DE3928808C1 - Treating chemical pollutants - by passage of waste gas through multiple passages between collector plates - Google Patents

Abstract

During a period forming 60-80% of total treatment time in an electrostatic cleaner for gas contg. dust and pollutants, waste gas first travels through the multiple passages between collector plate electrodes, operated dry. A subsequent set of collector electrodes have their surfaces wetted by an alkaline aq. soln., pH 7-9 sprayed onto the upper electrode surfaces. Washing liq. reaching the electrode feet is laterally extd. while any substantially dry dust collecting in the second unit is removed by a worm conveyor. All electrodes are subjected to polsating charges, and space round second unit electrodes is filter with hot gas. ADVANTAGE - Largely separate treatment of dust and chemical pollutants minimises sludge formation.

Description

The invention relates to a method for electrostatic cleaning containing dust and pollutants Exhaust gases in multi-field separators, the exhaust gases in Flow direction in the first stage is one dry electrostatic cleaning in from plate-shaped Precipitation electrodes formed and subjected to gas lanes then in a second stage through one or more fields with liquid-wetted, gas lanes Precipitation electrodes are passed and on a Device for performing the method.

Processes for the electrostatic cleaning of exhaust gases containing dust and pollutants, in which the exhaust gases are fed to dry electrostatic cleaning in a first process step and then to a wet electrostatic cleaning in a second process step, are known. GB-PS 9 88 350 describes a method for electrical dust separation in which a drying tower, one or more dry-working electrical fields and one or more wet-working electrical fields are arranged one behind the other. The water sprayed through nozzles into the wet field (s) flows off as cloudy, is thickened by thickener and injected into the drying tower by steam or compressed air, where the evaporated liquid humidifies the hot dryer gas and thus prevents spraying back in the dry working fields. As from the article "Hybrid-type electrostatic precipitator" by Masuda, Air Pollut. Control Assoc. 1977, 27 (3), 241-2 (Eng.), Acidic components such as So _x , HF and HCl are absorbed by the liquid sprayed into the wet stage and arrive together with the dust still accumulating in the wet stage in a swamp arranged in the wet stage. This method has the disadvantage that a sludge is obtained in the sump of the wet stage, which in addition to the dust contains a relatively large amount of pollutants, which makes it difficult to process the sludge. Another disadvantage of this method is that the evaporated liquid injected into the drying tower humidifies the exhaust gas containing dust and pollutants, which results in an increase in the dew point. Since the gas temperature is simultaneously lowered during this process, the electrostatic filter falls below the dew point, so that corrosion caused by the acidic components in the exhaust gas cannot be avoided.

In CH-PS 3 62 682 an electrostatic filter with vertical and parallel, plate-shaped deposition electrodes described between which high-voltage electrodes lie. The Separation electrodes of this electrostatic precipitator have many interrupted, uneven separating surface. By adding Flushing liquid forms on the separating electrodes coherent, the interruptions of the electrode surface spanning, slowly flowing liquid film for recording and to remove the separated dust particles.

In US-PS 43 60 366 is a classic wet electrostatic precipitator described in which the washing liquid is sprayed and in addition to the precipitation electrodes, the housing wall of the Wet electrostatic precipitator. The washing liquid is below of the electrodes taken from tubs that look like a Venturi nozzle are shaped. The majority of this process is also used of the dust to the precipitation electrodes and is from the Washer fluid discharged.

In US-PS 17 66 422 is also a method for electrostatic cleaning containing dust and pollutants Exhaust gases described in which the dust and pollutants laden exhaust gas first a dry electrostatic Cleaning and then a wet electrostatic Cleaning is supplied. With this procedure the Precipitation electrodes in the wet electrostatic Cleaning stage wetted with a treatment liquid. The gas velocity is in the electrostatic precipitator chosen so high that the fine grain fraction in the dry electrostatic cleaning stage, the large grain fraction in separated from the wet electrostatic cleaning stage becomes. With this method, too, the wet falls in the swamp electrostatic cleaning step off a sludge that besides the dust also contains a relatively large amount of pollutants contains. In addition, this method has the disadvantage that the exhaust gas with a relatively high gas velocity is passed through the electrostatic precipitator to cause the coarse grain fraction of the exhaust gas containing dust in the wet electrostatic Cleaning stage can be separated. This has to Consequence that the residence time of the exhaust gas in the wet electrostatic cleaning level is too low to the in Exhaust gas contained to such an extent  remove that the limit values of TA-Luft from February 27th, 1986 for the pollutants in the clean gas can be maintained.

The invention is therefore based on the object Process for electrostatic cleaning dust and pollutant-containing exhaust gases in multi-field separators create which the above Avoids disadvantages and one separate separation of dry dust on the one hand and Pollutants, on the other hand, allow those in the exhaust contained pollutants in the wet electrostatic Cleaning stage separated as dust-free as possible should be.

The object on which the invention is based is achieved in that the liquid added in the second stage to the upper end of the precipitation electrodes is collected directly under the lower ends of the precipitation electrodes and discharged laterally from the separator, and in that the residue which still arises in the second stage is essentially dry dust is fed to a dust collector. "Dust" means the solid particles contained in the exhaust gas; For example, in sintering plants, the dust consists mainly of iron oxide-containing solid particles, and in combustion plants, it consists of the small fly ash particles. The term "pollutants" includes the acidic components contained in the exhaust gas such as HF, SO ₂ , SO ₃ and HCl and the non-ferrous metals such as Pb, Cd, Hg and As in the exhaust gas in gaseous or sublimed form. At least one electric field is arranged in the first stage and in the second stage of the multi-field separator used. With an exhaust gas volume of 100,000 m ³ / h, the field strength is 1.5 to 2.5 kV / cm and the total precipitation area of the multi-field separator is in the range of 400 to 700 m ² . Metal plates, metal nets, plastic mesh or plates made of ceramic materials can be used as plate-shaped precipitation electrodes. The liquid applied to the upper ends of the precipitation electrodes in the second stage is an aqueous solution. Various types of devices such as dust bunkers, dust collecting channels and discharge elements such as screw conveyors can be used as the dust collecting device.

While in the first stage the vast majority of the Dust is separated dry, can also still in the second stage dust largely dry separated and thus separated from the pollutants. This is achieved in that only the Precipitation electrodes are wetted and that for Sprinkling liquid used just below the Precipitation electrodes are led away in collecting channels, during the actual gas lane room as well as the room stay dry below the electrodes. Hence only gets a very small part of the dust in the liquid.

The method has the advantage that those contained in the exhaust gas Pollutants in the second stage do not match those in the second stage, essentially dry Dust is mixed and discharged from the separator. In the second stage, no one falls with pollutants loaded sludge, the disposal of which is problematic. This method also enables dust resistance to lower far that the phenomenon of back spraying is avoided and a separation of dust and Pollutants occur in such a way that the limit values for Pollutant concentrations in the clean gas are relatively high be undercut.

According to a preferred embodiment of the invention the residence time of the gases in the first stage is 60 to 80% of total residence time in a multi-field separator. This measure causes the Gas temperature in the second stage only approximately  Temperature difference by which the Gas temperature through the downstream fan as a result of Gas compression increased again. At the same time Raising the water dew point by only approx. 4 ° C. This has to Consequence that the distance between gas temperature and Water dew point in the second stage of the multi-field Separator is chosen so large that it does not become one Falling below the water dew point and thus to one Condensation of the acidic pollutants on the non-wetted dry parts of the second stage comes. Special Measures to prevent corrosion in the second stage are therefore not necessary. At the same time, the division of the residence time according to the invention the coarse grain fraction of the dust in the first stage and a separation of the fine grain content of the dust in the second stage. The process can thus be carried out with little Gas velocities are performed successfully, with the dwell time in the second stage is sufficient for the Sufficient pollutants from the exhaust gas remove.

Another preferred embodiment of the invention exists in that an alkaline aqueous solution as a liquid with a pH of 7 to 9 is used. Using such an alkaline aqueous solution becomes acidic Pollutants bound in a relatively large amount, so that from Clean gas discharged in the second stage is almost free of acid Is pollutants.

According to a further embodiment of the invention, NaOH and / or KOH and / or Ca (OH) _{2 is} added to the liquid. These substances are readily soluble in water, so that a pH in the range from 7 to 9 can be set quickly and without problems in the aqueous solution.

According to a further preferred embodiment of the invention the precipitation electrodes with a pulse voltage in  Range of 20 to 400 ms applied. In contrast to normal operation of an electrostatic precipitator are due to this measure only as many DC voltage pulses Spray electrode turned on that just enough Charge carrier for the separation of the in the raw gas stream existing dust are generated. Then for the thyristor is blocked for a period of 29 to 400 ms, the separator voltage decreases exponentially until the next DC voltage pulses are switched through. Between the individual DC voltage pulses the separator voltage at an optimal lower limit held to an excessive drop in the separator voltage and thus the driving force for the migration of the loaded Avoid dust particles to the precipitation electrode. Are the precipitation electrodes with a pulse voltage in Range from 20 to 400 ms, so a high Dust separation already in the first stage of the multi-field separator reached. Through this too The measure ensures that the coarser fraction of the Dust already in the first stage of the multi-field Separator can be separated.

According to a further preferred embodiment of the invention the dead space between the precipitation electrodes and the housing wall of the separator in the second stage Purged hot gas. The hot gas enters the Dead space. One caused by falling below the dew point Condensation of the water vapor contained in the exhaust gas to the Walls and the associated corrosion of the components the second stage can be avoided.

According to a further embodiment of the invention as Hot gas is part of that discharged from the second stage Clean gas used. This measure ensures that by flushing the dead space again in pollutants reach the second stage of the multi-field separator. The injected clean gas is largely free of pollutants,  so that corrosion specifically on the walls of the housing of the multi-field separator almost completely avoided becomes.

The object underlying the invention is further achieved by solved the creation of a device in which the Precipitation area of the precipitation electrodes of the second Level 20 to 45% of the total precipitation area of the Separator is. This allows dust and Pollutants even at low gas speeds largely remove from the exhaust so that the prescribed clean gas limit values for the dust and Pollutant concentrations are relatively low will.

According to a preferred embodiment of the invention, overflow troughs are arranged at the upper ends of the precipitation electrodes of the second stage and collecting troughs are arranged at the lower ends of the precipitation electrodes of the second stage, the precipitation electrodes of the second stage being attached to the lower end of the respective overflow troughs. On the one hand, this measure effects a uniform sprinkling of the precipitation electrodes, on the other hand it is ensured that the liquid loaded with the pollutants can be caught relatively free of dust directly below the lower ends of the precipitation electrodes and then discharged. The collecting troughs are dimensioned so that they can accommodate the amount of liquid, the throughput of which is usually 40 to 80 m ³ / h with an exhaust gas amount of 100,000 m ³ / h. The overflow channels are dimensioned so that the precipitation electrodes are evenly wetted with a liquid film. If the precipitation electrodes of the second stage are attached to the lower end of the respective overflow channels, a uniform wetting of the precipitation electrodes is achieved starting from the upper end of the precipitation electrodes.

According to a further embodiment of the invention at least one edge of the individual overflow channels comb-shaped. By this measure is ensured that the precipitation electrodes were even be wetted with a liquid film and that the thickness of the liquid film over the precipitation area of the respective precipitation electrode is approximately constant. This enables a uniform separation of the Pollutants in the second stage, almost each total precipitation electrode area for the deposition the pollutants are available and Oversizing the individual Precipitation electrode surfaces are not required.

According to a further embodiment of the invention a hot gas supply arranged in the second stage. The Arrangement of a hot gas supply in the second stage allows flushing the dead space between the Precipitation electrodes and the housing wall of the separator in the second stage with hot gas.

Another embodiment of the invention is that the edges of each second stage precipitation electrode are connected to a pipeline connected to the Liquid supply is connected. This has the Advantage that the liquid directly the individual Overflow channels can be supplied, the individual Gas lanes between the precipitation electrodes for the Gas passage are kept clear so that the Separation process in the second stage of the multi-field Separator is not hindered.

According to a further embodiment of the invention provided that the pipeline at the bottom of each Second stage precipitation electrode with openings is provided. This has the advantage that liquid is also in the collecting troughs are injected directly so that these during  performing the procedure cleaned at the same time become and thus a discharge of those loaded with pollutants Liquid from the collecting troughs is ensured. The Openings are designed so that the liquid can also be circulated and still a Closure of the openings by already loaded liquid is avoided.

According to a further embodiment of the invention is in everyone Overflow channel on the liquid supply connected, with openings Liquid distribution pipe arranged. According to this arrangement the liquid can flow directly from the individual overflow channels be fed above. It is also with this arrangement possible to circulate the liquid.

According to a further embodiment of the invention, each Overflow channel with the respective liquid distributor pipe connected. This measure ensures that each Precipitation electrode over the respective overflow channel directly with the respective liquid distributor pipe is connected, what a quick at repair work Allows access to the precipitation electrode.

The object of the invention is explained below with reference to the drawings ( Fig. 1 to 9).

Fig. 1 shows a longitudinal section through the multi-field separator with three separate electrical fields, the third field being equipped with wetted precipitation electrodes and looking as a second stage.

Fig. 2 shows a cross section through the second stage of the multi-field separator.

Fig. 3 shows a precipitation electrode, the edges of which are connected to a pipeline, with liquid supply and collecting channel.

Fig. 4 shows a perspective section of some gas lanes of the second stage of the multi-field separator.

Fig. 5 shows the perspective view of a wetted precipitation electrode with the overflow channel and the apertured liquid distributor pipe, which is connected to the liquid supply.

FIG. 6 shows a side view of the precipitation electrode according to FIG. 5.

Fig. 7 shows a cross section through the upper part of a wetted precipitation electrode with overflow channel, liquid distributor pipe and liquid supply.

Fig. 8a, 8b, 8c show various embodiments of the overflow edge of the overflow channels.

Fig. 9 shows a perspective section of a collecting channel with the extending to the lower edge of each collecting electrode pipe.

In Fig. 1 a longitudinal section of the multi-field precipitator is illustrated. The exhaust gas laden with dust and pollutants enters the first stage 1 , in which the dry electrostatic cleaning takes place, in the direction of the arrow. In the first stage 1 there are dry working precipitation electrodes 3 a and spray electrodes 4 which are held in a suspension device 18 and are electrically insulated with support insulators 19 . The cleaning of the dry type precipitation electrodes 3 a of the first stage 1 is effected by periodically tapping during operation. In order to discharge the dry dust, a dust collecting device 5 a and a discharge device 6 a are provided in the first stage 1 . The exhaust gas enters the second stage 2 immediately after the dry electrostatic cleaning. In the second stage 2 there are precipitation electrodes 3 b and spray electrodes 4 wetted with liquid. As in the first stage 1 , the precipitation electrodes 3 b and spray electrodes 4 are electrically insulated with post insulators 19 . The liquid loaded with pollutants runs down the respective precipitation electrode surfaces and reaches the respective collecting troughs 8 . A dust collecting device 5 b and a discharge device 6 b are provided for the separation of the dust which is dry in the second stage. A hot gas supply 11 is arranged in the second stage 2 of the multi-field separator. The hot gas 21 passes through the nozzles of the hot gas supply 11 into the dead spaces between the precipitation electrodes 3 b and the housing wall 9 of the separator. The clean gas leaves the second stage 2 of the multi-field separator in the direction of the arrow.

In Fig. 2 is a cross section through the second stage 2 of the multi-field precipitator with the collecting electrodes 3b, the emission electrodes 4, the overflow channels 7, the collecting grooves 8 and the hot gas supply 11. The dust collecting device 5 is carried out for b Fig. 2 as a discharge screw which a discharge device 6 supplies the resulting in the second stage 2 dry dust b. The liquid, which is collected by the collecting troughs 8 and is loaded with pollutants, is discharged laterally via an outlet 20 . Via the outlet 20 , the loaded liquid, in which dissolved salts are present, can be fed to a downstream crystallization system, in which the dissolved salts are obtained as solids.

In Fig. 3, a wetted precipitation electrode 3 b is shown with a liquid supply 13 and the collecting channel 8 . The liquid passes from the liquid feed 13 via a pipeline 12 to the overflow channel 7 and from there via the precipitation electrode surface into the collecting channel 8 . The loaded liquid is discharged via the outlet 20 .

In FIG. 4 is a perspective cut-out is some gas passages between the collecting electrodes 3b by hot gas inlet 11, overflow channels 7 and collecting grooves 8 illustrated. The liquid is supplied through the conduit 12 of the respective overflow channel 7 and passes the overflow channel 7 b over edges 10 to the precipitation electrode. 3 The hot gas 21 is injected through the hot gas supply 11 into the dead space between the precipitation electrode 3 b and the housing wall 9 of the separator.

In Figs. 5, 6 and 7, a collecting electrode 3 is b with the overflow channel 7 and the collecting channel 8 shown in which the liquid is supplied from the top of the overflow channel 7. The liquid passes into the overflow channel 7 via a liquid distributor pipe 15 which is provided with openings 16 and is connected to the liquid supply 13 . The precipitation electrode 3 b is weighted down by a weight 17 . This enables them to be fixed centrally in the collecting trough 8 . In Fig. 6, a valve 23 is arranged outside the housing wall 9 of the separator in the liquid feed 13 , with which the amount of liquid can be metered exactly. As shown in FIG. 7, the liquid feed 13 and the liquid distributor pipe 15 are connected to the overflow channel 7 by webs 22 . Thus, the electrode 3 b can be held directly on the overflow channel 7 on the liquid distributor pipe 15 and the liquid supply 13 .

Figs. 8a, 8b and 8c show various embodiments of the edge 10 of the overflow grooves 7. In contrast to a smooth edge, the comb-shaped design enables the liquid to be fed uniformly to the precipitation electrode 3 b .

In Fig. 9 a collecting channel 8 is shown with a part of the pipe 12 at the lower edge of a collecting electrode 3 b. A portion of the supplied liquid passes directly into the collecting channel 8 through openings 14 and rinses it out. The unloaded liquid is discharged from the collecting channel 8 together with the loaded liquid.

The invention will now be described with reference to an example described:

The amount of exhaust gas from a sintered belt is 400,000 Nm ³ / h, the exhaust gas having a temperature of 120 ° C, a dew point of 40 ° C and a dust content of 1 g / Nm ³ .

The duration of the treatment time in the first stage 1 of the multi-field separator is 6.2 s, the treatment time in the second stage 2 of the multi-field separator is 1.8 s. The precipitation area of the precipitation electrodes 3 b of the second stage 2 is 23% of the total precipitation area of the separator.

The throughput for the liquid for wetting the precipitation electrodes 3 b is 300 m ³ / h. At a field strength in the range from 1.5 to 2.5 kV / cm, a residual dust-like content after treatment was measured in the first stage 1 of 135 mg / Nm ³ and in the second stage 2 of 21 mg / Nm ³ . The emission values for dusty inorganic substances were below the second level 2 for class I (Cd, Hg etc.) below 0.2 mg / Nm ³ , for class II (As, Ni etc.) below 1.0 mg / Nm ³ and for class III (Pb, F, Sn etc.) below 5.0 mg / Nm ³ (classification of the dust-like inorganic substances according to TA-Luft from February 27, 1986). The limit values for vaporous or gaseous inorganic substances - especially for SO ₂ with 500 mg / Nm ³ - were not exceeded in the test.

The temperature drop in the area of the wetted precipitation electrodes 3 b was approximately 25 ° C., as a result of which the gas temperature dropped to 95 ° C. and the dew point was raised to 44 ° C. The downstream fan increased the gas temperature by 24 ° C, which raised it to 119 ° C again. The gas thus had a gas inlet temperature at the chimney base of 119 ° C. Furthermore, the relatively slight cooling of the exhaust gas, which was brought about in accordance with the invention in the second stage 2 , achieved an energy saving of approximately 120 kW for the 3 MW fan used at a gas inlet temperature of 95 ° C. and a dew point of 44 ° C.

Claims (15)

1. A method of electrostatic cleaning of dust and pollutant gases in multi-field separators, wherein the exhaust gases in the flow direction in a first stage (1) of plate-shaped collecting electrodes (3a) formed gas passages first subjected to a dry electrostatic cleaning and then in a second stage ( 2 ) through one or more fields with liquid-wetted, gas lanes forming precipitation electrodes ( 3 b) , characterized in that the liquid applied in the second stage ( 2 ) to the upper end of the precipitation electrodes ( 3 b) immediately below the lower ends of the Precipitation electrodes ( 3 b) are collected and laterally discharged from the separator and that the essentially dry dust still accumulating in the second stage ( 2 ) is fed to a dust collecting device ( 5 b) . 2. The method according to claim 1, characterized in that the residence time of the gases in the first stage 60 to 80% the total dwell time in a multi-field Separator is. 3. The method according to claim 1 or 2, characterized characterized in that an alkaline liquid aqueous solution with a pH of 7 to 9 used becomes. 4. The method according to claim 3, characterized in that the liquid NaOH and / or KOH and / or Ca (OH) _{2 is} added. 5. The method according to any one of claims 1 to 4, characterized characterized in that the precipitation electrodes with a pulse voltage in the range of 20 to 400 ms be charged. 6. The method according to any one of claims 1 to 5, characterized in that the dead space between the precipitation electrodes ( 3 b) and the housing wall ( 9 ) of the separator in the second stage ( 2 ) is flushed with hot gas ( 21 ). 7. The method according to claim 6, characterized in that part of the pure gas discharged from the second stage ( 2 ) is used as the hot gas ( 21 ). 8. Apparatus for carrying out the method according to one of claims 1 to 7, which consists of a first stage ( 1 ) for dry electrostatic cleaning and a second stage ( 2 ) with liquid-wetted, gas-forming precipitation electrodes ( 3 b) , characterized that the precipitation area of the precipitation electrodes ( 3 b) of the second stage ( 2 ) is 20 to 45% of the total precipitation area of the separator. 9. The device according to claim 8, characterized in that at the upper ends of the precipitation electrodes ( 3 b) of the second stage ( 2 ) each overflow channels ( 7 ) and at the lower ends of the precipitation electrodes ( 3 b) of the second stage ( 2 ) in each case Collecting channels ( 8 ) are arranged, the precipitation electrodes ( 3 b) of the second stage ( 2 ) being attached to the lower end of the respective overflow channels ( 7 ). 10. The device according to claim 9, characterized in that at least one edge ( 10 ) of the individual overflow channels ( 7 ) is comb-shaped. 11. Device according to one of claims 8 to 10, characterized in that a hot gas supply ( 11 ) is arranged in the second stage ( 2 ). 12. Device according to one of claims 8 to 11, characterized in that the edges of each precipitation electrode ( 3 b) of the second stage ( 2 ) are connected to a pipeline ( 12 ) which is connected to the liquid supply ( 13 ). 13. The apparatus according to claim 12, characterized in that the pipe ( 12 ) at the lower edge of each precipitation electrode ( 3 b) of the second stage ( 2 ) is provided with openings ( 14 ). 14. Device according to one of claims 8 to 11, characterized in that in each overflow channel ( 7 ) is connected to the liquid supply ( 13 ) connected with openings ( 16 ) provided liquid distributor pipe ( 15 ). 15. The apparatus according to claim 9 or 14, characterized in that each overflow channel ( 7 ) is connected to the respective liquid distributor pipe ( 15 ).