DE2433852A1 - PROCEDURE FOR CONDITIONING DUST-LOADED HOT EXHAUST GAS - Google Patents

Description

METALLGESELLSCHAFT Frankfurt / M., April 1, 1974 Aktiengesellschaft Bbl / HGa
6 Frankfurt / Main

prov. No. 7160 LT

Process for conditioning dust-laden hot exhaust gases

The invention relates to a "method for conditioning dust-laden hot exhaust gases by means of an evaporation cooler with dry dust discharge in the lower part of the evaporation cooler and with one downstream of the evaporation cooler electrostatic dust collector.

It is known that the dusts to be separated in electrostatic dust collectors are dependent on the state of the gas have electrical resistance. This dust resistance runs through depending on the temperature and Moisture a curve with a maximum. With a value of

11 specific dust resistance of about 10 ohm · cm a limit value is reached, and if it is exceeded, the separation effect of an electrostatic dust collector is reduced so deteriorated that an enlargement of the electrostatic dust collector is necessary to achieve the desired one To achieve a degree of separation. Efforts are therefore made to keep the operating temperatures of an electrostatic precipitator outside of this To keep the limit range. If this is not possible, however, an attempt is made to condition the gas-dust mixture in such a way that that the resistance of the dust at operating temperatures below the critical dust resistance of

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10 ohm cm. This is possible by adding conditioning agents such as SO ,, H ₂ SO ^, NH-z and others, which are already effective in very small amounts of a few ppm. These are adsorbed by the dust surface, reduce

the electrical resistance of the dust and thereby improve the ability to separate the dust in an electrostatic precipitator (Industrial. Electrostatic Precipitation by Harry J. White, Pergamon Press, Oxford - London - Paris - Frankfurt, 1963, pages 294-330; Dust - keeping the air clean, Volume 26, 1966, No. 1, pages 11-14).

These conditioning methods are only used in exceptional cases.

Another widely used method is the conditioning of the dust by direct gas cooling through injection of finely divided water into an evaporative cooler. The evaporated water is used to cool the Exhaust gases and thus a reduction in the amount of exhaust gas and at the same time to increase the gas humidity. The cooling has the advantage that final temperatures and humidity of the gas can be chosen so that the dust resistance below the critical

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Limit of 10 ohm cm.

Such an evaporation cooler is for example flowed through in cocurrent with the injected water from top to bottom by dusty gas, deflected at the lower end and passed into an electrostatic precipitator. Dust precipitates in an amount of around 10 - 20 % of the dust content in the gas inlet. It collects in the bunker at the lower end of the evaporative cooler, from where it is discharged. The evaporative cooler can be operated both in cocurrent and in countercurrent, ie water is injected with or against the gas flow (DT-AS 1 085 854; Zement-Kalk Gips 23 (1970), No. 3, pages 106-112).

Typically evaporative cooler are used for dust collector, in which the input temperature-en exceed 300 ⁰ C and it is in this case at 120 - cooled down to 140 ° C. Such a preconditioned electrostatic dedusting system then works without any problems. In dedusting systems, the exhaust gases without pre-cooling in the range of 130 - 160 ° C -

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are to clean, electrical disturbances can sometimes occur due to a dust resistance that is still too high, so that further cooling and conditioning is necessary even at these temperatures. If it is necessary to cool to low exhaust gas temperatures, for example to 80 to 100 ^° C., then the evaporative cooler becomes very large and it must preferably be expected that incompletely evaporated water will humidify the dust in the evaporative cooler. By increasing the amount of atomized water you can reduce the exhaust gas temperatures and bring the dust resistance into the desired range, but you have to reckon with difficulties in removing dust from the bunker of the evaporative cooler; Difficulties caused by damp dust. The moisture promotes agglomeration of the dust particles and there is a risk that the dust will clump together to form larger aggregates, which lead to clogging of the dust removal organs, such as redlers, snails and others. This can go so far that an operational shutdown is necessary.

The agglomeration of the particles, i.e. the increase in the adhesive forces between the dust particles, is extensive In addition to the humidity, the fineness of the dust and other physical properties as well as the chemical composition dependent on the dust. This is also reflected in the fact that the residual moisture in the dust is due to the incomplete evaporation in the evaporation cooler can have very different values before the feared malfunctions in the Dust transport organs come. The upper limit of the residual moisture, which leads to these disturbances, must therefore be considered can be determined experimentally for each type of dust.

This is where the invention comes in, which set itself the task has to avoid these disadvantages and also with increased addition of water or incomplete evaporation of the sprayed water in the evaporation cooler to make moist dust flowable again in order to achieve a

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to achieve undisturbed conditioning of the dust for separation in the electrostatic precipitator.

The object is achieved in that the residual moisture of the dust in the dust removal organs of the evaporative cooler is reduced by adding dry dust until the dust can flow again.

It has been found, surprisingly, that the flowability of the dust can be restored by adding dry dust if / the amount of dry dust added is selected so that the mean residual moisture content is below a certain level. As already explained above, this limit value for the humidity differs from case to case and can only be determined through experience with the systems that have been implemented. Flue gas dusts from the combustion of coal behave somewhat differently than dusts from cement processes, for example mill dust or dust from heat exchange processes. It is known that ζ. B. a residual moisture of about 0.5 % generally has no effect on the flowability of dusts. On the other hand, a residual moisture of 1 % can lead to malfunctions in one case and a residual moisture of 8-10% in the other.

With knowledge the residual moisture build an evaporative cooler smaller in order to obtain a higher moisture content, whereby one has this disadvantage can compensate again by adding appropriate amounts of dry dust according to the invention.

According to a preferred embodiment of the method, the dry dust is added to the dust removal element at the bunker outlet of the evaporation cooler.

Since the disturbances mainly occur in these transport organs due to constipation, the addition offers a good possibility the dry and damp dust evenly with one another

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to mix and maintain undisturbed transport.

According to a further embodiment of the method, the dry dust is added before or in the evaporation cooler.

The residual moisture in the bunker can also be reduced by increasing the dust content in the inlet of the evaporation cooler Dust can be reduced.

Finally, according to a further preferred embodiment of the method, there is also the possibility of adding dry dust in the lower part of the evaporative cooler via a distribution device.

Although this requires a little more effort, it has the advantage that the residual moisture content in the bunker is too high can be reduced, especially if there is a risk of build-up due to damp dust due to the special Properties of a dust is to be feared.

According to a further preferred embodiment of the invention, the dust precipitated in the electrostatic dust collector is dry dust is at least partially mixed with the moist dust generated in the evaporative cooler.

By adding dust from the electrostatic dust collector, the residual moisture in the mixed dust from the evaporation cooler and electrostatically separated dust can be reduced in the ratio (evaporation cooler dust): (evaporation cooler dust + electrostatically separated dust), for example in a ratio of 1:10 if the proportion of evaporation cooler dust is 1 / 10 and the proportion of the electrostatically separated dust is 9/10, ie the residual moisture can be reduced, for example, from 10% to 1% or from 5 % to 0.5 %. This also makes it possible, for example, to use the evaporative cooler with a smaller one

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Volume to "build, if one has a higher residual moisture from the start in the evaporation cooler dust and the flowability of the dust by a corresponding reduction of the moisture content according to the method according to the invention. But it is also possible, just a part of the separated dust from the electrostatic precipitator, for example dust from the first two thirds or the first half of the electrostatic dust collector and the remaining part of the electrostatic precipitated Collect dust separately because of its special properties. Because it is known that an electrostatic precipitator selectively separates, so that at the end of the electrostatic precipitator a chemically somewhat different dust, for example with a higher Alkalinity, occurs as at the beginning of the filter.

The method according to the invention makes it easy to overcome malfunctions in an evaporative cooler. Evaporative coolers can be made smaller without having to accept a loss of adequate conditioning of the exhaust gases with regard to the electrical dust resistance for the electrostatic precipitator. There are no separate Sam m same container necessary for electrostatically deposited dust and evaporation cooler dust. In the combination of an evaporation cooler and an electrostatic separator, a common dust discharge device can be used.

The invention is explained in more detail and by way of example with reference to the figure described.

The figure shows an arrangement of an evaporative cooler with an electrostatic dust collector.

About the Channel 1 flows in this example with a system operated in parallel flow evaporative coolers usually about 300 ⁰ C hot gas into the head of the evaporative cooler: 2. Here are gas distribution system and deflecting intended for Vergleicnmäßigung the gas flow. The evaporative cooler 3

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is an empty tower with a nozzle 4 at the upper end, through which a regulated amount of water in fine Droplet is introduced atomized. On the way from the head of the evaporation cooler to the gas exhaust duct 5 flow hot gas and atomized water and in doing so takes place a direct gas cooling through the rapid evaporation of the Water particles instead. The cooled and saturated gas reaches the electrostatic dust separator 6 via the gas exhaust duct 5. By cooling and saturating the Gas in the evaporative cooler, the gas is conditioned. The dust resistance is outside the critical range and the dust can be optimally separated in the electrostatic precipitator. The deposited dust is dry and will after its cleaning of the collecting electrodes 7 either in separate dust bunkers 9 or in a trough-shaped Bunker collected and by redler or dust screw 10 or other transport method on the bottom of the bunker 9 or the trough bunker. The accumulating in the evaporation cooler base 8 below the gas exhaust duct 5 Dust is also removed via a dust screw 12 or similar.

A humidity measuring device 11 for determining the residual humidity of the dust is expediently located in the outlet of the evaporative cooler. If you want to introduce the separated dust from the electrostatic precipitator into the bunker 8, it is expedient to build a switch 13 in the dust conveyor 10 ,. from where the dust via a distribution system 14 into the bunker of the evaporative cooler 3 is introduced.

example 1

In a combination of evaporation cooler and electrostatic precipitator, 220,000 Nm ^ / h of gas with 60 g / Nm- ⁵ dust were conditioned and dedusted in a cement plant. In the evaporative cooler, the temperature was lowered from 350 ° C to 15P ° C in front of the electrostatic dust collector. The degree of separation of the dust separator was 99.92 %. Approx. 13,200 kg / h were deposited in the evaporation cooler and electrostatic precipitator. Of this, the evaporative cooler accounted for 12 %, ie about 1584 kg / h

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a residual moisture of 8 %. In the evaporative cooler outlet and in the dust removal organs, blockages often occurred, so that an operational shutdown was necessary.

In an experiment, the dust removal devices of the electrostatic dust collector were connected to the dust removal device of the evaporative cooler and the mixed dust was brought to a residual moisture content of 0.96%. Experiments showed that the dust still at about 2.5 - was good flowability 3% and was only 3% from expected major disruptions. In this way, it was possible to reduce the addition of dust to approx. 4,000 kg / h, with an average residual moisture level of 2.5%.

In a further experiment, the same amount was blown into the bunker and distributed via pneumatic conveying through an arrangement of perforated pipes. The residual moisture of the dust mixture was 2.6 %.

In all cases, sufficient conditioning of the gases in the electrostatic precipitator was achieved. The dust-

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resistance in all cases was below 10 0hm · cm, approximately at

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2 x 10 ohm cm. The separated dust with a residual moisture of 0.9 - £ 6 % was free-flowing and clogging no longer occurred during operation.

Example 2 _?

In a power plant there were 1,250,000 only / h of exhaust gas in one electrostatic dust collector at an exhaust gas temperature Treated from approx. 128 - 132 ° C. The dust content was 15 g / Nm. The untreated, not preconditioned dust-gas mixture had an electrical dust resistance far

11 above the critical dust resistance of 10 ohm cm. The electrostatic dust separator had correspondingly poor separation performance, which is already evident small temperature changes improved.

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In order to remedy this, evaporative cooling for temperature reduction and conditioning was installed later. Die'Abgastemperatur was increased to about 105 by injecting fine water darken - 110 ⁰ C lowered. The residual dust content behind the electrostatic dust collector could now. safely below 100 mg / Nm. Approx. 6 % of the total dust, ie approx. 1.125 t / h on average, was produced in the evaporation cooler section. The residual moisture in the dust was 5 %. In this state, larger lumps of dust in the dust discharge led to temporary disruptions in the dust transport. In order to eliminate these disturbances, increasing amounts of separated dust were returned from the electrostatic dust separator and continuously introduced into the cooler part near the wall. As a result, the residual moisture of the dust mixture in the dust outlet from the evaporation cooler part decreased from an initial 5 % to approx. 1.1 %, corresponding to an addition of 4.6-4.8 t / h of dust to the amount of dust occurring in the cooler part itself of approx. 1.1 - 1.2 t / h. Even with a residual moisture content of 1.5 %, corresponding to an addition of dust of approx. 3.8 t / h, there were no longer any operational disruptions.

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Claims

CiTiAOOO

Claims (5)

Claims Process for conditioning dust-laden hot exhaust gases using an evaporative cooler with dry
Dust discharge in the lower part of the evaporation cooler and
with one downstream of the evaporative cooler
Electrostatic dust separator, characterized in that the residual moisture of the dust in the dust removal organs of the evaporative cooler is reduced by adding dry dust until the dust can flow again. 2. The method according to claim 1, characterized in that the addition of dry dust in the dust removal organ at the bunker outlet of the evaporation cooler directly
he follows. 3. The method according to claim 1, characterized in that the addition of dry dust takes place before or in the evaporative cooler. 4. The method according to claim 3, characterized in that the addition of dry dust in the lower part of the
Evaporative cooler via a distribution device
he follows. _t 5. The method according to claims 1 to 4, characterized in that the separated in the electrostatic dust separator dry dust at least partially
the damp dust accumulating in the evaporative cooler
is mixed. / nc ι -5