DE3919124A1 - METHOD FOR SEPARATING POLYCYLCIC HYDROCARBONS AND HEAVY METALS FROM EXHAUST GASES - Google Patents

Abstract

The invention concerns a process for the removal of traces of pollutants from the exhaust gases from waste incineration plants. The invention calls for the gases, pre-cleaned in a gas purification plant to remove dust, acid gases (HCl, HF, SOx), heavy metals and NOx, to be freed of the remaining polycyclic hydrocarbons (e.g. dioxins and furanes) and heavy metals (e.g. Hg, Cd) by means of a combined adsorption/filtration process. To this end, the gases, at a temperature of about 70 to 160 DEG C, are mixed in a reactor (C4) with suitable adsorption agents (e.g. activated charcoal, molecular sieves or slaked lime) and subsequently passed through a fibrous filter (F2). The pollutants are bound to the adsorption agent in the reactor and subsequently in the filter cake on the fibrous filter.

Description

The polycyclic hydrocarbons, e.g. B. halogenated Dibenzodioxins and dibenzofurans (PCDD and PCDF) or polychlorinated benzenes and phenols, as well as heavy metals (e.g. Hg, Cd) can be used with the exhaust gases from the combustion plants, especially of waste and special waste incineration plants, emit.

The polycyclic hydrocarbons that are extremely harmful to health can have a carcinogenic effect when burned through complex recombination reactions from organic and inorganic compounds arise. These connections can only be used to a limited extent in downstream cleaning systems (with the dust in the electrostatic precipitator or in the exhaust gas washing system) be deposited. Also some heavy metals (Hg, Cd), which are also harmful to health can be found in the existing exhaust gas temperatures in part in the gaseous state or as fine dust and aerosols from the exhaust gas cleaning system emit.

This invention allows all of them to be used conventionally Exhaust gas purification process with regard to the separation of harmful organic compounds and Heavy metals can be optimized.

Figures 1 and 2 are examples of the invented process in connection with a conventional exhaust gas cleaning system behind a waste incineration system, consisting of an electrostatic filter for dust separation, a two-stage scrubber for the separation of acidic gases (HCl, HF, SOx) and an SCR system for NOx Reduction shown. The exhaust gases coming from the incinerator are first led to an electrostatic precipitator at approx. 200-350 ° C for the purpose of dust separation. Depending on the design of the e-filter and the properties of the exhaust gas and dust, high degrees of dust separation or very low dust concentrations (approx. 50-30 mg / m³, in general) can be achieved. At the same time, a high proportion of the polycyclic hydrocarbons and heavy metals can be separated with the fly ash. However, since some of these substances accumulate on fine dust and aerosols that leave the E-filter or are partly in a gaseous state, their extensive removal in the E-filter is not possible.

After dedusting, the exhaust gases are passed through a heat exchanger led to a two stage scrubber where by cooling to about 60-70 ° C and the use of absorbents  (NaOH, Ca (OH) 2) the acidic exhaust gas components (HCl, HF, SOx) and further heavy metal fractions are deposited. The remaining hydrocarbons and heavy metals the washing system as fine rods, aerosols or gases and if no additional measures are provided, with the exhaust gases emit from the chimney.

According to the emissions of these pollutants through a combined adsorption-filtration process be prevented. For this purpose, the exhaust gas is after the laundry is heated to approx. 70 to 150 ° C in a heat exchanger and in a reactor with finely divided powder Adsorbent mixed intensively. The reactor can e.g. B. consist of a circulating fluidized bed through which a large contact area between exhaust gas and adsorbent can be realized. A partial addition is already taking place here polycyclic hydrocarbons and heavy metals to the adsorbent. The exhaust gas from the reactor is led to a downstream fabric filter, where the adsorbent to form a filter cake separates the filter bags. Because the exhaust gas is forced must flow through the filter cake here a largely adsorptive at the same time as the dedusting Separation of the remaining polycyclic hydrocarbons and the heavy metals instead.

All selectively acting substances, e.g. B. activated carbon, hydrated lime, molecular sieves and sodium sulfite, with a high specific surface.

By returning the one separated in the fabric filter Adsorbent to the reactor becomes a high dust concentration (approx. 5000 to 50 000 mg / m³, i.N.) and consequently a high contact between adsorbent and exhaust gas produced. Depending on the operational requirements Removal of adsorbed pollutants a little Proportion of the returned quantity due to fresh additive replaced. The branched portion can be used for disposal be led to the incinerator where the bound organic compounds thermally decomposed and the heavy metals released again and ultimately in the downstream Systems (e-filter and exhaust gas scrubbing) separated will.

As is apparent from Figures 1 and 2, the method may be in front of the chimney for use either according to the exhaust gas scrubbing or after the SCR system (catalytic NOx reduction using ammonia). In the latter case, ammonia residues and possible ammonium salts (NH4HSO4, (NH4) 2SO4) from the SCR system can also be separated.

The invented process is characterized by a high degree of flexibility and adaptability to the respective operating conditions out. Depending on the application and the present Boundary conditions can include the adsorption process and plant operation can be optimized by the following measures:

• - Optimization through the use of different selective acting adsorbents in any proportions (e.g. 20% activated carbon and 80% hydrated lime),
• - Optimization by adapting the exhaust gas / adsorbent Contact by regulating the return of the fabric filter Amounts of solids,
• - Optimization by adjusting the ratio of fresh recycled adsorbent,
• - Optimization by adjusting the thickness of the filter cake through appropriate regulation of cleaning times the fabric filter,
• - Optimization by setting the operating temperature in a relatively wide range from approx. 70 to 160 ° C.

Claims (4)

1. Process for the separation of health-damaging polycyclic hydrocarbons (e.g. dioxins and furans) and heavy metals from the waste gases from waste incineration plants (e.g. waste and hazardous waste incineration), characterized in that the dust, HCl, HF, SOx, NOx and heavy metals pre-cleaned exhaust gases are freed from the remaining polycyclic hydrocarbons and heavy metals by adsorption / filtration in the temperature range of 70-160 ° C. 2. The method according to claim 1, characterized in that
that the pre-cleaned exhaust gases are first mixed in a reactor (C 4 ) with finely divided adsorbents and then passed to a filtering separator (F 2 ), where an adsorbent cake is generated on the filter fabric, which the exhaust gases have to flow through,
that a large adsorptive separation of polycyclic hydrocarbons and heavy metals takes place when flowing through the filter cake. 3. The method according to claim 2, characterized, that depending on the local boundary conditions the separation performance of the process by type, quantity and composition of the adsorbent, exhaust gas / additive Quantity ratio, thickness of the filter cake and Reaction temperature is optimized.   4. The method according to claim 1, 2 and 3, characterized in
that substances with a high selectivity (e.g. activated carbon, molecular sieves, sodium sulfide, hydrated lime) can be used as adsorbents in different proportions,
that in order to minimize the adsorbent consumption and the accumulated residues, the adsorbent mixture separated in the filter is circulated and only slightly replaced by fresh additive only because of the removal of the adsorbed pollutants,
that the portion discharged from the recirculation circuit is led to the thermal decomposition of polycyclic hydrocarbons to the incinerator.