DE1619879B2 - DEVICE FOR REMOVING SULFUR OXIDES FROM EXHAUST GASES - Google Patents

Description

3 4

Fig. 3 is a cross section along the line III-III in have the same design and are with respect to the

Fig. 1, position of the slots arranged in the same position

F i g. 4 a schematic representation of an annet. Carbon dioxide (CO.,) Is used as the desorption gas

their embodiment of the invention or nitrogen (N.,) used. An inlet pipe 45

Device, 5 and an outlet pipe 46 (Fig. 1) for the desorption

F i g. 5 is a cross-section along the line V-V in gas at each end on the outer sides

F i g. 4, the gas passage changeover elements 6 and 7 for the purpose

F i g. 6 shows a cross section along the line VI-VI in connection with the slots 42 (FIG. 3) in FIG

F i g. 4 and corresponding changeover elements attached. the

7a and 7b enlarged representations of an io changeover element 6 and 7 have support pins 47 and

Part of Fig. 4. 48 (Fig. 1), which are fixed with their inside to-

In FIG. 1 carries a cylindrical body 1 a coherent and run in bearings 43 and 44 that

Gas inlet tube 2 in communication with its bottom in corresponding support blocks 49 and 50 on both

end and a gas outlet pipe 3 connected to ends of the hollow cylindrical member 9-

its upper end. At the neck parts 5 and 4 of the 15 are brought. It follows that the conversion

The gas inlet pipe 2 and the gas outlet pipe 3 are elements 6 and 7 of the hollow cylindrical part 9

Gas passage changeover elements or means to be held.

switch 7 and 6 of the gases provided. The interior The changeover elements 6 and 7 are both on theirs the body 1 is by means of partitions 8 evenly circumference with external teeth for engaging in corresponding divided into twelve sector-shaped parts, as shown in FIG. 2 20 corresponding gears 51 and 52. The tooth shows and each partition 8 is on both edges wheels 51 and 52 are respectively engaged with Zahnmit the inner wall of the body 1 and the outer wheels 53 and 54, which have groups of cone-wall a hollow cylindrical member 9 (Fig. 1) gears 55 and 56 in driving connection with welded, which extends axially in the body 1, electric motors 57 and 58 are. From this erso that the hollow cylindrical element 9 from the body 25 is that the changeover elements 6 and 7 from the per 1 by means of the partitions 8 (Fig. 2) held corresponding electric motors 57 and 58 operated will. The electric motors 57 and 58 are

As mentioned, the interior of the body 1 is interconnected in twelve by a conductor wire 59 for the elec-

Parts divided (F i g. 2), which are connected from chambers 11 to 22 tric synchronism,

exist; each chamber is further by steel belt- 3 ° between the hollow cylindrical element9

elements 31 and 32 divided into three sub-chambers. and each belt element 32 are inclined deflection

The intermediate sub-chamber 33 (mounted in the following plate 61 in order to ensure that the

denoted as the adsorption bed zone) is with gases and desulphurized gases, as indicated by the arrows

an adsorbent such as B. activated carbon filled. The indicated zigzags flow.

Steel belts 31 and 32 are each with a cor- 35 When operating the device of the above erosion-resistant Fabric or corrosion-resistant construction is written when the gas-permeable paint covered and have a number of small changeover elements 6 and 7 in the positions Perforations 34 and 35 (Fig. 1). Such Fig. 3 are, the exhaust gas inlet pipe 2 in connection However, openings are in the upper parts 36 and with the chambers 12 to 16 (Fig. 2), so that the 37 of these steel strips 31 and 32 are not formed to 40 exhaust gases into these chambers through the slot 41 the passage of exhaust gases from the adsorption (Fig. 3) are admitted. These five chambers bed zone in the adjoining sub-chambers in each serve as adsorption chambers and in this case Chamber to prevent without them by the Ad- setting the in F i g. 2 designated adsorption zone. sorbents occur in the adsorption bed zone, sulfur dioxide gas is from active coal with what else would happen if an air space adsorbs at a high level of efficiency, if exhaust gases after upper part of the adsorption bed zone as a result of cooling to 100 ° C in the activated carbon adsorption volume reduction the activated carbon bed zone contained therein. On the other hand, because this would result in less sulfur trioxide gas with a high degree of efficiency as a result of the crumbling of the adsorber space occupies. beer when the exhaust gases after cooling to 200 ° C in

The cylindrical body 1 (FIG. 1) is embedded in the activated carbon adsorption bed zone at its top with a plurality of activated carbon 'den, therefore it is by lowering the temperature of the allow 38 in connection with the adsorption bed exhaust gases according to the nature of the individual case zones provided. He also points to his lower- removing sulfur oxide possible, the sulfur side a plurality of activated carbon outlets 39 in oxide to adsorb effectively.

Connection with the adsorption bed zones. The 55 in the position of the gas passage switching element 6

Inlets and outlets 38 and 39 are during the normal (FIG. 1) according to FIG. 3 is a desorption gas input

paint operation of the device closed. outlet pipe 45 (Fig. 1) in connection with the chamber

The gas passage changeover elements 6 and 7 are mern 18 to 22 (F i g. 2), so that the desorption gas

according to FIG. 3 each with an arched slot 41 for entering these chambers through the slot 42 (FIG. 3)

Passage of exhaust gases and an arc slot 42 60 is left. These five chambers serve in this one

for the passage of desorption gas into the interior of the case as desorption chambers, the one shown in FIG

Body 1 provided, both of which represent the arc slot designated desorption zone. The desorp-

41 and the arc slot 42 a central angle tion gas consists of carbon dioxide gas or nitrogen

each having about 150 °. The opposite gas; which is heated to about 400 ° C. By

The ends of these archers 41 and 42 can be exposed to such a desorption gas

on the other hand by a central angle of the sulfur oxides, which are adsorbed by the active carbon

each separated by about 30 °. desorb into the desorption gas.

The two gas passage changeover elements 6 and 7 The chambers 17 and 22 (Fig. 2), which are between

5 6

see the adsorption zone and the desorption zone there washes out adsorbed sulfur oxides, and is

are, are resting chambers, in which none through a drain pipe 82, which with the lower

Exhaust gases and also no desorption gas admitted end of each chamber is connected, discharged,

will. The chambers in the drying zone are all available

The chambers 5, which form the adsorption zone, have a drying gas inlet pipe 85 and a drying gas outlet pipe 84 is connected to the exhaust gas outlet pipe 3 (FIG. 1). A bond through which the exhaust gases, from which the sulfur oxides are removed through the slot 78 in the gas passage switchover, are vented through the slot 41 element 6 'into the chamber in the drying zone (Fig. 3). On the other hand, the drying gas introduced flows through the chambers which represent the desorption zone in ver io-speaking chambers, where it dries the moist active bond with the desorption gas outlet pipe 46, and is passed through the drying gas (FIG. 1), through which the desorption gas, wel- outlet pipe84 contains the desorbed sulfur oxides via the slot78 in the surrounding area, drained via the element T.
Slot 42 (Fig. 3) is left out. The drying gas is expediently the

The electric motors 57 and 58 are used during 15 gases from a gas turbine or a steam boiler of the process of adsorption and desorption. The drying gas outlet pipe 84 is kept inoperative. When the adsorption and with the exhaust gas inlet pipe 2 in connection, so that desorption treatment for a predetermined time the exhaust gases, which were used for drying, has been carried out, one actuates the electric chambers in the adsorption zone to de-motors to thereby the corresponding Gas through 2 ° sulphurisation can be introduced,
lassumstellelemente at an angle of 30 ° as shown in Fig. 7, each has to rotate through the. After rotation of the switching elements, partitions 31 and 32 drilled opening is adjusted to the chamber 11 so that it belongs to the adsorption upwardly widening Abzone, and the chamber 17 is adjusted so that the guide plate 90 in connection with the lower edge it belongs to the desorption zone, while the chamber 25, so that it is prevented that water from the mern 16 and 22 now form the rest zone. In the manner described in the adsorbent bed zone 33 through this opening, each chamber is rotated to allow flow. The opening between the upper edge of each successively to the adsorption zone, desorption zone baffle 90 and the outer walls of the and rest zone to belong, as the switching partitions 31 and 32 is with a screen 91 beelemente6 and 7 rotated. 3 ° covers, as shown in Fig. 7b, in order to

At the points where the changeover elements 6 and 7 occur the activated carbon particles from the adsorption

stand in contact with the corresponding pipes to prevent bed zone 33 (Fig. 4). Instead of this

if sealing means 62 and 63 (Fig. 1) are arranged, the screen screen 91 can also be attached in such a way that

to prevent the gases from escaping there. that it directly covers each opening 35 in such a way that

• According to another embodiment 35 as shown in FIG. 7 a is shown.

of the device according to the invention, which is in the water supply pipes 81 (Fig. 4), respectively

the Fi g. 4 and 5, the inside of a solenoid valve 92 is turned on, and so is

cylindrical body 1 evenly in six sectors, the drainage pipes 82 each have a solenoid

shaped parts divided from the chambers valve 93, the solenoid valves 92 and 93

71 to 76 exist and through partitions 70 to 40 with an electrically conductive wire 94 for electrification are. The gas passage changeover elements 6 'are connected to Irish synchronism.

and 7 'are, as Fig. 6 shows, each with a When operating the device according to this embodiment

Arc slot 77 for the passage of exhaust gases, in the exemplary embodiment the gas passage switchover

cher has a central angle of about 180 °, and elements 6 'and T intermittently at an angle of

an arc slot 78 for the passage of a drying 45 rotated 60 ° further. After the lapse

ming gas, which has a central angle of about a certain period, the changeover

120 °, provided in such a way that the one elements clockwise, as in F i g. 6 shown

Ends of the corresponding slots in the circumference is rotated, whereby the chamber 76 migrates further,

The chamber 73 forms a central angle of about 60 ° from one another in order to belong to the adsorption zone

are separated. The migrated in the manner described 50 in order to wash water desorption

Slits placed allow chambers 71 to belong to zone and chamber 74 to move on,

72 and 73 form an adsorption zone and the chambers to form the drying zone. Belongs to itself 75 and 76 form a drying zone, as in each chamber, one after the other in the working order F i g. 5 is shown. The chamber 74 provides a washing zone for adsorption, water washing and desorption water / desorption zone represents in which water conversion zone and drying zone. The device is running. The adsorption bed zone 33 of each chamber, according to this embodiment, is due to the which is filled with activated carbon is economically advantageous with a fact that water Water supply pipe 81 above the upper limit point of carbon dioxide gas or nitrogen gas as wall of the body 1 in connection. That is used in the ad desorbent and moreover Sorption bed zone 33 admitted water flows through 60 exhaust gases to dry the moist activated carbon Stack of activated charcoal facing down with it being turned.

1 sheet of drawings

Claims (1)

1 2 these columns constantly circulate, with the adsorber Claim: bens ^{after adsorption of} the sulfur oxides during the passage through the adsorption column in the Regenerated apparatus for removing sulfur desorption column and SO ₃ is fed from loading of gas turbines, 5 adsorption column for re-use back-boilers and furnaces exhaust gases emitted back into the oxides such as SO., And. However, in order to achieve the continuous upright position from a cylindrical container, with the removal of sulfur oxides from exhaust gases with the device described below for the interior of the container, the adsorptive dividing walls must constantly circulate accordingly with activating agent. This means that coal-filled adsorbent beds and generally the device must be provided with a drive device and known device details for periodic means, in order to see the repositioning of the chambers, are provided to effect circulation of the adsorbent. In addition, when activated carbon is used as an adsorbent adsorption zone in which the exhaust gases from the activated carbon are adsorbed during the continuous activated carbon, some of the 15 lent circulation are subjected to a breaking load. Chambers in a water washing and desorption zone In order to have the adsorption capacity of the activated carbon, in which the adsorbed exhaust gases can be better utilized and, on the other hand, the desorption by water or other solvents can be washed out of the activated carbon with smaller amounts of water through the activated carbon and can be carried out in the device for some of the chambers in a drying zone 2 ° removal of sulfur oxides, such as SO ₂ and SO ₃ , in which the water-containing activated carbon, after being washed out by gas turbines, boilers and ovens, is exhausted by a heated gas, consisting of a cylindrical container is dried, characterized in that, for the interior of the container, several that the adsorbing beds (33) are arranged in the form of vertically dividing partitions corresponding to active rows, that baffles (61) ² 5 carbon-filled adsorbing beds and generally for generating of a vertical stream in Zick- known devices Details of the periodic zigzagging of the exhaust gases and the heated gas are provided in order to rearrange the chambers in such a way that through the adsorbing beds and some of the chambers are in an adsorption zone, feed pipes (81) for generating a flow in which the exhaust gases are adsorbed by the activated carbon of water or other solvents are 3 °, some of the chambers are in a water washing through the adsorbing beds in the vertical direction and desorption zone in which the adsorbed ones are provided. Waste gases from water or other solvents are washed out by the activated carbon, and some of the chambers are in a drying zone, 35 in which the hydrous activated carbon is dried after being washed out by a heated gas according to the invention the adsorbing beds in the form of verti- To avoid pollution of the air by sulfur kaier rows, baffle plates for generating oxides containing exhaust gases from industrial furnaces to supply a vertical zigzag flow of the To prevent this, devices are used to absorb the exhaust gases and the heated gas through the adsorbent Remove sulfur oxides from the exhaust gases. beds attached and supply pipes for generation For example, from the German patent a stream of water or other solution 377 520 a device is known, which consists of means through the adsorbent beds in a vertical direction there is a cylindrical container, being provided for the device. Inside the container several dividing separators 45 This solution enables the washing out of walls correspondingly filled with activated carbon adsorbent sulfuric acid from the activated carbon with a beer bed and the generally known amount of water, as the activated charcoal beds with Details on the periodic rearrangement of the chambers - more considerable in vertical dimensions than in horimern are provided in such a way that some of the zontal direction are formed and the washing chambers are in an adsorption zone in which the 50 water flows vertically through the activated carbon beds, Exhaust gases are adsorbed by the activated carbon, whereby it is in prolonged contact with the activated carbon some of the chambers are kept in a washing machine and the recovery of a 30 to 40 desorption zone are in which the adsorbed percent sulfuric acid allows, Also take care Waste gases through water or other solvents use the baffles to keep the waste gases out and about the activated charcoal are washed out, and 55 heated gases in a generally vertical flow zig a few the chambers are in a drying zone, perform zigzag movements through the adsorbent beds of the water-containing activated carbon after the training, which allows a more complete enforcement of the washing is dried by a heated gas. Activated carbon and thus better capacity utilization In this device, the adsorbent beds are guaranteed. For processing certain exhaust gas with Activated charcoal a considerable expansion in 60 amounts is therefore less activated charcoal and less horizontal direction and require the Desor- base area. the adsorbed sulfur oxides ratio- The device is shown in the drawing moderately large amounts of water. vividly. It shows A device has also already been described, FIG. 1 is a schematic representation of an Ausin which is an adsorption column and an exemplary embodiment of the device desorption column according to the invention in a separate arrangement in the middle, are connected to one another and an adsorbent, Fig. 2 is a cross section along the line TT-TI in such as activated carbon or pitch coke particles, through Fig. 1.