution of 1 to 20 mm.

5. Use of the granular sorption material according to claim 1, comprising the steps of providing the granular sorption material in offgasses of a thermal process and removing at least one of SOx and HCl and HF from the offgases of the thermal process.

6. The use of the granular sorption material according to claim 5, further comprising the step of conducting the thermal process in a solids/offgas reactor.

7. The granular sorption material according to claim 1, wherein the granules have an increased porosity relative to porosity of pre-buildup-agglomerated granules.

8. The granular sorption material according to claim 1, wherein the granules having a dry apparent density ρ, determined by means of an apparent density pycnometer, of 0.7 to 1.1 kg/dm.sup.3.

9. A granular sorption material comprising a plurality of buildup-agglomerated, porous granules for separation of harmful gases from offgases of thermal processes, the granules containing greater than 80% by weight of Ca(OH).sub.2 and/or CaCO.sub.3 based on the dry mass, the granules having a porosity, determined from a dry apparent density ρ, determined by means of an apparent density pycnometer, and a specific density ρ.sub.0, determined with a helium pycnometer, of 45 to 73 vol. %.

10. The granular sorption material according to claim 9, wherein the granules have a porosity, determined from a dry apparent density ρ, determined by means of an apparent density pycnometer, and a specific density ρ.sub.0, determined with a helium pycnometer, of 55 to 65 vol. %.

11. A granular sorption material comprising a plurality of buildup-agglormerated, porous granules for separation of harmful gases from offgases of thermal processes, wherein the granules contain Ca(OH).sub.2 and/or CaCO.sub.3 as active substance, wherein the granules have an open pore system with pores created by means of a porosity agent during the production of the granular sorption material.

12. The granular sorption material according to claim 11, wherein the open pore system includes interconnected air pores, a portion of the air pores are the pores created by the porosity agent.

13. The granular sorption material according to claim 12, wherein at least some of the air pores emerge into the open on a grain outer surface of the granules, and wherein the open pore system is in communication with surroundings thereof via the air pores that emerge into the open.

14. The granular sorption material according to claim 11, wherein the granules contain primary particles which are agglomerated together.

15. The granular sorption material according claim 14, wherein the granules have a cluster of the primary particles which are agglomerated together, wherein the pore system interpenetrates the cluster.

16. The granular sorption material according claim 14, wherein the pores which are created by means of the porosity agent during the production of the granular sorption material are located between the primary particles.

17. The granular sorption material according to claim 11, wherein the granules contain greater than 50 wt. % of Ca(OH).sub.2 and/or CaCO.sub.3, in terms of the total solids fraction of the granules.

18. The granular sorption material according to claim 11, wherein the granules have greater than 50 wt. % to 99.9 wt. % hydrated lime and/or limestone meal and/or precipitated calcium carbonate and/or chalk, in terms of the total solids fraction of the granules.

19. The granular sorption material according to claim 11, wherein the pores created by means of the porosity agent are in part nearly spherical or tubular.

20. The granular sorption material according to claim 11, wherein the granules have a dry apparent density ρ, as determined by means of apparent density pycnometer, 0.7 to 1.1 kg/dm.sup.3.

21. The granular sorption material according to claim 20, wherein the granules have a specific density ρ0, as determined with a helium pycnometer, of 2.0 to 2.8 kg/dm.sup.3.

22. The granular sorption material according to claim 21, wherein the granules have a porosity of 45 to 73 vol. %.

23. The granular sorption material according to claim 21, wherein the granules have a porosity of 55 to 65 vol. %.

24. The granular sorption material according to claim 11, wherein at least some of the granules are coreless.

25. The granular sorption material according to claim 11, wherein at least some of the granules are multilayered and have a mother grain and at least one agglomerate layer encasing the mother grain.

26. The granular sorption material according to claim 25, wherein at least the mother grain and/or one agglomerate layer has the pores created by means of a porosity agent.

27. A method for producing the granular sorption material according to claim 11, wherein the granular sorption material is formed by buildup agglomeration, and wherein pores are introduced into the granules by means of a porosity agent before and/or during buildup agglomeration.

28. The method according to claim 27, wherein the granules are produced by granulation from one or more fresh mass(es) each containing water and at least one meal component containing Ca(OH).sub.2 and/or CaCO.sub.3, wherein the pores are introduced by means of the porosity agent into at least one of the fresh masses prior to granulation.

29. The method according to claim 27, wherein the porosity agent used is one of a blowing agent, an air entraining agent, and a ready prepared foam.

30. The method according to claim 29, wherein the blowing agent used is one of aluminum, zinc oxide and hydrogen peroxide.

31. The method according to claim 29, wherein the air entraining agent used is one of cocamide propyl betaine, sodium olefin sulfonate and sodium lauryl sulfonate.

32. The method according claim 27, wherein the granules are coreless and are prepared by means of buildup agglomeration from a homogeneous fresh mass, which contains at least one SOx absorbing Ca-component and water, and wherein the pores are introduced into the fresh mass by means of the porosity agent before and/or during the agglomeration.

33. The method according claim 32, wherein the SOx absorbing Ca-component used is one of limestone meal, hydrated lime, chalk meal, precipitated calcium carbonate, do-lomite meal and dolomite hydrate.

34. The method according to claim 27, wherein the multilayered granules are produced by means of stepwise buildup agglomeration from several fresh masses, each containing at least one SOx absorbing Ca-component and water, while at least one of the fresh masses contains the pores created by means of the porosity agent, wherein the pores are introduced into the at least one of the fresh masses by means of the porosity agent before and/or during the agglomeration.

35. The method according to claim 34, wherein mother grains are first created by means of buildup agglomeration from a first mixture containing water and then one or more agglomeration layers are applied to the mother grains by means of stepwise buildup agglomeration from other mixtures containing water.

36. The method according claim 27, wherein the granules contain primary particles which are agglomerated together and wherein the pores are introduced between the primary particles.

37. The granular sorption material according to claim 11, wherein the granules contain greater than 80 wt. % of Ca(OH).sub.2 and/or CaCO.sub.3, in terms of the total solids fraction of the granules.

38. The granular sorption material according to claim 11, wherein the granules contain greater than 95 wt. % of Ca(OH).sub.2 and/or CaCO.sub.3, in terms of the total solids fraction of the granules.

39. The granular sorption material according to claim 11, wherein the granules have greater than 80 wt. % hydrated lime and/or limestone meal and/or precipitated calcium carbonate and/or chalk, in terms of the total solids fraction of the granules.

40. The granular sorption material according to claim 11, wherein the granules have greater than 95 wt. % hydrated lime and/or limestone meal and/or precipitated calcium carbonate and/or chalk, in terms of the total solids fraction of the granules.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) In the following, the invention will be explained more closely with the help of a drawing as an example. There are shown:

(2) FIG. 1: schematically, a cross section of a granule of the granular sorption material according to the invention in a first embodiment of the invention.

(3) FIG. 2: schematically, a cross section of a granule of the granular sorption material according to the invention in another embodiment of the invention

DETAILED DESCRIPTION

(4) According to a first embodiment of the invention (FIG. 1), the granular sorption material according to the invention consists of a plurality of buildup-agglomerated, coreless granules 1. The coreless, uniform or monolithic granules 1 in familiar fashion have a cluster 2 of primary particles 3 agglomerated together (shown schematically as points in the figures). Monolithic in the sense of the invention means that the granules 1 have a homogeneous structure. Clusters in the sense of the invention are mixtures of solid particles which are loosely mingled or firmly joined to each other. The finely divided or finely dispersed primary particles 3 of the granules 1 according to the invention have a grain size ≦250 μm, preferably ≦90 μm. Thus, they are pulverized grains.

(5) The granules 1 contain, as their principal fraction in terms of weight, a SOx and HCl absorbing calcium compound in the form of Ca(OH).sub.2 and/or CaCO.sub.3. That is, the amount of Ca(OH).sub.2 or CaCO.sub.3 (if only one of the two components is present) or the sum of Ca(OH).sub.2 and CaCO.sub.3 (if both components are present) is >50 wt. % in terms of the total solids fraction of the granules 1. Preferably, the granules each time contain at least 80 wt. %, preferably at least 90 wt. %, of Ca(OH).sub.2 and/or CaCO.sub.3, in terms of the total solids fraction of the granules 1. Consequently, a principal fraction (>50 wt. %) of the primary particles 3 consists of Ca(OH).sub.2 and/or CaCO.sub.3. In particular, the primary particles 3 are chiefly (>50 wt. %) limestone meal grains and/or hydrated lime meal grains, in terms of the total fraction of primary particles 3.

(6) According to the invention, the coreless granules 1 furthermore each have an open pore system 4 of interconnected gas pores or air pores 5 filled with gas, especially air. The open pore system 4 is furthermore in communication with the outside through many of the air pores 5, which emerge into the open on a grain outer surface or outer grain surface 6. The pore system 4 is thus open to the outside. The open pore system 4 thus interpenetrates the entire granule 1, especially its cluster 2.

(7) Some of the air pores 5 according to the invention are pores 7 which have been created during the granulation process by means of a porosity agent. The granules 1 are thus made porous. The open pore system 4 according to the invention thus has air pores or gas pores 7 which were created during the granulation process by means of a porosity agent. These pores 7 result from the adding of a blowing agent, such as aluminum powder and/or aluminum paste, and/or an air entraining agent and/or a ready prepared foam to the fresh mixture or fresh mass during the granulation. It has been found, surprisingly, in the course of the invention that the pores 7 created by means of the porosity agent remain intact at least for the most part during the buildup agglomeration. In particular, while they are partly fragmented or disrupted, in any case they increase the open porosity of the granules 1 which is important to the gas absorption. This was not to be expected. In particular, the adding of a porosity agent appeared counter-intuitive.

(8) Thanks to the additional pores 7 created by means of the porosity agent, the granules 1 of the granular sorption material according to the invention have very large open porosity. The granules 1 made porous according to the invention are thus open to diffusion, so that the harmful gas being absorbed can penetrate almost without hindrance into the granules and no unwanted shell formation occurs. Of course, the overall porosity results not only from the pores 7 created by means of the porosity agent. Because the granules 1 furthermore also have cluster pores in familiar fashion, which are present between the individual primary particles 3. Moreover, compacting pores and/or evaporation pores are also present in familiar fashion.

(9) The pores 7 created by means of a porosity agent often have a nearly spherical shape or sphere shape. Moreover, at least some of them are macropores with a pore size >50 μm. Thus, it is distinctly evident from the finished granule 1 that it has pores 7 created by means of a porosity agent. Some of the pores 7 can also be tubular in shape.

(10) An additional potential of the pores 7 created by means of a porosity agent which can be utilized is their water storage capacity. It is presumed that the pores 7 according to the invention also serve to interrupt the capillary pore system of the granules 1. At least it has been discovered in the course of the invention that capillary water bound in the granules 1 is better retained and can still be made available for the reaction even at high temperatures. This is known to favor the reaction between the SO.sub.x containing offgas and the limestone meal or the hydrated lime, since water for dissolving of SOx is present on the surface of the limestone meal grains or the hydrated lime meal grains and the formation of calcium sulfate occurs from the solution. This likewise improves the separation performance of the granular sorption material according to the invention. The water content of the granular sorption material according to the invention in particular amounts to 0.5 to 10 wt. %, preferably 1 to 5 wt. %, as determined by DIN EN 459-2.

(11) The porosity, as is known, indicates the ratio of the volume of voids to the total volume and is thus a dimensionless quantity. The porosity is calculated by

(12) $\varphi =\left(1-\frac{\rho }{\rho o}\right)\times 100\%$
from the specific density ρ.sub.0 and the dry apparent density ρ.

(13) Preferably, the granules 1 of the granular sorption material according to the invention, especially when they consist by >80 wt. %, preferably >95 wt. %, of Ca(OH).sub.2 and/or CaCO.sub.3, have a dry apparent density ρ of 0.5 to 1.2 kg/dm.sup.3, preferably 0.7 to 1.1 kg/dm.sup.3. That is, the low dry apparent density ρ is accomplished according to the invention even without or with only slight addition of other porous primary particles, such as CSH pulverized grains. The specific density ρ.sub.0 of these granules 1, which is independent of the porosity, is advantageously 2.0 to 2.8 kg/dm.sup.3, especially 2.0 to 2.4 kg/dm.sup.3, preferably 2.1 to 2.3 kg/dm.sup.3. For the determination of the apparent density ρ one will preferably use the apparent density pycnometer GeoPyc from Micromeritics. In this case, a glass cylinder is filled with DryFlo™, a fine-sand mixture of Teflon beads and some graphite as lubricant, which behaves similar to a liquid. The cylinder is clamped and the instrument determines, by pushing forward the cylinder piston with simultaneous vibration/rotation of the cylinder, the volume of the DryFlo™ mixture. The specimen is then placed in the cylinder, so that it is submerged in the DryFlo™ mixture and the volume is determined in the same way for the mixture of DryFlo™ and specimen. Since DryFlo™ does not penetrate into the pores. one gets the total volume of the specimen (i.e., including pore space) and from this the dry apparent density. The specific density ρ.sub.0 is determined with a helium pycnometer, especially the helium pycnometer accupyc of the Micromeritics company. When determining the specific density ρ.sub.0 by means of helium pycnometer, two specimen containers whose volumes are exactly known are connected together across a valve. One of the containers is filled with the specimen and then evacuated. The second container is filled with helium at a predetermined pressure. By opening the valve, the pressure is equalized. From the final pressure, one can determine the volume occupied by the specimen. And from the volume and the previously determined weight, the specific density is calculated. The calculation of the densities is done on dried specimens. For this, similar to the determination of the moisture content of hydrated lime per DIN EN 459-2:2010-12, the specimens have been dried at 105° C. in a drying cabinet until the weight is constant.

(14) The porosity of the granules 1 according to the invention as determined from the apparent and specific density, especially when they consist by >80 wt. %, preferably >95 wt. %, of Ca(OH).sub.2 and/or CaCO.sub.3, is advantageously 45 to 73 vol. %, preferably 55 to 65 vol. %.

(15) Based on the high fraction of pores 5;7, the granular sorption material according to the invention has a very slight bulk density. The bulk density of the granular sorption material according to the invention is advantageously 0.5 to 0.9 kg/dm.sup.3, preferably 0.5 to 0.8 kg/dm.sup.3. Despite the pores 5;7, the grain strength and abrasion resistance are very good. The granular sorption material according to the invention preferably has an abrasion resistance of <5 wt. %, preferably <2 wt. %, determined by means of abrasion tester of the Erweka company. The specific surface of the granular sorption material according to the invention measured according to BET is advantageously 10 to 60 m.sup.2/g, preferably 20 to 45 m.sup.2/g.

(16) Furthermore, the granular sorption material according to the invention advantageously has a grain size distribution of 1 to 20 mm, preferably of 2 to 10 mm, especially preferably of 2 to 6 mm.

(17) Advantageously, moreover, the granules 1 have at least one binding agent, especially a film-forming one, especially starch and/or methylcellulose and/or carboxymethylcellulose and/or glucose and/or lignin and/or alginate and/or clay minerals, preferably bentonite. The binding agent creates an adhesive force between the individual primary particles 3 of the cluster 2. Consequently, the binding agent serves to solidify the granules and to boost the grain strength and abrasion resistance of the granules 1 according to the invention. Furthermore, it stabilizes the pores 5;7.

(18) Furthermore, it is of course within the scope of the invention for the granules 1 to contain other desulphurization agents, such as dolomite hydrate ((Ca(OH).sub.2.MgO or ((Ca(OH).sub.2.Mg(OH).sub.2) and/or dolomite meal ((Ca,Mg)CO.sub.3) and/or sodium hydrogen carbonate (NaHCO.sub.3) and/or soda (Na.sub.2CO.sub.3). Additional adsorption and/or absorption agents, including those for other harmful gases, can also be present, such as zeolites and/or activated charcoal and/or activated coke and/or laminar silicates. In this way, other pollutants such as mercury can be removed from the offgases being cleaned. The additional adsorption and absorption agents likewise form part of the primary particles 3 of the cluster 2.

(19) Of course, the granules 1 moreover can also contain other known additives which improve the separation performance, especially compounds of the alkaline metals. For example, the granules can contain one or more of the following alkaline metals: sodium chloride, sodium hydroxide, sodium nitrate, sodium phosphate, sodium bromide, potassium chloride, potassium hydroxide, potassium hydrogen carbonate, potassium carbonate, potassium nitrate, potassium phosphate or potassium bromide. Preferred amounts of the bound alkaline metals are 0.5 to 5 mol % in terms of the dry substance of limestone and/or hydrated lime.

(20) Furthermore, the granules 1 can also contain additionally pulverized grains of a porous mineral product, such as fine-grained aerated concrete according to DE 10 2011 112 657 A1 or materials with slight specific density. The granules 1 can also have finely divided, shredded cellulose material according to DE 10 2011 113 034 A1. Both of these further improve the diffusion of the harmful gas into the interior of the granules 1. Both the porous pulverized grains and the shredded cellulose material likewise form primary particles 3 of the cluster 2.

(21) The granular sorption material according to the invention advantageously contains as its main fraction (wt. %), in terms of the total solids fraction, hydrated lime and/or limestone meal. In particular, the granular gas absorption material according to the invention has >50 to 99.9 wt. %, preferably >80 wt. %, especially >95 wt. % of hydrated lime and/or limestone meal, in terms of the total solids fraction.

(22) According to a second embodiment of the invention, the granular sorption material according to the invention has multilayered granules 8 (FIG. 2). The granular sorption material can have both the coreless granules 1 and the multilayered granules 8 or only one kind. The multilayered granules 8 each have an inner mother grain or an inner core 9 and at least one, advantageously several agglomerate layers 10 arranged around the mother grain 9 and bordering on each other. Both the mother grain 9 and the agglomerate layers 10 are composed analogously to a coreless granule 1. That is, the agglomerate layers 10 and the mother grain 9 each have a cluster 2 of primary particles 3 agglomerated to each other, being principally limestone meal grains and/or hydrated pulverized lime grains. Moreover, the pores 5;7 according to the invention are present between the primary particles 3, so that the multilayered granules 9 also have the open pore system 4. That is, the pores 5;7 of the individual agglomerate layers 10 and of the mother grain 9 are likewise interconnected. Furthermore, the agglomerate layers 10 and the mother grain 9 can contain, as described above, at least one binding agent, additional adsorption/absorption agents, especially desulphurization agents, and/or additives. For example, the individual agglomerate layers 10 and the mother grain 9 can be different in terms of the content or fraction of the individual components. The agglomerate layers 10 and the mother grain 9 in this case have different material compositions.

(23) The above indicated values in terms of the bulk density, the porosity, the water content, the grain strength, the specific surface, as well as the grain sizes of the granular sorption material according to the invention with the coreless granules 1 apply equally to the granular sorption material made from or with the granules 8 with mother grain 9.

(24) In the following, the production of the granular sorption material according to the invention will now be explained:

(25) The production is done, as already mentioned, by means of buildup agglomeration (moist granulation). For example, the production is done by means of roll agglomeration, such as in a plate granulator (also known as a pelletizer plate), a granulating cone or a granulating drum, or by mix granulation in a granulating mixer or by means of fluid bed or fluidized bed granulation.

(26) The granular sorption material with the coreless granules 1 is produced by buildup agglomeration from a homogeneous fresh mass or a mixture containing at least one SO.sub.x absorbing calcium meal component (i.e., a meal containing Ca(OH).sub.2 and/or CaCO.sub.3), such as limestone meal and/or hydrated lime and/or chalk and/or precipitated calcium carbonate and/or dolomite meal and/or dolomite hydrate, water, as well as at least one porosity agent. The porosity agent is a blowing agent and/or an air entraining agent and/or ready prepared foam. The production of the fresh mass can be done either by preparing a thin slurry or sludge, which is gradually brought to the desired consistency by adding the pulverized solids little by little. Alternatively, water is added little by little to a mixture of solids until the desired consistency is reached, so that granulation can be done.

(27) It is of special benefit that the hydrated lime used must not—as required for example by the construction lime standard DIN EN 459-1:2010-12—have moisture (free water)<2%, but rather it can have production-dependent high moisture of up to 25 wt. %. Hydrates with specific production-related high moisture content can thus be put directly into the pelletizer, and the cost intensive drying process can be omitted.

(28) A blowing agent or also gas forming agent in the sense of the invention reacts in alkaline medium to form gas. In particular, the blowing agent used according to the invention is aluminum (e.g., in the form of aluminum powder and/or paste) and/or zinc oxide and/or hydrogen peroxide. The blowing agent is preferably added to the slurry together with or shortly after the adding of the hydrated lime and/or limestone meal. Since the outgassing and thus the pore formation occurs at once, no waiting time is needed before granulation can be done. However, it is possible for gas formation to occur even during the granulation, until such time as all of the blowing agent has been reacted.

(29) Air entraining agents in the sense of the invention are agents which introduce a certain amount of small, uniformly distributed, spherical air pores during the mixing process of the water-containing mixture. Air entraining agents are known as additives for concrete. The stabilization of the air pores in the water-containing mixture is done by adsorption on surfaces and reduction of the surface tension of the water. In the context of the invention, the air entraining agent used is preferably cocamide propyl betaine and/or sodium olefin sulfonate and/or sodium lauryl sulfate. The air entraining agent is preferably added likewise together with or shortly after the adding of hydrated lime or limestone meal to the slurry. The pore formation occurs in familiar manner upon mixing and is dependent on the mixing intensity.

(30) For the adding of the ready prepared foam, at first a foam is produced with the help of a foaming device and a foaming agent with many uniformly divided spherical air pores. This ready prepared form is then added to the previously prepared fresh mass of limestone meal and/or hydrated lime and water and optionally other ingredients. In the context of the invention, polypeptide alkylene polyol and/or sodium olefin sulfonate and/or coco alkyl dimethyl aminoxide is used preferably as the foam concentrate.

(31) In the preparation of the multilayered granules 8, at first the mother grains 9 are prepared by buildup granulation similar to what was described above. Next, the mother grains 9 are coated little by little in steps by means of buildup agglomeration with one or more agglomerate mixtures to form the agglomerate layers 10. The individual agglomerate mixtures likewise contain at least limestone meal and/or hydrated lime, water, as well as at least one porosity agent according to the invention.

(32) After the granulation, the granules 1,8 are preferably dried.

(33) In the following, preferred compositions of the dry mass for the preparation of the granular sorption material according to the invention, especially granular gas absorption material, are indicated. The individual ingredients can be combined with each other to make up 100 wt. %, while the binding agent and the additives are only preferably present:

(34) TABLE-US-00001 Content per total dry weight [wt. %] preferably Absorption agent Hydrated lime and/or .sup. 80-99.9   95-99.9 limestone meal Porosity agent Aluminum 0.02-0.2  0.03-0.1 Air entraining agent 0.02-0.5  0.05-0.2 Binding agent Starch <4 <2 Methylcellulose <3 <1 Bentonite <8 <5 Additive Sodium carbonate 0-5 Potassium carbonate 0-5 Sodium hydroxide 0-3

Sample Embodiment

(35) From the following composition a fresh mass was prepared and a granular material of coreless granules was produced by buildup agglomeration. The air entraining agent was added together with the hydrated lime to the slurry. The water content of the fresh mass, in terms of total mass, was 33 wt. %:

(36) TABLE-US-00002 Hydrated lime 99.3 wt. %  Starch (starch ether) 0.6 wt. % Air entraining agent (sodium lauryl sulfate) 0.1 wt. %

(37) The resulting granular material had a very high open porosity and therefore excellent properties in regard to absorption of SO.sub.x.

(38) As already explained, it was discovered surprisingly in the course of the invention that it is possible to add porosity agents to the fresh mass or mixture for the buildup agglomeration and thereby produce an open pore system in the granules. In particular, it is surprising that the pores generated are not destroyed during the granulation and remain stable even after the drying. In particular, the air entraining agent seems to stabilize all pores of the open pore system. Thanks to the resulting interconnected pores, the granules according to the invention have low dry apparent density with high Ca(OH).sub.2 and/or CaCO.sub.3 content of >80 wt. %, preferably >95 wt. % and are open to diffusion. The harmful gas being absorbed can penetrate into the interior of the granules and the unwanted shell formation is prevented. This leads to a very high separation performance of the granular gas absorption material according to the invention. Of course, it is also within the scope of the invention for the granules to contain closed pores. But their fraction is small.

(39) But the pores apparently also interrupt the capillary pore system of the granules. Thanks to this, the capillary water bound in the granules is better retained and is available for the reaction even at high temperatures. This also favors the reaction between the SO.sub.x containing offgases and the CaCO.sub.3 and Ca(OH).sub.2 and further improves the separation performance of the granular gas absorption material according to the invention.

(40) Of further advantage to the granular sorption material according to the invention is the catalytic action of lime in the breaking down of organic compounds. This has a positive influence on the reducing of harmful organic hydrocarbons in the smoke gas.

(41) It is also within the scope of the invention that not all agglomerate layers of the multilayered granules have the pores generated according to the invention, although this is preferable. Neither does the mother grain absolutely have to have the pores. But according to the invention at least one of the agglomerate layers or the mother grain has the pores, in order to ensure the diffusion of the harmful gases through the multilayered granules. The other agglomerate layers or the mother grain then have porous CSH meal grains, for example, so that the open porosity of the granules is preserved.

(42) As already mentioned in the course of the production, it is within the scope of the invention to use, instead of limestone meal or hydrated lime or additionally, as Ca(OH).sub.2 and/or CaCO.sub.3 containing desulphurization agent or Ca(OH).sub.2 and/or CaCO.sub.3 containing SO.sub.x absorbing agent, respectively precipitated calcium carbonate (PCC) and/or precipitated calcium magnesium carbonate and/or chalk and/or dolomite meal and/or dolomite hydrate (slaked dolomite). PCC (precipitated calcium carbonate) is synthetic or synthetically produced calcium carbonate (CaCO.sub.3). PCC is also known as precipitated calcium carbonate. In contrast with this, GCC (ground calcium carbonate) is ground calcium carbonate of natural origin (=limestone meal). The production of PCC is done by reacting carbon dioxide with milk of lime. The milk of lime is produced either by slaking of quicklime or by dispersing of calcium hydroxide in water. Calcium magnesium carbonate is produced accordingly.