EP0092854A1 - Wet electrofilter for a converter exhaust - Google Patents

Abstract

For a dedusting system for cleaning converter exhaust gases, a wet electrostatic precipitator is proposed, with a circular cylindrical housing, one or more separating fields arranged one behind the other, the height of which is divided at least once and the lower and upper parts of which are offset from one another by half the width of the aisle, with removal devices for the Spray electrodes and the precipitation electrodes as well as with a flushing device, all components being arranged in the housing in such a way that the flow cross section is optimally used. FIG. 5 shows the arrangement of the precipitation electrodes 9 with removal devices 13, the spray electrodes 11 and the rinsing device 10, 12 in the region of the parting plane between the lower part and the upper part of the separating field, which are arranged offset by half a gas aisle width B.

Description

The invention relates to a wet electrostatic precipitator for horizontal gas passage for dedusting converter exhaust gases.

In recent years, scrubbers have often been used to dedust converter exhaust gases. They usually consist of a cooling and saturation stage and the actual washing stage. In the first stage, the exhaust gases are cooled to 60 to 80 ° C. It has a pressure drop of 200 to 400 mm WS, while a pressure drop of 1200 to 1400 mm WS is required for the second stage. The dedusting effect of such washers is limited to about 100 mg / Nm ³ because of the fineness of the dust.

In the course of efforts to save energy and to recycle the flammable exhaust gases, scrubbers are increasingly regarded as unsatisfactory. The relatively high pressure loss requires a considerable expenditure of blower power and the degree of purity achieved is not sufficient for gases which are to be used further.

In the meantime, the energy-saving and efficient circular dry-type dry electrostatic precipitator has practically replaced the washer for new systems, but for existing systems with washers, it is usually not possible to convert to the dry electrostatic precipitator due to space constraints and the necessary downtime.

In this sense, the replacement of the energy-consuming second washing stage by a wet electrostatic precipitator would be a desirable compromise, in which longer downtimes are avoided than the new fine cleaning during the existing production operation outside the steelworks and only then is the new gas paths converted.

There have therefore been made already considerations converter exhaust gases by means naßarbeitender electrostatic precipitator to ^- clean, without previously viable proposals have become known. Due to the risk of deflagration in the overall system, the electrostatic filter housing is designed to be pressure shock resistant. In addition, one wants to avoid connecting several units in parallel because this would unnecessarily increase the system costs. From this it follows, however, that very large gas flow cross sections must be provided in order to be able to clean the large, intermittently occurring gas quantities effectively, ie at flow speeds between 1 and 1.8 m / s. This in turn requires large-area precipitation electrodes with a height of up to 10 m or more, in which additional structural measures must be taken to achieve sufficient rigidity or to ensure the mutual distance under operating conditions.

Precipitation electrode plates, the height of which - depending on the type of dust and the other conditions - exceed 3 to 5 m, are therefore ruled out because they can no longer be effectively rinsed. The converter exhaust gases are usually saturated before entering the separation fields, so that condensate is also deposited on the precipitation electrodes together with the moist dust. Since the converter exhaust gases occur intermittently, there is enough time in the blow breaks of the converter to clean the precipitation electrodes by spraying flushing liquid. A continuous rinse is therefore not necessary. During the blowing phases, i.e. if the electrostatic precipitator has to work with maximum separation capacity, the flushing is switched off in order to be able to operate the electrostatic precipitator with the highest possible voltage and to avoid impairment of the voltage regulation by sprayed-in liquid droplets.

Depending on the type and consistency of the deposits, cleaning the precipitation electrodes from the damp or even sludge-like dusts by spraying liquid with nozzles arranged outside the electrical field requires, on the one hand, a corresponding fine distribution of the spray jets and, on the other hand, a certain minimum energy of the impinging liquid drops . From numerous experiments and experiences on built wet electrostatic precipitators, it is known that these two conditions can only be met at the same time if the surface to be cleaned is not too far from the spray nozzle. The liquid jet loses more and more of its kinetic energy with increasing distance from the nozzle and is no longer effective after a certain spray distance for cleaning the precipitation electrodes enough. No fixed values can be given for the maximum permissible spray width or the resulting maximum plate height, because in other cases other restricting conditions have to be taken into account, but the limits are in any case 3 to 5 m.

For the dedusting of converter exhaust gases by means of wet electrostatic precipitators, the efforts for economical cleaning should be considered on the one hand and the constructive and functional conditions must be met on the other hand. There is therefore the task of designing a wet electrostatic precipitator for the dedusting of converter exhaust gases in which can be in the _V ER- equal better for laundry cleaning (with CO gas recovery to about 10 mg / Nm ³⁾ realized at much lower pressure drop, which is designed to be pressure-resistant for the entire exhaust gas flow and with regard to possible deflagrations and whose precipitation electrodes can be effectively cleaned from the separated mixture of dust and condensate by means of a flushing system in the blow breaks.

• a) ein kreiszylindrisches Gehäuse, dessen Strömungsquerschnitt mindestens 20 m² beträgt,
• b) ein oder mehrere in Gasströmungsrichtung hintereinander angeordnete und in der Höhe wenigstens einmal unterteilte Abscheidefelder,
• c) deren obere und untere Teile aus quer zur Gasströmungsrichtung äquidistant im Wechsel angeordneten Sprüh- und Niederschlagselektroden bestehen, ferner durch
• d) spezielle Abtragseinrichtungen für die Elektroden sowie der Spüleinrichtungen.

To solve this problem, a wet electrostatic filter is proposed, which is characterized by

• a) a circular cylindrical housing, the flow cross section of which is at least 20 m ² ,
• b) one or more separating fields arranged one behind the other in the gas flow direction and divided at least once in height,
• c) whose upper and lower parts consist of spray and precipitation electrodes arranged alternately at right angles to the gas flow direction, further by
• d) special removal devices for the electrodes and the rinsing devices.

Further advantageous details and refinements of the inventive concept result from subclaims 2 to 6.

Furthermore, a method for operating the wet electrostatic filter according to the invention is proposed, which is characterized in that the wet cleaning takes place by spraying liquid jets against the precipitation electrodes in each case in the work breaks of the filter with the high voltage switched on.

• Figur 1 zeigt einen Querschnitt durch das Naßelektrofilter mit den Niederschlagselektroden.
• Figur 2 zeigt einen Längsschnitt durch das Naßelektrofilter mit den Niederschlagselektroden.
• Figur 3 zeigt einen Querschnitt durch das Naßelektrofilter mit den Sprühelektroden und den Niederschlagselektroden.
• Figur 4 zeigt einen Querschnitt durch das Naßelektrofilter mit den Niederschlagselektroden und den Spüleinrichtungen.
• Figur 5 zeigt einen vergrößerten Ausschnitt im Bereich der Teilungsebene.

Further details and advantages of the invention are explained in more detail with reference to the embodiment shown in a highly simplified form in the figures:

• Figure 1 shows a cross section through the wet electrostatic precipitator with the precipitation electrodes.
• Figure 2 shows a longitudinal section through the wet electrostatic precipitator with the precipitation electrodes.
• Figure 3 shows a cross section through the wet electrostatic precipitator with the spray electrodes and the precipitation electrodes.
• Figure 4 shows a cross section through the wet electrostatic precipitator with the precipitation electrodes and the rinsing devices.
• FIG. 5 shows an enlarged section in the area of the division plane.

According to FIG. 1, plate-shaped precipitation electrodes 9 are arranged in a circular cylindrical housing 1 parallel to the gas flow direction and suspended in the housing 1 via removal devices 13. The separation fields are subdivided in height, the upper parts being designated 5 and the lower parts 6. Accordingly, separate removal devices 13 must also be provided. The precipitation electrodes 9 of the lower part 6 are arranged offset by half a lane width in relation to the precipitation electrodes 9 of the upper part 5, which will be discussed in more detail in connection with FIG. 5. Outside of the housing 1 is a part of the removal devices 4 for the spray electrodes.

It can be seen from FIG. 2 how the separating fields 2 and 3 arranged in the housing are arranged one behind the other in the direction of gas flow and differently divided in height into upper and lower parts 5 and 6 (division level 7). The direction of gas flow is indicated by an arrow. 4 again designates the upper parts of the removal device for the spray electrodes.

The cross section according to FIG. 3 shows how the precipitation electrodes 9 and the spray electrodes 11 are arranged alternately transversely to the gas flow direction. For a better overview, the removal devices for the precipitation electrode 9 have been omitted. The removal devices 4 for the spray electrodes 11, consist of insulators arranged in special housings above the actual filter housing 1, to which support rods are fastened, which in turn are connected to the support frames for the wire or ribbon-shaped spray electrodes. Details have not been presented because they belong to the prior art. It should only be mentioned that the components appearing approximately semicircular also belong to the removal system 4 for the spray electrodes 11. They are arranged in front of and behind the fields of the precipitation electrodes in the gas flow direction and ensure the removal and equidistant adjustment of the frames for the spray electrodes 11.

FIG. 4 shows the rinsing device together with the precipitation electrodes 9. From a pipe for the liquid supply 14, the rinsing pipes 10 are supplied with liquid which is sprayed against the precipitation electrodes 9 under pressure by means of spray nozzles. The rinsing tubes 10 for the lower part of the precipitation electrodes 9 are simultaneously used to adjust the lower ends of the precipitation electrodes 9 of the upper part. In this way it is possible to realize the inevitable subdivision in height without taking up a lot of space and to limit the "field-free" gas flow cross-section to a minimum. In connection with the offset arrangement of the precipitation electrodes 9, an optimal cleaning is also ensured.

The relationships in the area of the division level between the upper and lower part of the deposition fields are shown again enlarged in FIG. In alternation with the frame for the spray electrodes 11, the precipitation electrodes 9 are arranged, namely in the lower part by a half aisle width B compared to the upper one Part offset. Thereby, the wash pipes 10 are arranged as the upper collecting electrodes 9 and allow the same plane an optimal _A North drying of the spray nozzles 12 and the already mentioned lateral adjustment of the upper collecting electrodes. 9

With the embodiment shown in the figures, an optimal utilization of the housing cross-section available for the gas flow is achieved without any restrictions being accepted with regard to the necessary distances of the spray system from the precipitation electrodes and the devices for supplying and spraying the cleaning liquid Need to become. In this way, the plate height, which was limited with regard to the cleaning of the precipitation electrodes, on the one hand, and the large gas flow cross-section required, on the other hand, could be implemented constructively in a pressure-resistant wet electrostatic precipitator. A dedusting device is now available which, compared to washers, enables a much better gas cleaning with a significantly lower energy expenditure.

Claims (6)

1. Wet electrostatic precipitator for horizontal gas passage for dedusting converter exhaust gases, characterized by a) a circular cylindrical housing (1), the flow cross section of which is at least 20 m ² , b) one or more separating fields (2, 3) arranged one behind the other in the gas flow direction and divided in height at least once, c) whose upper (5) and lower (6) parts consist of spray electrodes (11) and precipitation electrodes (9), which are alternately arranged transversely to the gas flow direction, further by d) removal devices (4, 13) for the electrodes (9, 11) and rinsing devices (10, 12, 14). 2. Wet electrostatic precipitator according to claim 1, characterized in that the dividing planes (7) of the separating fields (2, 3) arranged one behind the other are at different heights. 3. Wet electrostatic precipitator according to claim 1 or 2, characterized in that the upper parts (5) of the separating fields (2, 3) are offset by half a pitch (B) from the lower parts (6) of the separating fields (2, 3) . - 4. Wet electrostatic precipitator according to claim 3, characterized in that the lower ends (8) of the precipitation electrodes (9) of the upper parts (5) of the Separation fields (2, 3) are adjusted by means of the rinsing pipes (10) for the lower parts (6) of the separation fields (2, 3). 5. Wet electrostatic precipitator according to one of claims 1 to 4, characterized in that the separating fields (2, 3) consist of equidistantly arranged, vertical, plate-shaped, gas-gas-forming precipitation electrodes (9), in each case arranged in the middle of the gas-gas spray electrodes (11) and in each case There are rinsing devices (10, 12) arranged at the top between the precipitation electrodes (9) and devices for removing (4.13) the precipitation electrodes (9) and spray electrodes (11) and for the liquid supply (14). 6. A method for operating a wet electrostatic filter according to one of claims 1 to 5, characterized in that the wet cleaning is carried out by spraying liquid jets against the precipitation electrodes (9) each in the work breaks of the filter with the high voltage switched on.

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