DE3228532A1 - Process for carbonizing and gasifying carbonaceous solids - Google Patents

Abstract

The invention relates to a process for the fluidised-bed carbonization and gasification of carbonaceous solids, oxygen-containing compounds of the alkali metals and alkaline earth metals being added and the heat energy required for gasification being supplied by indirect heating of the gasification zone. In this way, a gasification product of high calorific value and low pollutant content is obtained in a operationally simple manner and with simple plant engineering means.

Description

Process for carbonization and gasification of

carbonaceous solids The invention relates to a method for fluidized bed carbonization and gasification of carbonaceous solids, water vapor being introduced into the fluidized bed to gasify the solids.

Such a process is already known as the Winkler process known for coal gasification for a long time (see Franck / Knob, Kohlenveredelung, Springer-Verlag 1979, p, 162), but only very reactive coal can be used here are used, which have a grain size of 1 to 10 mm and up to one Moisture content of 8 to 10% must be dried. A major disadvantage this known method therefore consists in that for processing the coal required effort. It is also unfavorable that the air supply that is intended for the direct heating of the fluidized bed used for carbonization and gasification is necessary is, a strong dilution and thus a rather poor calorific value of the gasification product brings with it.

A further development of this procedure has resulted in the last few years for high-temperature pressurized gasification of coal in the fluidized bed (see chemical engineering 11: 5.93-98 (1982)). The coal gasification takes place in a fluidized bed below a gasification pressure of about 10 bar, the one with a refractory brick lining lined high pressure tor directly (through substoichiometric Partial combustion) is heated. The main disadvantage of this process is the due to the high-pressure-high temperature conditions required high level of technical equipment Expenditure.

The invention is therefore based on the object, avoiding the to create a new process with simple plant engineering Means a smoldering and gasification of carbonaceous solids of all Art without complex prior preparation and with a slight adjustment to different Permitted operating conditions and at the same time to a gasification product of high Calorific value leads.

According to the invention, this object is achieved by the following features: a) The carbon-containing solids are oxygen-containing compounds of the Alkali and alkaline earth metals added; b) at least part of the gasification The heat energy required is fed to the gasification zone by indirect heating.

The carbonaceous solids become oxygenated compounds the alkali and alkaline earth metals added, a number of advantageous before Effects one of which, above all, a catalytic effect of these additives in the Fluid bed heard. Through these additives in particular catalytically influences the water-gas reaction that occurs during gasification in such a way that that there is a substantial lowering of the necessary gasification temperature.

This lowering of the gasification temperature makes it possible to a Refractory lining of the fluidized bed reactor to be dispensed with and an indirect one Provide heating of the gasification zone (on the floor and / or on the peripheral wall). Such indirect heating of the gasification zone has the great advantage that the gasification product is not replaced by the gaseous gas required for heating Medium is diluted. In this way, the gasification product has a particularly high calorific value achieved.

In addition to the catalytic effect (which mainly lowers the Gasification temperature with the other advantages mentioned above) result from the addition of oxygen-containing compounds of the alkali and alkaline earth metals still other advantages. This represents a substantial increase in the yield of carbonization gas and tar during the carbonization and, at the same time, a decrease in the volume of condensation water fixed. This desired effect can be based on the fact that - the swelling partially relocated - a gasification of the already formed coke with its own moisture the carbon-containing solids and with the cracked water produced during pyrolysis occurs. By adding the oxygen-containing compounds of the alkali and alkaline earth metals pollutants (especially Sulfur compounds, however also hydrohalic acids) and remain in the solid residue. as well are phenols, which in thermal coal processing act as acidic organic Compounds arise from the basic substances in the non-volatile salts the alkali and alkaline earth metals transferred. They stay longer than solids Time in the lower area of the fluidized bed and are largely cracked as a result. These toxic phenols do not get into the condensate of the gas scrubbing. The gaseous discharge of highly toxic acid cyanide compounds is also prevented their reaction with the substance-containing compounds of the alkali and alkaline earth metals highly limited.

According to a first expedient embodiment of the invention Procedure, the carbonization and the gasification are arranged in two on top of each other Zones of a single, indirectly heated fluidized bed reactor carried out, wherein the gasification product arising in the gasification zone is also the fluidization medium forms for the smoldering zone arranged above and that consists of carbonization gas and gasification product existing mixed gas is withdrawn from the upper part of the reactor. This method is characterized by a particularly high calorific value of the (not diluted by flue gases) Gasification product, also by a very space-saving design of the reactor.

In a second variant of the method according to the invention, the Carbonization in a vortex that is directly heated by substoichiometric combustion layer reactor and the gasification is carried out in an indirectly heated fluidized bed reactor, wherein the carbonization gas withdrawn from the carbonization zone is at least a part of the fluidization medium forms for the gasification zone. One advantage of this procedure is the special simple construction of the directly heated fluidized bed reactor used for the carbonization. It is also possible to have several such directly heated ones that are used for carbonization Fluidized bed reactors on a common, used for gasification, indirectly to let the heated fluidized bed reactor work.

Should carbon-containing solids with a high inherent moisture content (such as undried Brown coal or peat with high.

Water content) be dried, carbonized and gasified, so it has Proven to be advantageous if the smoldering zone has a separate drying zone is connected upstream and that arises during the drying of the carbonaceous solids steam-containing vapors at least a part of the gas fed to the gasification zone Form fluidization medium. Since these vapors have a high water vapor content, must - if at all - only what is necessary for the stoichiometric conversion, proportionally small residual amount of water vapor can also be introduced into the gasification zone. The use of the vapors in the drying zone as fluidization and gasification medium of the gasification zone thus results in a substantial energy saving.

The supply of steam is expediently regulated in such a way that an excess pressure of up to 5 bar, preferably between 300 and 1000, in the gasification zone mm WS. In the experiments on which the invention is based, namely showed that in this area of a slight mountain pressure the optimum of the gasification reaction lies. Within this pressure range, on the one hand, the water vapor can be sufficiently Diffuse proportions on and into the coal, while on the other hand the reaction products can diffuse out of the coal. For both processes exist in the fluidized bed ideal conditions.

A temperature is expedient in the smoldering zone and in the gasification zone between 600 and 800 "C, preferably between 650 and 7500C.

This relatively low reaction temperature is above all by the added oxygen-containing compounds of the alkali and alkaline earth metals enables. The lowering of the temperature to be maintained in the gasification zone is also with a view to using those expelled in the drying zone Vapors as fluidizing and gasifying agents in the gasification zone are advantageous. In this way, the vapors in the gasification zone only need substantially to be heated up less, which results in a considerable energy saving.

The carbonaceous solids are expediently 1 to 7.5% by weight, preferably 1.5 to 2.5% by weight, of oxygen-containing compounds of the alkali and alkaline earth metals added. Calcium hydroxide and calcium carbonate are particularly suitable and / or calcium oxide, each added in fine-grain form will.

at least / part of the oxygen-containing compounds of the alkali and alkaline earth metals will be the carbonaceous solids before their Feed into the smoldering zone, preferably in an upstream drying zone added. This ensures a good mixing of these aggregates with the carbonaceous ones Solids reached before they enter the smoldering zone and then into the gasification zone reach.

In order to optimally adapt the operating conditions to the respective conditions and especially if the input material changes within the desired According to the invention, staying within limits of the pollutant content of the exhaust gases can be a part of the oxygen-containing compounds of the alkali and alkaline earth metals the carbon-containing ones Solids are only added in the gasification zone. The ones in the fluidized bed Any intense reaction that occurs ensures that the process can be adapted quickly to changing operating conditions.

In addition to the oxygen-containing compounds of the alkali and According to the invention, alkaline earth metals can also be added to the carbonaceous solids Oxygen-containing iron compounds and / or iron scrap are added.

Further features of the invention are the subject of the subclaims and are in the appendix with the following description of some exemplary embodiments explained.

In the drawing, FIGS. 1 and 2 each show an exemplary embodiment Plant for carrying out the method according to the invention.

The plant according to FIG. 1 contains an indirectly heated fluidized bed reactor 1, in which, one above the other, a fluidized bed smoldering zone 2 and a fluidized bed gasification zone 3 are arranged. A hearth furnace 4 is connected upstream of the reactor 1, in which a Drying zone 5 is located. The hearth furnace 5 stands over a material line 6 with a material lock 7 with the smoldering zone 2 of the reactor 1 in connection.

The fluidized bed smoldering zone 2 is supported on a sieve tray 8 and the gasification zone 3 on a sieve tray 9. Both sieve trays 8, 9 are the same like the jacket 10 of the reactor 1 heated indirectly.

The smoldering coke arrives from the smoldering zone 2 via a suitable one Conveyor devices 11, 12 and a material lock 13 provided material line 14, into the gasification zone 3. The ash is discharged from the gasification zone 3 through a conveyor 15.

A separator 16 is connected downstream of the reactor 1.

The dust separated therein is passed through a line 17 to the gasification zone 3 supplied.

The gas dedusted in the separator 16 reaches a combustion chamber 18 (which is supplied with air at 19).

Part of the smoke generated in the combustion chamber 18 gases is fed to the reactor 1 via the lines 20, 21 and is used for indirect The sieve trays 8, 9 and the jacket 10 are heated. After the reactor 1 has been heated, arrive the hot gases to the hearth furnace 4 via a heat exchanger 22 the air for the combustion chamber 18 is preheated.

The remaining part of the flue gases emerging from the combustion chamber 18 is fed to a heat exchanger 24 via line 23.

The vapors produced in the drying zone 5 pass through a Line 25 as a fluidization medium in the gasification zone 3. In addition, the gasification zone 3 additional steam (at 26) and part of the mixed gas dedusted in the separator 16 (Line 27) supplied.

The carbonaceous solids to be carbonized and gasified - expediently together with the oxygen-containing compounds of the alkali and alkaline earth metals - added to hearth furnace 4 at 28.

Part of the oxygen-containing compounds of the alkali and alkaline earth metals can be introduced separately into the gasification zone 3.

As can be seen from FIG. 1, that which arises in the gasification zone 3 forms Gasification product (arrows 29) at the same time the fluidization medium for the above arranged smoldering zone 2. The mixed gas (arrows 30) is from the upper part of the Reactor 1 withdrawn. A part of this mixed gas passes through line 27 as Fluidizing medium in the gasification zone 3 (after heating in a heat exchanger 20a).

Procedural details of a possible mode of operation of the The system according to FIG. 1 results from an example explained later.

In Figure 2 is a further embodiment of a system for implementation of the method according to the invention shown. It contains one through substoichiometric Combustion directly heated fluidized bed reactor 31, which forms a smoldering zone 32, and an indirectly heated fluidized bed reactor 33 with a gasification zone 34. The drawing is kept very schematic; the reactors 31, 33 become in a practical design usually arranged very close to one another, possibly connected to a single structural unit.

The smoldering zone 32 is preceded by a drying zone 35, which is shown in FIG is constructed in the same way as in FIG. 1 and is therefore not explained in more detail.

A combustion chamber 36 is also connected to the reactor 31, the Carbonization gas is supplied via a line 37 and preheated air via a line 38 will.

The upper region of the reactor 31 is via a line 39 with a Separator 40 connected. The carbonization gas dedusted in the separator 40 is via a Line 41 fed to a combustion chamber (not shown). A part of the from the Separator 40 withdrawn carbonization gas is via a line 42 and an actuator 43, after being heated in a heat exchanger 56, is fed to the combustion chamber 36 on the one hand and on the other hand (via a line 44) as Fluidizing medium the reactor 53. The fluidized bed reactor 33 also receives plumbing medium via line 45 (vapors from drying zone 35), furthermore in the form of additional Steam (line 46).

The one from the smoldering zone 32, for example, via a height-adjustable Charcoal coke drawn off overflow 47 passes via a line 48 (which is in a simple Chute may exist) into the gasification zone 34, the entry devices 49 are also illustrated very schematically. It will also be the gasification zone 34 from the separator 40 the fine-grained solids separated in it (smoldering coke and lime) supplied via a line 50.

The gasification product withdrawn from the reactor 33 passes through a Separator 51 to a (not shown) combustion chamber (line 52). The one in the separator 51 deposited solids (ash) represent a solid residue of the process dar (line 53).

The same applies to that withdrawn from the gasification zone 34 at 54 solid residue.

For the indirect heating of the reactor 33 are used in the illustrated Embodiment from a (not shown) combustion chamber via a line 55 coming hot flue gases.

It goes without saying that Si the embodiments shown in FIGS a plant for carrying out the method according to the invention, the plant engineering Details within the scope of the invention be modified many times can. For example, indirect heating of the fluidized bed reactor can also be used other way than with hot gases, such as electro-inductive or under Use of immersion burners that protrude into the fluidized bed. The indirect one The fluidized bed cannot only be heated by the floor or an external heating jacket take place, but alternatively or additionally also through pipes or partitions that pass through the fluidized bed, preferably in a vertical direction, and are flowed through by the medium used for heating. Can also be beneficial the circumference of the fluidized bed with rib-like heating walls to enlarge the surface be provided.

Both the smoldering zone and the gasification zone can also each consist of several superimposed fluidized beds, with also for the good connection of the individual fluidized beds known different solutions are (side discharge, overflow pipes, etc.). The one surrounding the fluidized bed Space can advantageously be expanded upwards, thereby creating a gas calming space through which a reduction in the amount of dust discharged is achieved.

In the embodiment of Figure 2, the fluidization of the Fluidized bed in the gasification zone also with that from the gasification zone instead of carbonization gas withdrawn Vor.gasungsprodukt take place, which a condensate-free, hydrogen-rich and therefore very clean, suitable for chemical syntheses gas supplies. The excess water vapor introduced into the gasification zone is thereby additionally exploited.

As far as carbonization gas is used to fluidize the gasification fluidized bed is, can - in a modification of the scheme according to Figure 2 - this carbonization gas previously thermally be cracked. This avoids caking in the fluidized bed and achieves this an increase due to the increase in temperature of the gas used for fluidization the energy supply to the fluidized bed. The one produced when the carbonization gas is cracked Cracked soot can be introduced into the gasification fluidized bed and improved the efficiency or the yield of the gasification.

The start-up of a system according to Fig. 1 can be done with Wa? An, nitrogen, Steam or inert gas take place. To start up the system according to Fig. 2 is appropriate Natural gas is introduced into the directly heated smoldering zone and water vapor is introduced into the gasification zone.

Finally, it is also possible to add the gasification zone 34 to the vapors (line 45) and any further steam (line 46) still air and / or to supply oxygen, in order in this way a partial direct heating to undertake the gasification zone, which is a particularly simple heating and a light Keeping the gasification temperature constant.

Example 1 (charring and gasification according to Fig. 1 carbonaceous Solids: Rhenish lignite Composition: 21.5% C 54% H2O 5% ash 18.5 % volatile constituents 1% sulfur a) Carbonization and gasification with the addition of lime Addition of 12 kg Ca (OH) 2 per t coal material temperature 6000C throughput 0.6 t / h pressure 1.05 bar Composition of the mixed gas obtained H2 61% Co 2% Co2 28% higher KW 2% N2 2.6% CH4 4% H2S 0.4% calorific value 9050 kJ / Nm3 dry density 0.62 kg / Nm3 Amount 853 Nm3 / h dust content 827 mg / Nm³ moist discharge 31 kg with loss on ignition 41 E b) Carbonization and gasification without the addition of lime, product temperature 850 oC, throughput 0.45 t / h Pressure 1.05 bar Composition of the mixed gas obtained H2 59% Co 15.5% Co2 19.5 % CH4 2% higher KW 1 N2 1% H2S 2 calorific value 8850 kJ / Nm³ dry density 0.69 kg / Nm³ "Quantity 610 Nm³ / h" dust content 760 mg / Nm³ moist discharge 35 kg with loss on ignition 39 Example 2 (charring and gasification according to FIG. 2) Carbon-containing Solids: Rhenish lignite Composition: 21.5 go C 54 * H2O 5% ash 18.5% volatile components 1% sulfur Addition of 12 kg Ca (OH) 2 per t coal Product temperature during smoldering 500 ° C throughput 0.3 t / h pressure 1.03 bar composition of the sulfur gas (diluted by the flue gases from the direct heating): H2 25% Co 2% Co2 17% CH4 12% C2H4 1.5% higher KW 3% N2 39% H2S 0.5% calorific value 5200 kJ / Nm3 dry density 1.01 kg / Nm3 quantity 555 Nm³ / h "dust content 925 mg / Nm3 moist gasification of the smoldering residue in the gasification zone: product temperature 600 ° C throughput 0.12 t / h pressure 1.07 bar Composition of the water gas obtained H2 65 a Co 2% Co2 30 N2 2.5% KW 0.5 5 H2S calorific value 8500 kJ / Nm³ dry quantity 205 Nm³ / h density 0.70 kg / Nm³ dust content 890 mg / Nm³ moist discharge 25 kg with loss on ignition 37

Claims (15)

Claims: 1. Process for fluidized bed carbonization and gasification of carbonaceous solids, with water vapor for gasification of the solids is introduced into the fluidized bed, characterized by the following features: a) The carbon-containing solids are oxygenated compounds of the alkali and alkaline earth metals added; b) at least part of the gasification required Thermal energy is supplied to the gasification zone by indirect heating. 2. The method according to claim 1, characterized in that the charring and the gasification in two superimposed zones of a single, indirect heated fluidized bed reactor are carried out, which in the gasification zone resulting gasification product at the same time the fluidization medium for the above arranged smoldering zone and that consisting of carbonization gas and gasification product Mixed gas is withdrawn from the upper part of the reactor. 3. The method according to claim 2, characterized in that a part of the mixed gas withdrawn from the reactor as a fluidization medium into the gasification zone is introduced. 4. The method according to claim 1, characterized in that the charring in a fluidized bed reactor directly heated by substoichiometric combustion and the gasification is carried out in an indirectly heated fluidized bed reactor the carbonization gas withdrawn from the carbonization zone at least a part of the Forms fluidizing medium for the gasification zone. 5. The method according to claim 4, characterized in that the smoldering zone a combustion chamber is connected upstream, in which part of the generated in the smoldering zone Carbonization gas - preferably after dedusting - and air - preferably after preheating by means of the hot gases used for indirect heating of the gasification zone - introduced be, the flue gases generated in this combustion chamber at the same time the fluidization medium for the smoldering zone. 6. The method according to claim 1 for drying, charring and gasification of carbon-containing solids with high inherent moisture, characterized that the smoldering zone is preceded by a separate drying zone and that the steam-containing solids produced during the drying of the carbonaceous solids Vapors at least part of the fluidization medium supplied to the gasification zone form. 7. The method according to claim 1, characterized in that the feed is regulated by steam in such a way that there is an overpressure in the gasification zone up to 5 bar, preferably between 300 and 1000 mm WS, sets. 8. The method according to claim 1, characterized in that in the smoldering zone and in the gasification zone a temperature between 600 and 800 "C, preferably between 650 and 7503C. 9. The method according to claim 1, characterized in that the carbon-containing Solids 1 to 7.5% by weight, preferably 1.5 to 2.5% by weight, of oxygen-containing Compounds of alkali and alkaline earth metals are added. 10. The method according to claim 1, characterized in that the carbon-containing Solids calcium hydroxide, calcium carbonate and / or calcium oxide in fine grain Form to be added. 11. The method according to claim 1, characterized in that the carbon-containing Solids in addition to the oxygen-containing compounds of the alkali and alkaline earth metals Oxygen-containing iron compounds and / or iron scrap are added. 12. The method according to claim 1, characterized in that at least some of the oxygen-containing compounds of the alkali and alkaline earth metals carbonaceous solids before their Task in the Smoldering zone, preferably in an upstream drying zone, is added. 13. The method according to claim 12, characterized in that a part of the oxygen-containing compounds of the alkali and alkaline earth metals the carbon-containing ones Solids are only added in the gasification zone. 14. The method according to claim 1, characterized in that the from The gas withdrawn from the smoldering zone is dedusted and the separated dust into the gasification zone is introduced. 15. The method according to claim 1, characterized in that for the indirectly heated gasification zone a reactor is used, which has an inner Has steel jacket and an outer ceramic lining, with the space between Steel jacket and brick lining create a flow space for heating the gasification zone serving medium forms.