DE3507596A1 - Process and apparatus for dry or semi-dry separating out of gaseous pollutants from exhaust gases, in particular flue gases - Google Patents

Abstract

In processes of this type, the polluted exhaust gases exiting from a combustion plant (1) are mixed in a reaction section (2) with a sorbent, by means of which the pollutants are bound, so that they can be removed from the exhaust gas in a downstream separating device (3). Although these dry or semi-dry processes are less complex in comparison to wet processes, they have the disadvantage of lower degrees of separation and a higher consumption of sorbent. To improve the degree of separation and reduce the consumption of sorbent, an improved mixing between exhaust gas and sorbent is induced in the reaction section (2) by irradiation with sonic energy (4) (Fig. 1). <IMAGE>

Description

Method and device for dry or quasi-dry drying

separation of gaseous pollutants from exhaust gases, especially smoke gases The invention relates to a method for dry or quasi-dry deposition gaseous pollutants from exhaust gases, in particular flue gases, in which the exhaust gas mixed with a sorbent serving to sorb the gaseous pollutants which is separated from the exhaust gas after the sorption of the pollutant, and to a device for carrying out this method.

There are wet working methods for cleaning up Smoke gases known, in which a sorption of harmful gas molecules, such as HF, HC1, S02 or S03 takes place below the dew point. Such wet-working processes are notable through a high degree of separation, whereby the consumption of added sorbent, such as calcareous substances, magnesium-containing substances, ammonia and the like. is only slightly above the stoichiometric amounts. However, these show wet working processes the disadvantages of water saturation of the cleaned flue gases that require reheating, as well as high energy consumption, partially as yet unsolved corrosion difficulties and problems in the area of the required Wastewater treatment.

On the other hand, these disadvantages occur with dry or quasi-dry Process for separating gaseous pollutants from exhaust gases does not exist, so that these dry or quasi-dry processes mainly for cleaning flue gases in Appear suitable in the area of smaller and medium-sized systems. However, are known method of the type mentioned with the disadvantage that they a lower degree of separation and / or a higher consumption of sorbent exhibit.

This in the known processes for dry or quasi-dry Deposition difficulties occurring can be understood due to the fact that the chemical sorption of the pollutants takes place in principle in two stages. In the first stage there is an adsorption, i.e. an accumulation of the molecules of the gaseous pollutant to the molecules of the sorbent, while in the second At the 2nd stage an absorption, i.e. a chemical conversion to reaction molecules takes place. These processes can be in a Gas-gas phase as well complete in a gas-solid phase. So there is one of the most important prerequisites for achieving a high degree of separation with the lowest possible at the same time Amounts of sorbent in it, the pollutant exhaust gases and the sorbent to mix as well as possible while avoiding high pressure losses and this mixing to be maintained for a time sufficient for the sorption process.

In the known processes for dry or quasi-dry deposition This mixing is of the type mentioned at the beginning in very different ways brought about, such as through the use of static gas mixers, the use of vortex sink reactors, the spraying of aqueous solutions to achieve the Mixing by evaporation and the like because of unfavorable boundary conditions, such as a poor distribution of the sorbent in the exhaust gas flow, streaking, insufficient exhaust gas partial flows interspersed with the sorbent, too little turbulence in the However, currents and the like remain the results of the dry or quasi-dry Process behind the wet-working process so far significantly behind.

The invention is based on the object of a method for dry or quasi-dry separation of gaseous pollutants from the exhaust gases at the beginning mentioned type to the effect that a higher degree of separation and a lower consumption of sorbent is achieved, as well as a device for The implementation of this procedure.

According to the invention, this object is thereby achieved with regard to the method solved that radiated sound energy into the mixture of exhaust gas and sorbent will.

Due to the radiated sound energy in the mixture of exhaust gas and sorbent caused pressure waves both in the gas-gas phase as well also in the gas-solid phase between the gaseous pollutant and the sorbent lead to a very intensive mixing. The reason for this is likely to be in one of the relative speed between the sorbent caused by the radiated sound and the pollutant molecules can be seen.

Advantageously, in a preferred embodiment of the invention Procedure the sound frequency to achieve a maximum speed difference matched between the pollutant molecules and the sorbent particles. Under this condition creates an intense reaction contact between the pollutant and the sorbent achieved, which optimizes the degree of separation and the required amount of sorbent is useful.

Another variant of the method according to the invention provides that the sound frequency with an order of magnitude of the sorption time or less lying period duration tuned periodically over a certain frequency range will. In this way it can be achieved that the mixture of pollutant-laden exhaust gas and sorbents a continuous sequence of sound pressure states during the sorption time runs through, so that even if the other process parameters are changed the setting of favorable mixing conditions can be expected.

On the other hand, it can also be provided in this regard that a superposition of several sound frequencies is radiated.

A particularly advantageous way of carrying out the process is evident characterized in that the frequency of the radiated sound energy in the infrasound range lies. If the other process parameters allow such a frequency selection, In this way, any noise pollution in the environment is particularly simple avoided.

A device for carrying out the method according to the invention with an intermixing through which the exhaust gas and the sorbent flow of the exhaust gas and the sorbent for a sorption serving reaction path and a separating device connected to the outlet of the reaction section Separation of the pollutant-laden sorbent is distinguished according to the invention characterized in that the reaction path irradiates its volume with sound energy Has sounder.

The sound energy emitted by the sounder causes the in the desired intensive reaction path of the device according to the invention Mixing as well as the maintenance and constant renewal of this mixing of the gaseous pollutant with the sorbent during their residence time reached in the reaction section. A beneficial side effect is the sound energy at the same time, the reaction path is kept free of contamination because through the sound energy prevents accumulation on the walls of the reaction zone will. Such a cleaning effect is radiated by a sounder Sound energy is already used in connection with cleaning heating surfaces Boilers known.

The device according to the invention also has the Advantage of structural simplicity and is also suitable for retrofitting conventional devices, because the sounder can be retrofitted without much effort can be built into existing reaction lines.

According to a further concept of the invention, the reaction path can be provided with sound-guiding surfaces. It is true that with the sound frequencies in question normally the volume of the reaction path without such sound-guiding surfaces sufficiently evenly flooded by the sound waves, but it can turn out to be prove advantageous to additionally provide such sound-guiding surfaces to the Sound pressure distribution within the volume of the reaction path of a desired Approximate distribution, for example in order to be spatial, i.e. in all directions to further promote the ongoing propagation of pressure waves.

For effective irradiation of the sound energy and also in From a constructive point of view, it proves to be favorable that the reaction path is essentially U-shaped with U-legs extending vertically upwards from the U-web is, one of which is supplied with the polluted exhaust gas at the free end and one of which is other at the free end, the separating device is connected, and that the sounder is arranged in the area of the U-web.

One of the usual devices can be used as a sounder, as they do for the sound radiation for cleaning the heating surfaces of a boiler are already known. In this context it can be provided that the sounder a transducer excited by a fan and a Transducer from extending resonance tube, the transducer facing away from the open End communicates with the interior of the reaction section.

Further features, details and advantages of the invention result can be derived from the following description and the drawing, with respect to an essential to the invention Disclosure of all details not mentioned in the text are expressly indicated will. 1 shows a diagram of the sequence of a method for dry or quasi-dry separation of gaseous pollutants from exhaust gases, in particular Flue gases, and FIG. 2 shows a schematic representation of a device for implementation of the method illustrated in FIG. 1.

According to a sequence of a method shown schematically in FIG. 1 for the dry or quasi-dry separation of gaseous pollutants from exhaust gases arise, for example, in a combustion system or in a process-related one Appendix 1 Flue gases that contain gaseous pollutants such as HF, HC1, SO2, SO, and the like. The exhaust gases from the furnace 1 flow through a block 2 schematically shown reaction path in which they are with a sorption of the in the exhaust gas contained gaseous pollutants serving sorbents are mixed. This takes place in the reaction section 2 on a dry or quasi-dry route adsorptive attachment and then the absorptive binding of the pollutants instead of the sorbent.

As is known, suitable sorbents are, for example, calcareous ones Substances, magnesium-containing substances, ammonia- or ammonia-releasing substances and the like.

In single-stage systems, the sorbents are at the beginning of the reaction section, for multi-stage systems at several points along the reaction path entered into the flue gas flow and with this, for example, by using static Gas mixers, vortex sink reactors or the spraying of aqueous solutions for mixing by evaporation, mixed. The reaction section through which the exhaust gases flow 2 is followed by a separating device shown schematically by a block 3, in which the pollutant-laden sorbent from the in the reaction section 2 exhaust gases cleaned by the sorption is separated, whereby the blocks 2 and 3 continuously flowing exhaust gases finally the separating device 3, as indicated schematically by an arrow 5, left in purified form. the Separation device 3 can be formed, for example, by a dedusting system. In this, the separation can take place, for example, by means of electrostatic precipitators or fabric filters take place. When using fabric filters, the separating device 3 adsorptive and absorptive post-reactions still take place.

To achieve a high degree of separation and / or an economical one It is necessary to have a sorbent in the reaction section 2 as much as possible bring about intensive mixing between the exhaust gases and the sorbent. For this purpose, as indicated schematically in Fig. 1 by an arrow 4, Sound energy radiated into the reaction section 2 to cover the entire volume of the To apply pressure waves to the reaction section. The mixing-promoting effect the radiated sound energy is likely to cause a difference in speed based between the particles of the sorbent and the exhaust gas. Hence there is an expedient way of conducting the process, the sound frequency of the adjust the radiated sound energy in such a way that between the pollutant molecules and achieving a maximum velocity differential for the sorbent particles will.

Alternatively, however, there is also a periodic tuning of the sound frequency over a certain, appropriately chosen frequency range into consideration. The period duration this tuning is in the order of magnitude of the residence time of the mixture from exhaust gases and sorbents in the reaction zone 2, so in the order of magnitude the time available for the sorption process, or less. Alternatively, it is also possible to superimpose several sound frequencies to radiate.

If the other process parameters allow, it turns out the infrasound range for the frequency of the radiated sound energy as special advantageous. On the one hand, this choice of frequency makes the Environment avoided. On the other hand, it is also particularly important that in the infrasound range the degree of reflection is particularly high, so that even with reaction paths of any shape a sound exposure of the entire volume of the reaction section is guaranteed and the formation of dead zones is avoided.

In a device shown schematically in Fig. 2 for implementation of the process is that between the combustion or process plant 1 and the separating device 3 built-in reaction section 2 essentially U-shaped formed, the two U-legs 6.7 from the one with respect to the separating device 3 U-web 8 located below extend vertically upwards. The upper free end 9 of the U-leg 6 is connected to the exhaust gas outlet of the combustion or process engineering Attachment 1 connected, while the upper free end 10 of the other U-leg 7 is connected to the input of the separating device 3. Albeit along the reaction path 2 generally several sound generators 4 depending on their dimensions, volume can be provided in the following an embodiment with only one.

Sounder 4 dealt with.

The sound generator 4, which is used for irradiating sound energy, is in the area of the U-web 8 arranged.

This arrangement makes the entire volume of the reaction zone 2 acted upon by the transmitted pressure waves. If it proves necessary, can also be used in the reaction path 2 sound-guiding surfaces (not shown) be arranged to possibly by reflection of the radiated sound energy to apply sound energy to any anechoic rooms that occur.

For the sound generator 4, for example, come for the purposes of Heating surface cleaning of firing systems known sounders into consideration, see above that their training is not shown in detail. Such a sounder 4 has, for example, a sound head excited by a fan, from which from a resonance pipe extends. The open end of the transducer facing away from the transducer The resonance tube is mostly funnel-shaped. The coupling of the sounder 4 to the volume of the reaction zone 2 can be done in such a way that the free The end of the resonance tube either protrudes slightly into the reaction section 2 or is flush with an opening in the wall of the reaction section 2.

LIST OF REFERENCE NUMERALS Method and device for dry or quasi-dry Separation of gaseous pollutants from exhaust gases, especially flue gases 1 combustion system 2 reaction section 3 separating device 4 arrow, sounder 5 arrow 6,7 U-leg 8 U-web 9 free end 10 free end

Claims (10)

Claims 1. A method for dry or quasi-dry deposition gaseous pollutants from exhaust gases, in particular flue gases, in which the exhaust gas mixed with a sorbent serving to sorb the gaseous pollutants which is separated from the exhaust gas after the sorption of the pollutant, thereby characterized in that sound energy is radiated into the mixture of exhaust gas and sorbent will. 2. The method according to claim 1, characterized in that the sound frequency on achieving a maximum speed difference between the pollutant molecules and matched to the sorbent particles. 3. The method according to claim 1 or 2, characterized in that the sound frequency with an order of magnitude of the sorption time or less lying period duration tuned periodically over a certain frequency range will. 4. The method according to any one of claims 1 to 3, characterized in that that a superposition of several sound frequencies is radiated. 5. The method according to any one of claims 1 to 4, characterized in that that the frequency of the radiated sound energy is in the infrasound range. A 6. Device for performing the method according to one of the claims 1 to 5, with a thorough mixing through which the exhaust gas and the sorbent flow of the exhaust gas and the sorbent for a sorption serving reaction path (2) and one connected to the output of the reaction path (2) Separation device (3) for separating the pollutant-laden sorbent, thereby characterized in that the reaction path (2) has a volume thereof with sound energy having irradiating sound generator (4). 7. Apparatus according to claim 6, characterized in that the reaction path (2) is provided with sound-guiding surfaces. 8. Apparatus according to claim 6 or 7, characterized in that the reaction section (2) is essentially U-shaped and perpendicular to the U-web (8) upwardly extending U-legs (6,7) is formed, one of which (6) on the free At the end (9) the polluted exhaust gas is supplied and at the other end (7) at the free End (10) the separating device (3) is connected, and that the sounder (4) is arranged in the area of the U-web (8). 9. Device according to one of claims 6 to 8, characterized in that that the sound generator (4) has a sound head excited by a fan and a itself has the resonance tube extending from the transducer, its remote from the transducer open end communicates with the interior of the reaction section (2). 10. Device according to one of claims 6 to 9, characterized in that that the reaction section (2) is provided with several sounders (4).