DE3415489C1 - Plant for the desulphurisation of flue gas downstream of a boiler furnace - Google Patents

Abstract

A plant for the desulphurisation of flue gas downstream of a boiler furnace, having a scrubbing tower having a bottom flue gas entry and top flue gas outlet, a device for the introduction of a scrubbing tower liquid having a multiplicity of atomising jets distributed over the height of the scrubbing tower and a scrubbing liquid sump, an electrostatic precipitator being connected upstream of the flue gas entry and a mixture of predominantly calcium sulphate and calcium sulphite being precipitable from the scrubbing liquid sump, in which mixture the fly ash which has passed the electrostatic precipitator is contained. Between the electrostatic precipitator and the scrubbing tower, in the region of the flue gas entry, there is arranged an ionisation unit, which is provided with a plurality of spray electrodes and surrounding polarisation electrodes which are formed into a channel shape, through which electrodes flows the flue gas. The spray electrodes and the polarisation electrodes have a length of 10 to 40 cm in the direction of flow at a flow velocity of the flue gas of above 10 m/second. <IMAGE>

Description

The invention is based on the object of providing a generic system, in which the washing tower is designed in the manner described, so continue to train, that even with relatively high levels of SO2 and SO3, desulphurisation also occurs very good desulfurization efficiency takes place and aerosols are no longer discharged To solve this problem, the invention teaches that between the electrostatic precipitator and the scrubbing tower in the area of the flue gas inlet, an ionization unit is arranged is, -which a plurality of spray electrodes and surrounding, channel-shaped Has polarization electrodes that operate at a flow rate of the flue gas of over 10 m / sec. have a length of 10 to 40 cm in the direction of flow. It it goes without saying that in general all spray electrodes and all polarization electrodes have the same length. In the statement that the flow velocity of the Smoke gases over 10 m / sec. is, there is an indication of the dimensioning of the corresponding Flow channel and the ionization unit as a whole, ionization units are similar Construction are in devices for the dedusting of industrial gases per se known (DE-OS 33 29 638, PatG § 3 (2) 1.).

A preferred embodiment of the invention is in this context characterized in that the flow rate of the flue gas between 15 and 20 m / sec. and that the spray electrodes and the polarization electrodes have a length between 20 and 30 cm. The flue gas inlet expediently has a flue gas inlet nozzle, which is inclined on the surface of the oxidation zone of the washing liquid sump is directed.

The invention is based on the surprising fact that in a generic plant, the desulfurization is improved when the flue gas in ionized state enters the washing tower. The ionization unit is accordingly arranged sufficiently close to the flue gas inlet. It goes without saying that that Ionization unit on the ionizable components carried along in the flue gas acts, which are ionized in this way. The ionization unit works insofar not as an electrostatic precipitator. The length of the spray electrodes is corresponding and polarization electrodes taking into account the flow velocity the flue gas set up.

Apparently the ionization changes the reaction kinetics of the desulfurization reactions. The desulphurisation efficiency is also increased by the high contents of SO2 and SO3 in the flue gas no longer disruptive. Aerosols, consisting mainly of sulphurous acid or sulfuric acid are no longer discharged. Particularly pronounced The effects when the flue gas has not too low a content of dust, mainly Carries fly ash. Therefore, the invention teaches that the electrostatic precipitator for a flue gas dedusting is designed for over 50 mg / Nm3. It goes without saying that in the washing tower in this If, in addition to the desulphurisation, there is also a further dedusting by washing out, so that the clean gas that passes through the washing tower is much less than 50 mg / Nm3 with residual dust. In order to condition the ionization it is advisable to pre the ionization unit a device for a water supply or water vapor supply to arrange.

In the following the invention is based on only one embodiment Illustrative drawing explained in more detail. It shows in a schematic representation 1 shows a vertical section through a system according to the invention, FIG. 2 the enlarged Section A from the object according to FIG. 1 and FIG. 3 shows a section in the direction B-B by the item of Fig. 2.

The system shown in the figures is for desulfurization determined by flue gas behind a boiler. Part of the basic structure a washing tower 1 with lower flue gas inlet 2 and upper flue gas outlet 3, one Device 4 for the introduction of a washing liquid with a plurality of over atomizing nozzles 5 and a washing liquid sump distributed over the height of the washing tower 6 in the washing tower 1.

An electrostatic precipitator 7 is connected upstream of the flue gas inlet 2. the end the washing liquid sump 6 is a mixture of mainly calcium sulfate at 8 and calcium sulfite separable, in the fly ash is contained, which the electrostatic precipitator 7 happened.

Between the electrostatic precipitator 7 and the washing tower 1 is located at In the area of the flue gas inlet 2, an ionization unit 9. This has a plurality of spray electrodes 10 and surrounding, channel-shaped polarization electrodes 11, through which the flue gas flows. The spray electrodes 10 and the Polarization electrodes 11 have a flow velocity of the flue gas of over 10 m / sec. in the direction of flow a length of 10 to 40 cm. Preferably the flue gas has a flow rate of 15 to 20 m / sec., while the length of the spray electrode or the polarization electrodes 11 between 20 and 30 cm.

The washing liquid sump 6 is provided with horizontal oxygen supply lines 12 equipped and has devices 13 for the supply of additives.

The washing tower area above the washing liquid sump works as the absorption range. The oxygen supply lines 12 form a grate, one oxidation zone 0 above the grate and one reaction zone R below the grate separates. Below the grate are the devices 13 for the addition the additives arranged. Furthermore, the arrangement is made so that the flue gas inlet 2 has a flue gas inlet nozzle 14 which is inclined on the surface of the Oxidation zone 0 of the washing liquid sump 6 is directed. This has the consequence that the ionized components of the flue gas stream entering the scrubbing tower 1 act on the surface of the washing liquid sump 6, namely at the oxygen content and pH values essential to the O oxidation zone. That leads to very complete Reactions, especially when the residual dust in the washing tower 1 entering flue gas, which has passed the electrostatic precipitator 7, is not too low is e.g. B. is over 50 mg / Nm3. Aerosols, consisting mainly of sulphurous Acid or sulfuric acid exist, are no longer discharged and consequently get there not even in the droplet separator 15, which such a washing tower 1 regularly is downstream. In the embodiment shown, it is in front of the ionization unit 9 a device 16 for supplying water and / or water vapor is arranged.

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Claims (5)

Claims: 1. Plant for the desulphurization of flue gas behind a boiler furnace, - with washing tower with lower flue gas inlet and upper flue gas outlet, Means for introducing a washing liquid with a plurality of over the washing tower height distributed atomizing nozzles and washing liquid sump with horizontal Oxygen supply lines and devices for the supply of additives into the washing liquid sump, the washing tower area above the washing liquid sump works as an adsorption area and the oxygen supply lines create a grate form, an oxidation zone above the grate and a reaction zone below the grate separates, with the facilities for the addition of underneath the grate Additives are arranged and an electrostatic precipitator is connected upstream of the flue gas inlet is, characterized in that between the electrostatic precipitator (7) and the washing tower (1) an ionization unit (9) is arranged in the area of the flue gas inlet (2) is, which is a plurality of spray electrodes (10) and surrounding, channel-shaped designed polarization electrodes (11), which at a flow rate of the flue gas of over 10 m / sec. in the direction of flow a length (L) of 10 to 40 cm. 2. Plant according to claim 1, characterized in that the spray electrodes (10) and the polarization electrodes (11) at a flow rate of the Flue gas between 15 and 20 m / sec. in the direction of flow a length (L) between 20 and 30 cm. 3. Plant according to one of claims 1 or 2, characterized in that that the flue gas inlet (2) has a flue gas inlet nozzle (14) which is inclined directed at the surface of the oxidation zone (O) of the washing liquid sump (6) is. 4. Plant according to one of claims 1 to 3, characterized in that that the electrostatic precipitator (7) is designed for flue gas dedusting to over 50 mg / Nm3 is. 5. Plant according to one of claims 1 to 4, characterized in that that in front of the ionization unit (9) a device (16) for supplying water or is arranged by water vapor. The invention relates generically to a system for desulfurization of flue gas behind a boiler, - with washing tower with lower flue gas inlet and upper flue gas outlet, device for the introduction of a washing liquid with a plurality of atomizing nozzles and washing liquid sump distributed over the height of the washing tower with horizontal oxygen supply lines and devices for the supply of additives in the washing liquid sump, with the washing tower area above the washing liquid sump works as an adsorption area and the oxygen supply lines form a grate that has an oxidation zone above the grate and a reaction zone below the grate separates, with the facilities for the below the grate Addition of additives are arranged and the flue gas inlet is an electrostatic precipitator is upstream. Such a flue gas flow regularly carries with it fly ash also gets into the washing liquid sump. The fly ash in the washing liquid sump is accepted as a necessary evil because in an electrostatic precipitator a complete Separation of fly ash is not possible and especially fine-grained fly ash happened. In known generic systems, the flue gas occurs via a a more or less long transfer line into the washing tower, although it takes place in The electrostatic precipitator is also ionized, but this ionization works lost in the electrostatic precipitator during its separation work and is in any case due to the more or less long transfer line in the washing tower is no longer effective. The electrostatic precipitators can be constructed in different ways (Chemiker-Zeitung, 95, 1971, No. 10, p. 444). The known measures have proven themselves. This is particularly true for a generic system in which the washing tower, as described, in particular Way is designed (DE-OS 32 18 470). The oxygen supply lines exist here generally from a plurality of parallel, downwardly open hoods, which have upwardly open oxygen outlet bores, the distance between the hoods is chosen so that a backflow does not take place and consequently the zone separation described is very pronounced. In the context of the known measures, one problem remains, in particular with high SO2 and high SO3 contents in the flue gas. with increasing content of these Ingredients decreases the desulfurization efficiency, it is observed that from the washing tower aerosols, which mainly consist of sulphurous acid or sulfuric acid exist, be broadcast. These are indeed in downstream droplet separators deposited, but affect overall the function of the system.