DE19652770A1 - Process for gasifying solid fuels in the circulating fluidized bed - Google Patents

Abstract

Combustible fuels, for example waste substances, biomass or coal, are gasified in a circulating fluidized bed with the addition of oxygenous gas at temperatures ranging from 700 to 1000 DEG C. A fuel gas is obtained which contains dust and hydrocarbons, including higher hydrocarbons (C6+ hydrocarbons), and has a calorific value of between 2000 and 8000 kJ/m<3>. The dust-laden gas is passed through a separation chamber in which the higher hydrocarbons present in the gas are largely separated by the addition of gaseous oxygen at temperatures ranging from 800 to 1200 DEG C and below the temperature of the ash melting point. The content of C6+ hydrocarbons present in the gas emerging from the separation chamber is at most 10 wt % of the initial content. The gas from the separation chamber is cooled and dedusted and passed through at least one bed or at least one reactor with granular solids which bind with pollutants. The gas-purification process is carried out without forming waste water.

Description

The invention relates to a process for gasifying solid fuels in the circulating fluidized bed, the fuels being gasified in a gasification reactor with the supply of oxygen-containing gas at temperatures in the range from 700 to 1000.degree. C., a gas-solid mixture from the upper area of the gasification reactor Separator supplies, from the separator dust and hydrocarbons including higher hydrocarbons with more than 6 C atoms in the molecule (C ₆₊ hydrocarbons) containing gas with a calorific value of 2000 to 8000 kJ / m ² and separately separated solids and the solids leads back at least partially into the lower region of the gasification reactor.

Methods of this type are described in DE-A-42 35 412 (see corresponds to US-A-5 425 317) and DE-A-44 12 004. At In the known processes, the Gas containing flammable constituents to form liquid Slag gasifies or burns, and the liquid slag is removed from the process. That with the combustion or Gasification generated gas is in contact with washing liquid cleaned. It becomes necessary to use the Process or dispose of washing liquid.

The invention has for its object to modify the known methods so that the dust is removed dry and wet washing with the formation of waste water in the gas cleaning is eliminated. According to the invention, this is achieved in the process mentioned at the outset by passing the dust-containing gas from the separator through a cracking chamber, with the gas contained in the cracking chamber with the addition of gaseous oxygen in the temperature range from 800 to 1200 ° C. and below the temperature of the ash melting point Hydrocarbons largely splits and the content of the higher hydrocarbons (C ₆₊ hydrocarbons) in the gas is reduced to a maximum of 10% by weight of the content of these higher hydrocarbons in the gas coming from the separator by cooling the gas coming from the cracking chamber , the cooled gas is passed through a dedusting device and fly dust is separated, that the cooled and dedusted gas is passed through at least one bed or a reactor with pollutant-binding granular solids and that the gas is then dedusted.

Due to the conditions in the cracking chamber and the conditions in the gas cleaning, the condensation and sublimation of the higher hydrocarbons (C ₆₊ ) does not take place in the downstream gas cleaning devices.

In the solid fuels to be gasified, it can e.g. B. um municipal or industrial waste, biomass or coal act in different ways. When municipal waste is gasified this is usually done before gasification pre-sorted, especially metal and glass parts be discarded. The remaining waste is then still crushed, e.g. B. to piece sizes of at most 70 mm before it is gassed. To increase the calorific value of the from the Gasification reactor coming gas can be the solid fuel dry before gasification.

In the method according to the invention, no liquid falls Residues. The one from the bottom of the gasification reactor drawn ash is usually so inert that it z. B. still is usable for road construction, but at least the ashes are easy to deposit. The one in the dust collector Air dust can be heavy metal and then disposed of in the usual way. Expediently burns or if you gasify at least a part of the accumulated dust in a combustion chamber at temperatures in the range of 1000 to 1500 ° C. It is recommended that in the combustion chamber formed gaseous products in the gasification reactor give.

Design options of the process are with the help of Drawing explained. It shows  

Fig. 1 shows the flow diagram of a first process variant and

Fig. 2 shows the flow diagram of a second process variant.

Referring to FIG. 1, the supplied solid fuels to be gasified in the line (1) a gasification reactor (2), where they come up with hot gases and particles in the state of the circulating fluidized bed in contact. Oxygen-containing fluidizing gas is introduced in line ( 3 ) and passed through a distribution chamber ( 4 ) with a grate ( 5 ) into the fluidized bed of the reactor ( 2 ). The oxygen-containing gas in line ( 3 ) can be, for example, air or air enriched with O ₂ . The gasification in the reactor ( 2 ) takes place at temperatures of 700 to 1000 ° C and mostly at temperatures of at least 800 ° C. Ash is drawn off through line ( 6 ) and is deposited, if necessary after removal of metal components, or for further use, e.g. B. in road construction.

At the upper end of the reactor ( 2 ), a gas-solid mixture leaves the reactor through the channel ( 8 ) and flows into a cyclone separator ( 9 ), from which fuel gas containing dust is drawn off through the line ( 10 ). Solids accumulating in the separator ( 9 ) are led back through line ( 11 ) into the lower region of the reactor ( 2 ).

The dust-containing gas of line ( 10 ) contains condensable hydrocarbons and mostly carbon-containing fly dusts. It is important to at least largely eliminate the higher hydrocarbons (C ₆₊ ) and convert them into substances that do not condense at the given temperatures and partial pressures. To this end, passing the gas through a gap chamber (12), the one -containing through the conduit (13) O ₂ gas, eg. B. air, oxygen-enriched air or technically pure oxygen. Temperatures in the range from 800 to 1200 ° C and mostly 900 to 1100 ° C are ensured in the gap chamber ( 12 ). It is important here that the temperature and the residence time in the cracking chamber ( 12 ) are chosen so that the formation of liquid slag is avoided and at the same time an adequate cracking of the C ₆₊ hydrocarbons is ensured.

The gas coming in the line ( 15 ) from the gap chamber ( 12 ) contains various types of solids and ash particles, which are referred to here as flying dust. In a waste heat boiler ( 16 ), the gas is cooled to temperatures of approximately 150 to 300 ° C. and then passed through the line ( 17 ) to a dedusting device ( 18 ). This can be, for. B. can be a fabric or electrostatic filter. The resulting dust, which usually contains heavy metals, is drawn off in line ( 19 ), a part of which can be led to a combustion chamber ( 21 ) on the transport route ( 20 ). The remaining airborne dust is removed from the process through line ( 22 ).

One leads the combustion chamber ( 21 ) through the line ( 24 ) oxygen-containing gas, for. B. air, enriched with O ₂ or technically pure oxygen and burns the supplied dust at temperatures in the range of 1000 to 1500 ° C. The resulting solid or liquid and gaseous combustion products are put together in the upper area of the reactor ( 2 ), where they are taken up by the fluidized bed. Notwithstanding Fig. 1 liquid slag from the combustion chamber (21) are also drawn off so that it does not enter the reactor (2), compare Fig. 2.

From the dedusting device ( 18 ), a gas is drawn off in the line ( 25 ) which still has a disruptive content of pollutants. These pollutants are e.g. B. mercury, chlorine and sulfur compounds. In order to remove these pollutants to a large extent, the gas is first passed through an indirect cooler ( 26 ) and the temperature which is favorable for the subsequent treatment is, for. B. in the range of 100 to 150 ° C. The cooled gas is passed through line ( 27 ) for cleaning, avoiding the formation of waste water. In one or more beds or reactors, the gas to be cleaned is brought into contact with granular adsorbents. These adsorbents can e.g. B. in a fixed bed, moving bed or fluidized bed or you can use an entrained flow reactor.

In the drawing, a schematic illustration of a moving bed reactor (30) is shown, which supplies the one-grained through the conduit (31) adsorbent material forming a bed (33) in the reactor (30), which moves slowly downwards. The bed to be cleaned flows through the bed approximately in a horizontal direction. The gas leaves the reactor ( 30 ) through line ( 35 ) and is led to dust removal through the filter ( 36 ), which is z. B. can be a fabric or electrostatic filter. Cleaned gas leaves the filter ( 36 ) in line ( 37 ). The loaded adsorbent coming from the reactor ( 30 ) is discharged in line ( 38 ), mixed with the solids separated in the filter ( 36 ) in line ( 39 ) and drawn off.

When selecting and using suitable, more well-known Adsorption materials are particularly the following Options: hydrated lime, activated carbon, stove coke or Zeolites. The mercury removal using a Low-aluminum zeolites are described in EP patent 638 351.

In the flow diagram of FIG. 2, the reference numbers already mentioned together with FIG. 1 have the meaning explained there. According to FIG. 2, the pollutant-containing gas is fed to line ( 27 ) to a spray absorber ( 40 ), to which lime milk and possibly other adsorbents are fed through line ( 41 ). Gas and solids flow through line ( 42 ) to a filter ( 43 ), which is e.g. B. can be a fabric or electrostatic filter. Purified gas passes in line ( 44 ) to an adsorber ( 46 ) for the separation of mercury, e.g. B. in a zeolite fixed bed, as described in EP patent 638 351. Chloride-containing solids are drawn off in line ( 45 ). In the combustion chamber ( 21 ), liquid slag is drawn off through line ( 23 ) and the combustion gas is passed through line ( 32 ) into the reactor ( 2 ).

example

Residual municipal waste is fed to a process according to FIG. 2. The following data are partially calculated. The residual waste, which is delivered in an amount of 7500 kg / h, contains 24.5% by weight of moisture and 30% by weight of ash. This waste is first dried to 5% by weight of residual moisture and then gasified in the reactor ( 2 ) at 900 ° C. and with the supply of 6230 Nm ² / h of air. 13,000 Nm ^{2 of} gas flow through line ( 10 ) per hour, the gas contains 48 g / Nm ^{2 of} dust and 1% by volume of C ₆₊ hydrocarbons. The residence time of the gas in the gap chamber ( 12 ) is 1.5 seconds, air is supplied through line ( 13 ) and an outlet temperature of 1000 ° C. is reached. The content of C ₆₊ hydrocarbons in line ( 15 ) is only 0.1% by volume. 400 kg / h of dust are fed through the line ( 20 ) into the combustion chamber ( 21 ), which is fed with 1860 Nm ³ / h of air and in which 1300 ° C. can be reached. Lime milk is added to the spray absorber ( 40 ) and the outlet temperature is kept at 160 ° C. The adsorber ( 46 ) contains a fixed zeolite bed for mercury removal.

Claims (3)

1. A process for the gasification of solid fuels in the circulating fluidized bed, the fuels being gasified in a gasification reactor with the supply of oxygen-containing gas at temperatures in the range from 700 to 1000 ° C., a gas-solid mixture being fed to a separator from the upper area of the gasification reactor , from which the separator derives dust and hydrocarbons including higher hydrocarbons with more than 6 carbon atoms in the molecule with a calorific value of 2000 to 8000 kJ / m ³ and separated solids and at least partially returns the solids to the lower area of the gasification reactor , characterized in that the dust-containing gas is passed from the separator through a cracking chamber, the hydrocarbons contained in the gas being largely split in the cracking chamber with the addition of gaseous oxygen in the temperature range from 800 to 1200 ° C and below the temperature of the ash melting point d the content of the higher hydrocarbons (C ₆₊ hydrocarbons) in the gas is reduced to a maximum of 10% by weight of the content of these higher hydrocarbons in the gas coming from the separator, that the gas coming from the cracking chamber is cooled, the cooled Passing gas through a dedusting device and separating flying dust, passing the cooled and dedusted gas through at least one bed or a reactor with granular solids binding pollutants, and then dedusting the gas. 2. The method according to claim 1, characterized in that at least part of the deducted from the dedusting fly dust in a combustion chamber at temperatures in the range of 1000 to 1500 ° C with the addition of O ₂ -containing gas. 3. The method according to claim 2, characterized in that one the gaseous products formed in the combustion chamber Gasification reactor formed, solids-containing gas admixed.