DD200642A1 - METHOD FOR REDUCING THE IMMISSION OF HALOGEN COMPOUNDS FROM HEATING AND HEATING POWER STATIONS - Google Patents

Abstract

The invention relates to heated with lignite dust heating and heat engines, where mainly Flor compounds are released with the combustion and can get into the atmosphere with the flue gas. The aim and the task are to make possible their adsorptive formation from an economic point of view in economic terms or with certain secondary raw materials from the emergence of species-specific works. The essential feature of the invention is that fly ash of lignite dust combustion with a sufficiently high Al & ind2! O & ind3! Content, which is obtained in the last stages or as a fine-grained fraction existing electrostatic precipitator, is brought to the flue gas to the reaction.

Description

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Title of the invention

Method for reducing the emission of halogen compounds from heating and thermal power plants

Field of application of the invention

The invention relates in particular to lignite-fired heating and thermal power plants in which in the course of combustion halogen compounds, mainly fluorine compounds are released from the fuel and reach the flue gas into the atmosphere.

Characteristic of the known technical solutions

It is known that brown coal in addition to other halogens contains relatively large amounts of fluorine compounds. With the combustion of coal, these compounds are released mainly as hydrogen fluoride and scattered into the environment of heating and thermal power plants, which can lead to serious pollution damage. Thus, the phytotoxicity of hydrogen fluoride (HF) is 4-fold times that of sulfur diox- ide (SO2), which makes even low ambient concentrations harmful to the environment. Gaseous fluorine compounds are known to cause acute and chronic vegetation damage to deciduous and coniferous trees, as well as to agricultural and horticultural crops. "In addition, there is a risk of fluorine accumulation via the plant-animal food chain and, subsequently, the occurrence of fatal diseases in the animals concerned.

The journal "Chemie-Technik" 5 (1976), No. 5, pages 183 to 187, refers to possible fluorine adsorption due to dry hot cleaning of the flue gases. "According to this, environmental damage caused by fluorine immission must be avoided if the toxic emissions released by burning fossil fuels Fluorine compounds, such as HF or SiF 2, are still adsorptively converted to CaO 2 in the firing systems on GaO 2, and the resulting calcium fluoride-containing fine dusts are held out of the flue gas as a non-toxic compound.

It is also known, in lignite-fired power plants to make an adsorptive binding of fluorine-containing pollutants in the flue gas of the fly ash itself, provided that the fluoride-containing lignite contains so much lime that the resulting fly ash due to free lime can adsorb the previously released fluorine compounds again. In this case, care must be taken only for adequate flue gas cleaning (VGB magazine - Kraftwerkstechnik 54 (1974), pages 268 to 286.

The former literature also shows a fluorine adsorption. in the fluorine processing industry, by liberated hydrogen fluoride from alumina (Al ₂ Oo) to AlF ^ bound and the reaction product can be recycled to the process. "According to the Federal Republic of Germany OS 21 09 324 (F 23 J, 15/00) was an exhaust gas purification plant is known, the toxic or harmful by sodium compounds flue gas constituents, such as sulfur dioxide (SO2), cadmium, fluorine, etc., Finally, with the DDR-PS 123 119 (F 23 J, 5/10) is known a method for removing sulfur dioxide and other pollutants from flue gases, according to which a carbonaceous adsorbent is blown as Flugstaubwolke in the dedusted flue gas, separated after a sufficiently long residence time in an electrostatic precipitator and desorbed in a fluidized bed.The release of HF is based on the chemical reactions

CaF ₂ + HgO> CaO + 2HF

SiF ^ + 2H 2 O - ^ SiO ₂ + 4 HF, where it is sufficient for sufficient adsorption, for example by CaO,

which then runs contrary to the first reaction, a high CaO concentration (dust density), large reaction surface (fine grainy), long reaction time and low reaction temperature arrives ο

All the hler known ways of adsorptive binding of gaseous fluorine compounds can not practically realize in a large-scale combustion of fluorine-containing lignite in large Heiz ™ and thermal power plants, because it usually has neither the lignite reaching for combustion at the same time liberated for full setting fluorine compounds required for lime content nor would it be economically justifiable to use costly adsorbents in the required quantities sometimes over long transport distances.

Object of the invention

The aim is to solve the problem of adsorptive binding and retention of gaseous fluorine compounds from the flue gas of lignite-fired heating and thermal power plants on an industrial scale in an economically justifiable manner.

Explanation of the essence of the invention

The objective is to be achieved with the task of integrating the liberated with the combustion of lignite gaseous fluorine compounds exclusively with certain secondary materials of the heating and thermal power plants. It was found that for this fly ash lignite dust combustion with a sufficiently high A ^ C ^ content, which is obtained from the last or from the last two purification stages existing electrostatic precipitator or a fine fraction of recycled fly ash, added to the incinerating brown coal and / or is reacted with the flue gas by means of fluidized bed reactors and / or that fine fly ash is accumulated in a fabric filter arranged downstream of the electrostatic filter or the fly ash is collected exclusively in a fabric separator and exposed to the flue gas for a longer time.

embodiments

The erfindungsgeinäße solution is explained below with reference to several embodiments and associated drawings. The figures of the drawings show in detail:

1 is a flow chart of a first embodiment, FIG. 2 is a somewhat modified flow chart of the same embodiment,

3: a flow chart of a second embodiment, FIG. 4: a flow chart of the second modified according to FIG.

Embodiment,

5 is a flowchart of a third embodiment, FIG. 6i is a flowchart of the third modified according to FIG

Embodiment, Fig.: A flowchart of a fourth embodiment.

In all embodiments, it was assumed that the fly ash used with the sufficiently high A ^ O, - content in the fine grain fractions in their own heating or thermal power plant, resulting in the majority of existing works due to the geographical location of the Lignite (East Elbe area) applies. In exceptional cases, fly ash with the sufficiently high A ^ CU content from other heating or thermal power plants should be used, provided that the own fly ash in the fine grain fractions does not have the sufficient A ^ O, - content,

Embodiment 1

1 and 2 is based on a heating or thermal power plant, in which the reaching to burn raw lignite coal as a 9.1 via a conveyor 7 first branched off from the firebox 10 fire gases and then into a fan mill 8, then as suspended charcoal. 9 · 2 sent by burners, not shown, and burned in the presence of preheated air in the furnace 10. The dust-laden flue gas 1 emerging from the combustion chamber 10 after passing through heat exchange surfaces passes into an electrostatic precipitator 2 and from there into the chimney 17 as an approximately dust-free flue gas 3 for the purpose of dispersing it as flue gas swath 18.

-5- 23 3 55 2 8

The plug-in pocket deposited in the three-stage electrostatic precipitator 2 collects in collecting funnels 21, the granularity decreasing from one stage to the next, and the A 2 O 3 content increasing. Referring to FIG. 1 fine fly ash 5 x * is determined from the third stage, and optionally also from the second stage, ^ra it 4-geleltet the sufficiently high A ^ CU-content to a mass flow divider, the one partial flow 5 «2 a defined amount to the conveyor 7 for the indirect return to the firebox branches off. The remaining amount 12.1 of the fine fly ash 5 * 1 can then be a separate use, for. B. for the Al extraction or together with the fly ash of the first and optionally second stage of the electrostatic precipitator 2 as mixing component 6 of the landfill or for other purposes.

According to FIG. 2, as an alternative to the first exemplary embodiment, the fly ash precipitated in all three stages of the electroflider 2 is conducted from its collecting funnels 21 to an enrichment device 11 in which a fraction analogous to the fine fly ash 5 · 1 is held with a sufficiently high AlgO.sub.2 content then passes to the mass flow divider 4, which divides the indirectly attributable to the combustion chamber 10 partial flow 5.1 in a defined amount, while the remaining amount 12.1 z. B. can be used for Al extraction.

In this case, the partial coal 9 · 1 supplied partial flow 5 »2 of the fine fly ash 5-1 acts on the way from the combustion chamber 10 to and within the electrostatic precipitator 2 as an adsorbent for the liberated in the combustion chamber 10 fluorine compounds. The dusts enriched with fluorine interfere with the fly ash originating from the brown coal, so that the adaorption capacity of the partial stream 5.2 of the fine fly ash 5 * 1 sent into circulation can not be exhausted »

Embodiment 2

According to FIGS. 3 and 4, in addition to the procedure illustrated in exemplary embodiment 1, the approximately dust-free exhaust gas 3 is detected with the aid of an electrostatic precipitator 2.

23365 9

Filtered fine tissue filter 13 filtered, whereby the dari: detained Feinstflugasche 12.2 with a relatively high AlpOn content is also correspondingly higher adsorption effect The adsorption of Feinstflugasche 12.2 is particularly increased by the fact that their surface relative to other fly ash relatively largest, their temperature relatively lowest and whose residence time in the exhaust gas is long. The fine tissue filter 13 is only as far freed from the detained Feinstflug ash 12.2, as it is necessary on the one hand for a complete adsorption of gaseous fluorine compounds and how the other hand, each allow the prevailing tensile conditions. The addition of the second embodiment downstream adsorbent surfaces in the form of Feinstgewebefilters 13 improve to a corresponding extent the reaction yield for gaseous fluorine compounds over the embodiment 1 and there is also a secondary raw material, in this case a Feinstflugasche with increased utilization due to the increased Al ₂ CU content ,

Embodiment 3

Fig. 5 and 6 illustrate the procedure shown in Example 1 with additional connection of a fluidized bed reactor 14 between the furnace 10 and electrostatic filter 2. This fluidized bed reactor 14 is charged with the partial flow 5 · 2 of the fine fly ash 5 · 1 with sufficiently high AlgOn content 1 and 2 in the last and optionally penultimate stage or in the enrichment device 11 is obtained. In this case, the dust-laden flue gas 1 emerging from the combustion chamber 10 undergoes admixture with the substream 5.2 during its passage through the fluidized-bed reactor 14, and an intensive adsorption of the gaseous fluorine compounds on the fluidized bed adjusted to a predetermined degree of filling all ash constituents, especially those with a sufficiently high AlgO 2 content, take place due to high dust concentrations and longer reaction times.

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The flue gas 16 emerging from the fluidized bed reactor 14 and heavily laden with fly ash undergoes its purification in the electrostatic precipitator 2, wherein the removal of a residual amount 12.1 from the fine fly ash $ "1 precludes exhaustion of the adsorptive capacity of the recirculated substream 5.2 from the uses already mentioned in Example 1.

Embodiment 4

According to Fig. 7, a further embodiment of the inventive solution for reducing the immission of fluorine compounds in heating and thermal power plants is made possible by the exclusive involvement of a fabric separator 19 for the separation of the dust-laden exhaust gas 1 fly ash »Due to the naturally relatively long residence times and large concentrations of Fly ash over the dust-laden exhaust gas 1 is carried out according to this embodiment, a more intense reaction than in the first embodiment, whereby a return of a fine fly ash with sufficiently high A ^ O, - content in the sense of the first embodiment is unnecessary. However, it proves to be advantageous to pass the separated fly ash into an enrichment device 11 in order to be able to withstand a fraction of fine fly ash 5 * 1 which is suitable for aluminum smelting or otherwise of the remaining mixing component 6.

In this embodiment, the fabric separator 19 leaving dust-free flue gas 15 passes through the chimney 17 as a flue gas swath into the atmosphere.

Claims (7)

invention claim 1. A method for reducing the emission of halogen compounds from heating and thermal power plants by chemical integration, characterized in that fly ash with sufficient] high AlgCU content from the lignite dust combustion midem flue gas contained in the fluorine compounds to Reacti »brought and the reaction products in a known manner from the Flue gas can be sustained. 2. The method according to item 1, characterized in that fly ash of the last or the last two purification stage] an electrostatic precipitator is reacted. 3 * Method according to item 1, characterized in that a fine-grained fraction of the fluid obtained by treatment is reacted. 4. The method according to item 1, characterized in that the fly ash with the sufficiently high ALpCL content of Braui coal is added before their grinding. 5. The method according to item 1, gkennzeichnet characterized in that the fly ash with the sufficiently high A ^ O ^ content in a the electrostatic filter upstream fluidized bed for reaction g is introduced. 6. The method according to item 1, characterized in that in addition fine fly ash with the help of a downstream of the electrostatic filter fabric filter accumulated and is exposed to the flue gas for a long time. 7. The method according to item 1, characterized in that only fly ash of a tissue separator is accumulated and exposed to the flue gas for a long time. 4 sheets of drawings