SK304690A3 - Process and device for wet purification of gases especially of flue gases - Google Patents

Abstract

The invention provides a process and a device for wet purification of gases, in particular of flue gases, in which a gas is brought into contact with a foam-forming purifying liquid by means of turbulence formation. In order to reduce the energy consumption and improve the foam formation, it is proposed to feed the gas to be purified into a primary reaction chamber which has a passage cross section which varies in the flow direction and is laterally bounded in that direction by at least one movable wall having an irregular surface which is wetted by the purifying liquid. The wall can be provided with openings so that a secondary reaction chamber is formed on the side of the wall remote from the primary reaction chamber.

Description

Technical field

The present invention relates to a process for the wet scrubbing of gases, in particular flue gases, and to an apparatus for carrying out the process.

BACKGROUND OF THE INVENTION

A method and apparatus of this kind are known from European patent application 86 109 070.8. In this method, the purified gas is introduced under pressure into a foam-forming cleaning liquid. A turbulent, ring-shaped device with a underside, which is provided with a plurality of grooves or in the form of vertical corrugated sheets, generates a foam whose bubbles bind to each other the particles to be removed from the gas to be cleaned. A drawback of this method and of the corresponding device is that the cleaned gas must be pressed under the surface of the scrubbing liquid in order to achieve intensive contact with the scrubbing liquid and foam formation. It is also a drawback that only a limited formation of foam can be achieved in this way with regard to both the time and surface contact of the gas with the cleaning liquid.

It is therefore an object of the present invention to improve the method and apparatus of the aforementioned type with regard to the energy and foam costs required.

According to the invention, this object is achieved by the features set out in the characterizing part of points 1 to 7.

In the proposed type of purification, intensive contact of the gas to be cleaned with the cleaning liquid is achieved by the fact that the varying cross-sections of the transfer space result in a pulsating flow in the reaction space so that turbulence occurs. with cleaning liquid. This results in a particularly large filtration effect, since the bubbles formed form a large filtration surface. In doing so, it is not only the formation of individual bubbles, but rather that they can enclose again more smaller bubbles.

The surface of the limiting wall preferably has openings so that an additional reaction space is formed. There are similar ratios in this secondary reaction space as in the primary reaction space.

Advantageously, the constructed apparatus for carrying out the purification method has two free rollers limiting the lateral, primary reaction space in the flow direction, which are driven by a gas flow in the opposite sense. The irregular surface of these rollers is formed by blade-like inwardly projecting projections which are pushed from the surface of the rollers inwardly, so that at the same time holes are formed through which the secondary space is created. The secondary space is bounded laterally by one standing return pipe, which is arranged axially parallel in the corresponding freewheel cylinder. A pressure-equalizing flap is provided on each return pipe and can rest on the surface of the liquid reader. The surface of the scrubbing liquid limits the gas flow in the flow direction so that portions of the primary and secondary gas streams are absorbed by the scrubbing liquid. A further portion of these streams passes through the pressure equalization flap and cylinder openings into the cleaning chamber surrounding the cylinders. The foam formed can be removed and decomposed from the cleaning chamber. The resulting liquid is fed back to the cleaning liquid collection tank and the cleaned gas exits. The sludge formed in the collecting tank for the cleaning liquid is drained and can be dried using uncleaned gas as long as the gas has a sufficient temperature. Part of this sludge is returned for further purification to the secondary reaction space.

but can also primary and

BRIEF DESCRIPTION OF THE DRAWINGS

The invention is further explained by the examples shown in FIG. 1 to 4.

Fig. 1 shows a schematic representation of a gas scrubber. FIG. 8 shows a schematic representation of the purification chamber and the primary and secondary reaction compartments arranged therein.

Fig. 3 shows a side view of a

Fig. 4 is a top view showing the bearing and cylinder cover of FIG. 8.

EXAMPLES OF THE INVENTION

The gas purification device shown in FIG. 1 has a cleaning chamber 10, which is shown in detail in FIG. 1. The purge chamber 10 is fed with the gas to be cleaned through the gas inlet tube 18. This gas enters the primary reaction chamber 11a and the secondary reaction chamber 11b. Both spaces are laterally delimited in the direction of flow by free rollers.

15. which are driven by the gas supplied in the opposite sense. The cleaning chamber 10 has a tank 15 of cleaning fluid which forms a foam downwards. The foam, the formation of which will be described in detail later, is passed through the foam discharge pipe 16 to a blow-down device 83, which may consist, for example, of a radial blower device driven by a motor 88. of the cleaning liquid while the cleaned gas is discharged through the outlet pipe SS. The cleaning liquid 18 is also fed to the collecting tank 18 via a flow pipe 17 from the tank 15. The cleaning fluid is also conveyed to the collecting tank. The sludge deposited in the collecting tank 18 is fed wholly or partially through the outlet tube 80 and the other outlet tube 86 to the slurry collection tank 89. As shown, a portion of the sludge can be returned to the gas inlet pipe 12 via the pre-drip pipe 19.

The drive motor 88 also drives the blower wheel 84, which sucks the gas to be cleaned from the heat exchanger assembly 87. A heat exchanger assembly 27, a housing 30 in which a ring stands downwardly. collecting tank 89 for sludge Above it is on the grate 38 another sludge collection tank. Both tanks 82 are heated with clean gas coming from the boiler 34 and entering the housing 30 to dry the sludge. The housing 30 may further have additional cooling tubes 36 for supplying the boiler 35 with hot water.

The replacement tank Si, which is located in the pumping and regulating assembly 88, comprising the foam decomposition device 83, the engine 88, the blower 84, and the metering device, comprises a cleaning fluid that is fed to the cleaning process when the cleaning fluid is consumed.

As shown in FIG. 8, the purified gas passes through the inlet tube 18 into the primary and secondary reaction compartments 11a and 11b, respectively. The pressure states, flow velocities and temperature states prevailing in the reaction spaces and the adjacent regions are shown in the following table:

Po = const. With increasing + the T _o = decreasing Pi> Po Si <S ₀ Those <It Pa <Pi In> Si Ta <Ti Pa <pa In> the T3 <Ta P <> Pa and Pa S4 <Sa a the T4 <T3 and Ta Ps> Pa Ss <Sa Ts <T4 Ps <ps Ss> Ss Te <Ts Ρ7> Ρβ S7 <S ₆ Τ7 <Τβ

Cross sections

and < Ai Ai > and Aa < Ai and < Aa A4 > Aa, Aa and > A4 Ae < and And? > Ae

The primary reaction space 11a in the present example is delimited laterally in the flow direction by the two cylinders 15, which are driven by a gas flow in the opposite direction. The rollers 15 have inwardly projecting blade-like projections 59, through which openings 38 are formed. Through these openings, a gas flow can be introduced into the rollers 15, thereby creating a secondary reaction space 11b. The reaction space 11b is laterally delimited by the return pipes 13 which are arranged in the cylinders 13 parallel to their axis. Each return pipe 14 has a pressure-swinging pressure relief flap 37 that protrudes downwardly and, together with the cleaning fluid, seals the primary reaction chamber 11a and the secondary reaction chamber 11b. In operation, the pressure equalization flap 37 of the gas and the foam formed is conveniently raised above the surface of the cleaning liquid.

The two rollers 13 are immersed in the cleaning liquid, so that their surface is wetted both outside and inside with the cleaning liquid. A cleaning liquid is also present on the return pipes 14. In this way, the supply of scrubbing liquid to the reaction spaces leads to intensive contact of the cleaned gas and scrubbing liquid and a large amount of turbulence, thereby favorably affecting foam formation. The foam bound particles reach not only into the cleaning chamber 10 from where they are fed to the foam decomposition device, but also directly to the cleaning liquid in the tank 15 and from there to the collection tank 18.

Fig. Figures 3 and 4 show that the rollers 13 housed in the pedestal 40 are partially surrounded by a cover 41 which encloses the primary reaction space 11a and the secondary reaction space 11b.

Claims (17)

PATENT CLAIMS Process for the purification of gases, in particular flue gases, in wet form, in which the gas is brought into contact with a foaming scrubbing liquid by means of turbulence, characterized in that the gas is fed to a primary reaction space which has varying cross-sectional passages in the flow direction The flow is laterally delimited by at least one movable wall having a non-uniform and wetted surface wetted by the cleaning liquid. Method according to claim 1, characterized in that the wall has openings through which a secondary reaction space is formed on the side of the wall facing away from the primary reaction space. Method according to claim 1 or 8, characterized in that the primary reaction space and the secondary reaction space are limited by another wall formed by the cleaning liquid. Method according to one of Claims 1 to 3, characterized in that the foam formed is decomposed by contact with the cleaning liquid, the resulting liquid is collected and the cleaned gas is discharged. The process of claim 4, wherein a portion of the collected liquid is returned to the primary reaction space. Method according to claim 4 or 5, characterized in that another part of the collected liquid is dried with uncleaned gas. Apparatus for carrying out the method according to any one of claims 1 to 6, comprising a scrubbing chamber with a gas inlet pipe and a foam inlet pipe, a turbulence generating device for contacting the gas with the scrubbing liquid and a scrubbing liquid tank, characterized in that it has a primary reaction space (11a) into which gas is provided which has varying cross sections in the flow direction and which is laterally bounded in the flow direction by at least one idle running cylinder (13) having an uneven surface and immersed in a cleaning liquid whose surface delimits the primary reaction space (11a) in the flow direction. Apparatus according to claim 7, characterized in that the surface of the cylinder (13) has gas passage openings (38) through which a secondary reaction space (11b) is formed on the side facing away from the primary reaction space (11a). Device according to claim 8, characterized in that the openings (38) are formed by inwardly projecting paddle-like projections (39). Device according to claim 8, characterized in that the projections (39) are rectangular. Apparatus according to one of claims 8 to 10, characterized in that the secondary reaction space (11b) is limited in the flow direction by a lateral standing return pipe (14) which is arranged in the cylinder (13) parallel to the axis. Apparatus according to claim 11, characterized in that the secondary reaction chamber (11b) is laterally delimited by a pressure equalization flap (37) mounted on the return pipe (14) and sealing the primary reaction chamber (11a) at rest. and secondary reaction Apparatus according to characterized by oppositely arranged delimiting lateral primary space (11b), One of claims 7 to 18, characterized in that the two mutually free rollers (13) have a reaction space (11a). Apparatus according to claim 15, characterized in that a return pipe (14) with a pressure equalizing flap (37) is provided in each cylinder (13). Device according to one of Claims 7 to 14, characterized in that it has a flow pipe (17) which extends from the cleaning liquid tank (15) to the cleaning liquid collecting tank. Device according to claim 15, characterized in that it has an outlet pipe (80) connected to the collecting tank (18). Apparatus according to claim 16, characterized in that the outlet pipe (80) leads to a sludge collection tank (89). Device according to claim 16 or 17, characterized in that the outlet pipe (80) is guided through the pre-drip pipe (19) into the gas inlet pipe (18). Device according to one of Claims 1 to 18, characterized in that the foam guided through the foam outlet pipe (16) is decomposed by means of a foam decomposition device. The device according to claim 19, characterized in that the liquid resulting from the decomposition of the foam is returned via the return pipe (SI) to the cleaning liquid tank (18). ARE YOU. Apparatus according to claim 19, characterized in that the foam spreading device (S3) is driven by a motor (38) which simultaneously drives the suction blower (34) and the uncleaned gas. SS. Apparatus according to claim 17, characterized in that the sludge collection tank (89) is arranged in a heat exchanger to which contaminated gas is supplied.