NL8402481A - WASHING DEVICE AND METHOD WORKING WITH ONE OR MORE ROTATING DISCS. - Google Patents

Description

P & c W 6197-1 Ned.M / EvF ** »*

Short designation: Washing apparatus and method operated with one or more rotating discs.

The invention relates to an apparatus and method for removing gaseous and / or granular matter from a gas stream, and more in particular an apparatus and method for generating a large-volume liquid spray mist from a liquid mass, such that the liquid, which forms the spray mist, comes in quite intimate contact with a gaseous medium, which passes above the liquid mass. Spray mist forming devices of the type described herein are useful as a means of extracting solid particles or soluble components from an industrial exhaust gas stream or as a means of cooling a gaseous medium by evaporation due to contact of the liquid spray mist with the gaseous medium.

Known devices, such as those described in U.S. Patent No. 1,462,363, generate a liquid spray mist by means of large-area cylinders rotatably disposed about a central axis and supported over a liquid mass such that the top surface of the the liquid is only slightly touched and almost touches the lower part of the surfaces of the cylinders. When the rotating cylinders touch the surface of the liquid, it adheres. a thin liquid film thereto and, as the cylinders rotate, the centrifugal force throws the liquid film from the cylinder surfaces as a fine mist, which is distributed above the cylinders. In U.S. Patent 1,462,363, the cylinder is very slightly immersed in the liquid because the power required to rotate the cylinder then increases very sharply and the spray mist effect is largely destroyed even if a small portion of the cylinder is below the level of the liquid surface. The unsuitability of certain discs is discussed in U.S. Patent 1,462,363 because they cause a significant fluid flow in the direction of movement of the edge of the disc, which strikes the liquid due to the friction of the water on the sides of the discs . Other known devices, for example, those disclosed in U.S. Patent 1,361,607, use rotary, inclined disks or impellers to generate a liquid spray mist above a liquid mass, but they are similarly limited to a very low degree of villager in the liquid mass from which the spray mist is formed.

8402481 ï t »f - 2 -

The circumferential surface (edges) of the discs in U.S. Patent 1,361,607 generally includes specially constructed edges.

The foregoing limitations are significant in that only 5 limited fluid volumes of chins are picked up by the cylinders or impellers, and small increases or decreases in fluid level or turbulence at the fluid surface may result in impure contact between the rotating body and fluid mass, thereby reducing and irregular spray mist is generated. As a result, it has become generally accepted practice in the relevant techniques to remove gaseous and / or granular matter from the gas streams by various other means.

In most conventional scrubbers, the intimate gas-liquid contact necessitates the use of punches for atomizing or spraying a wash liquid into a vessel through which the gas to be cleaned is passed. Other gas scrubbers consume vertically stacked perforated trays on which the scrubbing liquid is circulated while the propellant gas driven through the perforations or stacked columns is washed by passing scrubbing liquid through the perforations. Other devices use sprinkling pipes to drive the gas to be cleaned through a puddle-cleaning liquid. Although spray nozzles are quite effective, they are subject to clogging by granular matter, which can form. contained in the liquid, which limits their ability to expose the liquid to the gaseous medium over and over again. In addition, such devices cannot be used in situations where it is desired to direct the liquid and gas in countercurrent flow, when it is necessary, for example, to efficiently recover components removed from a gas stream. It is also disadvantageous that the use of most devices depends on pumps, spray nozzles, perforated trays, column packings, sprinklers and the various installations required to operate these elements, due to the significant capital costs and consequent business fs and maintenance costs.

It is a primary object of the present invention to provide an improved device and method for removing gaseous and / or granular matter from a gas stream.

Another object of the present invention is to provide an improved apparatus and method for generating a large volume liquid spray mist above a liquid reservoir such that the liquid forming the spray mist is substantially intimate. comes into contact with a gaseous medium which is passed over the liquid.

Another object of the present invention is to provide an apparatus and method for effecting intimate contact between gases and liquids in the form of a spray mist, the apparatus acting independently of the level of a liquid mass from which the spray mist is is excited.

A further object of the present invention is to provide an improved device and method for scrubbing gases with a liquid spray wafer, wherein the flow of the liquid from which the spray wafer is generated is in a direction opposite to the flow direction of the liquid. wash gas.

Another object of the present invention is to provide an improved device and method for washing gases, wherein the device is relatively simple in construction, reliable in operation, and requires a minimum of maintenance and repair costs.

The present invention achieves the above objectives by providing a device containing a housing, in the lower part of which there is a liquid mass and a gas-liquid contact space in the upper part thereof. The bottom portion of the housing includes a fluid inlet and outlet, and similarly, the top portion includes a gas inlet and outlet.

In a first aspect of the present invention, it provides an improved device for effecting an intense contact between gases and liquids containing a) elongated, horizontally disposed housing having a bottom portion for storing a fluid and a top portion, which defines a gas-liquid contact space; means for introducing a gaseous medium into the gaseous liquid contact space of the housing and means enabling the gaseous medium to exit the housing; c) a plurality of disk-shaped impellers capable of forming a liquid spray mist in the gas-liquid contact space, the impellers being mounted on a number of rotatable shafts arranged axially 8402481 r-4. are supported in the housing and above the liquid such that a lower part of the impellers is substantially immersed in the liquid; and d) means for rotating the shafts.

In general, the present invention improves operating washing efficiency by using rotary disk-shaped impellers with a side-face configuration capable of forming a liquid mist in the gas-liquid contact space, the disk-shaped impellers being mounted on a number of rotatable shafts arranged axially in a housing and supported above a wash liquid such that a lower portion of the disk-shaped impellers is substantially immersed in the wash liquid. In certain embodiments, the rotary disk-shaped impellers have sheet-like liquid-ejection protrusions that have accumulated on each of their 15 side faces, which impellers are mounted on a number of parallel rotating shafts supported above a liquid mass such that the lower portions of the impellers are substantially immersed in the liquid. Since the impellers are substantially immersed in the liquid, the device operates independently of the level of the liquid mass. In addition, the immediately adjacent shafts and thus the impellers mounted thereon are preferably arranged for counter-rotation. When the shafts are rotated, the side projections of the impellers have been shown to pick up substantial liquid films and to throw or propel them upward into the gas-liquid contact space as a relatively fine, regularly dispersed mist above the impellers.

The liquid mass contained in the reservoir or in the lower part of the housing can be divided into a number of smaller compartments by means of partitions arranged between the end walls of the housing. In addition, the fluid inlet and outlet can be arranged such that the fluid inlet is located at the opposite end of the housing from the gas inlet and the fluid outlet is similarly located at the opposite end of the housing from the gas outlet, with the result that the liquid flow will be opposite to the gas flow to improve the efficiency of the device.

Additional components, such as agitators to keep the fluid in the reservoir moving, and air sprinklers for oxidizing components in the fluid mass, are also provided.

In another aspect of the present invention, it provides an improved method of washing a gas stream containing impurities which are removable by a liquid, characterized in that a) a gaseous medium containing the impurities is introduced to the one end of a gas-liquid contact space located above a liquid reservoir? b) sprays the liquid in the gas-liquid contact space; C) the gaseous medium containing the impurities passes through the liquid spray mist into the gas liquid contact space, thereby producing a depleted gas; d) removes the depleted gas at the other end of the gas-liquid contact space; E) introduces non-contaminated liquid into the reservoir at a point substantially below the point of removal of the pollutant-depleted gas, whereby the liquid spray mist formed in the gas-liquid contact space in or at the point of removal of the. impurity depleted gas, becomes a substantially impurity free liquid spray mist; and f). removes the contaminated liquid from the reservoir at a point substantially below the introduction point of the contaminant-containing gaseous medium.

The present invention overcomes the problems, disadvantages, and limitations of the prior art discussed above by providing an apparatus and method that do not involve the use of spray nozzles or rotary cylinders.

The present invention is effective for generating a liquid spray mist from a liquid mass, minor variations in the liquid level would not adversely affect the effective operation of the device.

The invention will be explained in more detail below with reference to some exemplary embodiments shown in the figures in the accompanying drawing.

Fig. 1 shows a perspective view, partly broken away, of the device according to the present invention;

Fig. 2 shows a cross section taken on line 2-2 in FIG. 1> showing a configuration of impellers mounted 8402481

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- 6 - on two rotatable shafts, the impellers being partially immersed in the liquid; FIG. 3 is a longitudinal sectional view taken along line 3-3 in FIG. 2 illustrating the use of baffles to form liquid storage compartments, oppositely arranged liquid inlet and outlet means and oppositely positioned gas inlet and outlet means for effecting a counterflow between gas and liquid through the device; and FIG. 4 is a sectional view similar to that shown in FIG. 2 showing a configuration of the impellers mounted on Ornamental Rotatable Shafts, which impellers are partially immersed in the liquid.

Pig. 1 of the drawing illustrates the device of the present invention for establishing intimate contact 15 between gases and liquids. The device includes an elongated housing or chamber 10. In the preferred embodiments, the housing or chamber 10 is substantially cylindrical. However, the house or room may also be in the form of various other shapes, shapes and geometric designs, which allow the washing of gases by intensive contact of gases and liquids. In Fig. 1, the housing 10 is arranged horizontally on a plurality of support bodies 11, from which a semicircular section has been removed for receiving and fitting the bottom surface of the cylindrical housing. The washers of the present invention are generally horizontal to provide effective washing of the gases with the liquid spray mist and to provide a substantially horizontal level of the liquid mass into which the impellers are immersed.

Although the device according to the present invention can be constructed from any suitable material, such as metal, plastic or the like, it is important when the device according to the invention is used for "washing" industrial exhaust gas flows that the housing is constructed from an acid and alkali resistant material due to the corrosive nature of the substances with which it comes into contact, for example, alkaline washing solution and acidic components of the gas stream. \

It is useful for a good understanding of the invention to mindfully divide the horizontally disposed housing 10 into a lower portion 12 and an upper portion 13, as indicated in the drawing, 8402481. > * - 7 - by illustrating a horizontal plane that runs through the longitudinal axis of the house. During normal operation of the device, the bottom portion 12 of the housing contains a fluid mass 14, which is maintained at a level such that its top surface 15 is immediately below the imaginary plane. Within the limits described below, the extent to which the liquid surface 15 is below the imaginary plane is not important for the proper generation of the liquid spray mist 16 (not shown in Figure 1) during operation of the device. However, it is preferred that means 10 be provided to maintain the fluid mass 14 at a predetermined level with respect to the impeller shafts, for example, by feeding fluid at a fluid inlet and controlling the flow of fluid at a fluid outlet wherein the inlet 17 and the outlet 18 are mounted in the wall of the lower portion 12 of the housing, eliminating the possibility of improper operation due to insufficient or superfluous amount of liquid. The liquid inlet and liquid outlet means are described in detail in Fig. 3.

As used herein, there are no limits on the portion of the housing occupied by the lower portion (reservoir) containing liquid and the upper portion defining the gas-liquid contact space as long as there is sufficient contact space for effectively washing the gas with the Liquid in the gas-liquid contact space. In most embodiments and in those illustrated in the drawing, the bottom portion for storing the liquid (the reservoir) is located in the approximately bottom half of the housing, and the top portion is the gas-liquid contact space defines itself in the approximate upper half of the house. However, the top and bottom sections of 30 other washers can be divided as considered desirable, for example, 60 * for the top section and 40% for the bottom section, or 40% for the top section and 60% for the bottom section, or 70% for the top section and 30% for the bottom section, and such divisions.

The upper part of the housing is provided with conventional means for introducing the gaseous medium to be washed in the gas-liquid contact space and means for the washed gaseous medium to allow the gas-liquid contact to be contacted 8402481 ♦ · · * · - 8 - left as illustrated in fig. 3 and discussed in more detail below »

In Fig. 1, two rotatable shafts 23 are provided with a number of disk-shaped impellers 24 with projections 25, which extend outwardly from the side surfaces of the disk-shaped impellers 24, placed longitudinally in the elongated housing 10. The disk-shaped impellers are immersed in the liquid 14 in the lower part 12 of the housing, so that rotation of the impellers ejects a mist of the liquid into the upper part of the housing, ie, in the gas-liquid contact space, 10 in the area above the impellers. The shafts 23 are mounted axially by conventional means in the housing a predetermined distance above the liquid mass, such that the lower halves of the impellers are substantially immersed in the liquid mass.

The impeller means 22 includes a plurality of rotary shafts 23, 15 which support a plurality of disk-shaped impellers 24 with blade-like projections 25 extending outwardly from their side surfaces. The impellers: 24 are serially attached to each of the rotary shafts 23.

The rotary shafts 23 are supported above the liquid mass 14 such that the shafts are parallel to the longitudinal axis of the housing 10 and such that the lower half of the impellers 24 are substantially immersed in the liquid. Rotational motion is imparted to the shafts 23 by a power source located externally of the housing 10, such as a motor as shown in Fig. 3, or the like, forcing the leaf-shaped projections 25 to eject liquid as a spray mist upwards. in the gas-liquid contact space 13 in the housing 10.

The spray lever 16 is illustrated in Figures 2, 3 and 4.

As intended herein, the disc-shaped impellers are "substantially immersed" in the liquid such that a substantial portion of the protrusions 25 extend into the fluid during rotation of the shafts 23. Obviously, a portion of the disc-shaped impeller must extend into the gas-liquid contact space to drive or discharge the liquid into the top portion of the housing, and for example, when 50% of the disk-shaped impeller is immersed ± s in liquid, 50% of the disk-shaped impeller extends in the gas-liquid contact space.

As shown in Fig. 2, the substantial immersion of the lower half of the impellers 24 into the fluid mass 14 will allow the leaf-shaped protrusions 25 to discharge fluid upward into the gas-liquid contact space 13, where it liquid surface 15 is located below the rotary shaft 23 and above the lower peripheral edge of the impellers 34.

The shape on the side faces of the disk-shaped impeller 5 may be in the form of any suitable geometric protrusion or design that will form a liquid spray if the impeller is substantially dipped and rotated in the liquid. Leaf-shaped protrusions 25 on the side surfaces of the discs or disc-shaped impellers 24 are preferred embodiments in the washers of the present invention. The protrusion can be mounted on one side of the disc or on both side axes of the disc.

Although any number of disk-shaped impellers 24 can be mounted on any rotary shaft 23, it is preferred that the impellers be aligned parallel to each other to provide a more uniform spray 16 in the gas-liquid contact space 13. Furthermore, it is preferred that each rotary shaft 23 is forced to counter-rotate with respect to the adjacent shafts and at least four such shafts may be provided. Such an arrangement is desirable in that it will cause the greatest overlap of spray mist generated by the individual impellers 24.

Increasing or decreasing the number of impellers 24 on each shaft 23 causes a proportional increase or decrease in the volume of the generated spray mist 16. Thus, the optimum gas-liquid contact can be easily obtained by the number of impellers 24 on the rotating shafts 23 to change. In addition, the properties of the spray mist 16 can be changed for different uses of the invention. For example, the size of the liquid droplets containing the spray nebula and the angle of the spray nebula can be changed by providing impellers 24 of different sizes, changing the design of the side projections 25 at the impellers, or increase or decrease the rotational speed of the shafts 23.

The liquid level can be maintained at any desired level, if desired, by conventional means, such as by pumping and overflow means. Fig. 3 illustrates a preferred embodiment of the present invention for supplying and removing fluid from the reservoir by fluid inlet means 17 and fluid outlet means 18. The water mass 14 can be maintained at a predetermined level with respect to the shafts of the impellers by fluid 8402481 - 10 - at the fluid inlet 17 and by controlling the fluid flow from the reservoir or the fluid mass 14 through the fluid outlet 18. Thus, means may be provided for maintaining the fluid at a predetermined level relative to the shafts of the impellers, ie such that the fluid level is maintained an even distance from the shafts 23. Generally, the in the fluid inlet disposed in the lower portion of the housing means for introducing fresh fluid into the housing, and the fluid outlet disposed in the lower portion of the housing also provides a means 10 for removing spent fluid from the housing. In preferred embodiments, the fluid inlet 17 is substantially opposite the fluid outlet 18.

Pig. 3 also illustrates a means for introducing the gaseous medium to be washed into the gas-liquid contact space and means for enabling the gaseous medium to leave the housing 10. The gaseous medium enters the housing 10 through the conduit 30 and exits the housing 10 through the conduit 32. The flow of gas into the casing 10 is illustrated by arrows 34. The gas entering the conduit 30 flowing in the direction of the arrows 34, is washed 20 by the liquid 16 in the form of a mist or mist, in the upper part 13 of the housing 10. The washed gas then leaves the housing 10 via the conduit 32. and can be directed to a ventilation means , a chimney, or the like (not shown).

In many instances, it is desirable to flow the gaseous medium and the liquid 14 in countercurrent during operation of the device, for example, when removing soluble components from an industrial exhaust gas stream. Such a counterflow makes it possible to fill the liquid mass 14 to the maximum with constituents removed from the gaseous medium and is therefore particularly useful when recovery of such constituents is important.

To obtain counterflow in preferred embodiments of the present invention, a fluid inlet is placed in the lower portion of the housing below the means enabling the gaseous medium to exit the housing, and a fluid outlet 35 is fitted opposite the inlet of the housing. housing below the means for introducing the gaseous medium into the housing such that the gaseous medium and the liquid flow through the housing in opposite directions.

Stated another way, the fluid inlet is placed in the bottom portion 8402481 * y ♦ - 11 - of the housing near the means to enable the gaseous medium to exit the housing, while the fluid outlet is located in the bottom portion of the housing near the means for introducing the gaseous medium into the gas-liquid contact space.

In the embodiment shown in Figure 3, a countercurrent between the gaseous medium and the liquid is obtained by arranging the liquid inlet 17 below the gas outlet pipe 32 and the liquid outlet 18 below the gas inlet pipe 30 such that the gaseous τηρ <? · Ϊ́νπη and the fluid is introduced into and withdrawn from the housing 10 at opposite ends thereof. In accordance with the present invention, a more effective countercurrent can be obtained by additionally arranging at least one partition wall 26 in the lower portion 12 of the fluid reservoir. in the housing 10 to form a plurality of liquid-containing compartments 27. Thus, in certain preferred embodiments of the present invention, at least one partition is provided in the lower portion for containing liquid to form a plurality of liquid-containing compartments and means to keep the liquid between the comp to lead artiments.

The partition wall 26 acts to allow a fluid flow between adjacent compartments 27, preferably by flowing the substance over the top surface of the partition wall 26 as an overflow, but other means such as perforated walls or the like may also be used. Thus, there may be at least one dividing wall in the bottom portion of the housing to form a plurality of liquid-containing compartments, with the surface of the dividing wall closest to the surface of the liquid being immersed in the liquid in sufficient degree to allow fluid flow between the compartments. The end wall 19 forms the outer end wall of the bottom portion or reservoir 12 and the top portion 13.

When partitions are placed in the reservoir or bottom portion 12, the gaseous medium passed through the gas-liquid contact space 13 is purified as it enters the gas outlet means 21, and the compartments 27 closer to the liquid outlet means will be 18 are progressively containing larger amounts of components removed from the gaseous medium.

(To prevent granular material from settling on the bottom of the compartments 27, conventional stirring means 28 may be provided therein to keep the liquid moving and to keep the granular material in suspension. As shown in Figs. 2-4, agitators powered by motors 36 'provide the desired agitation. Granular matter exiting through the liquid outlet 18 may be circulated to the liquid by conventional methods, for example, by filtration or by settling.

In certain circumstances it is desirable to oxidize or react with dissolved substances (impurities) in the liquid in the reservoir or lower portion 12. These solutes are often impurities or constituents resulting from the intimate gas-liquid contact. The oxidation or reaction can be accomplished by injecting air or other medium into the liquid causing the oxidation or reaction of the impurity or impurities. The medium injected into the liquid may be another liquid, but in preferred embodiments it is a gas. Thus, in certain embodiments of the present invention, a gaseous medium is introduced into the liquid in the reservoir to cause oxidation of at least some of the impurities or components in the contaminated liquid. Conventional means may be present for introducing esigas-like medium into the liquid to prevent oxidation. cause the components dissolved in the liquid as a result of an intimate gas-liquid contact.

For example, in Figure 3, when it is desired to oxidize matter in liquid 14, air injectants 29 may be installed in a compartment or compartments 27 formed by housing end wall 19 and partition wall 26 and / or by adjacent partition walls 26. If the apparatus is used to remove sulfur oxide from a flue gas generated by a coal-burning plant, a light injecting agent may be used to convert calcium sulfur salts to plaster for use in the manufacture of cement and wall paneling (plastering) ., in this case the contaminated or washed gas becomes a sulfur oxide depleted gas.

Since the gaseous medium is passed through the gas-liquid contact space 13 at a considerable speed, the mist 16 tends to be blown into the gaseous medium outlet conduit 32. Accordingly, in certain embodiments, it is desirable to provide means to remove therefrom liquid contained in the gas depleted or washed to impurities. Anti-condensation agents 40 may be disposed adjacent the exhaust line 32 or internally therefrom. used to keep the spray mist 16 within the gas-liquid contact space 13. In addition, such an anti-condensation agent 40 serves to minimize corrosion in the exhaust chimney, which corrosion results from acid condensation,

In a preferred embodiment of the present invention, there is provided an improved device for effecting intimate contact between gases and liquids, comprising a) an elongated horizontally disposed housing with a lower portion for containing a fluid, and an upper portion containing a defines gas-liquid contact space; b) means for introducing a gaseous medium into the gas-liquid contact space of the housing and means enabling the gaseous medium to leave the housing; c) a plurality of disk-shaped impellers with protruding outwardly from the exterior of their side surfaces, the impellers mounted on at least four rotatable shafts arranged axially in the housing and supported above the liquid so that the lower halves of the impellers are substantially immersed in the liquid; d1 means for rotating immediately adjacent axes in opposite directions; e) a liquid inlet resp. exhaust, both installed in the lower part of the house; and f) at least one partition wall in a position between the ends of the bottom portion of the housing to form a plurality of liquid-containing compartments.

Optionally, agitators can be mounted in the lower part of the housing to keep the liquid in constant motion; Means may be provided for introducing a gaseous medium into the liquid to precipitate dissolved components in the liquid as a result of an intimate gas-liquid contact; and / or means may be provided in said means enabling the gaseous medium to leave the housing to prevent loss of liquid spray mist from the housing.

In a specific aspect of the invention, it provides a method of removing sulfur dioxide (SO 2) from a gas stream using a calcium-containing compound in water, 840248 1 - characterized in that a) introduces the gaseous medium containing the sulfur dioxide into one end of a gas-liquid contact space placed above a reservoir of the calcium-containing water; B) forms a spray of the calcium-containing water in the gas-liquid contact space; c) the gaseous medium containing the sulfur dioxide passes through the spray of the calcium-containing water into the gas-liquid contact space, thereby producing a low-sulfur dioxide gas; D) the low sulfur dioxide: - gaseous medium removes at the other end of the gas-liquid contact space, placed above a reservoir of the calcium-containing liquid; e) introduces fresh calcium-containing water into the reservoir at a point substantially below the removal point of low sulfur dioxide gas, whereby the spray of calcium-containing water formed in the gas-liquid contact space at the removal point of low-carbon gas is substantially purified calcium-containing water spray mist; f1 introduces air into calcium-containing water in the reservoir to convert calcium sulfur salts contained therein into a gypsum-containing water; g) removes the gypsum-containing water from the reservoir at a point substantially below the introduction point of the SC-containing gaseous medium; and h) the plaster is recovered.

The calcium-containing water can be agitated in the reservoir to keep the precipitated gypsum in suspension.

Fig. 4 illustrates an embodiment of the present invention, wherein four rotatable shafts are used in the housing 10 to support a number of disk-shaped impellers on each 30 shafts. Each rotatable axis is preferably rotated independently of the other axes, for example as illustrated in Fig. 3, so that immediately adjacent axes can perform a counter-rotation. As shown by the arrows in Fig. 4, the axis nearest one wall is rotated counterclockwise; the next adjacent 35 axis: is rotated clockwise; the next adjacent axis is rotated counterclockwise; and the axis closest to the other wall is rotated clockwise. Of course, each axis can also be rotated opposite to that shown in Fig. 4 to achieve the 8402481 t-IS preferred embodiment of the present invention, which provides means for counter-rotating the immediately adjacent shafts.

Although other modifications of the invention and variations thereof, which may be envisioned within the scope of the invention, have not been described, the invention is intended to include such modifications »10 8402481

Claims (28)

A device for effecting an intense contact between gases and liquids comprising a) a long, horizontally arranged housing provided with a lower part for storing a liquid and an upper part,. 5 defining a gas-liquid contact space; b) means for introducing a gaseous medium into the gas-liquid contact space of the housing and means enabling the gaseous medium to exit the housing; a plurality of disk-shaped impellers capable of forming a liquid spray mist in the gas-liquid contact space, the impellers mounted on a plurality of rotatable shafts axially disposed within the housing and above the liquid such that a lower portion of the impellers is substantially immersed in the Liquid; and d) means for rotating the shafts. 2. Device as claimed in claim 1, characterized by a liquid inlet arranged in the lower part of the housing, which liquid inlet provides a means for introducing fresh liquid into the housing, and a liquid outlet arranged in the lower part of the housing. 20 houses, wherein the fluid outlet provides a means for removing spent fluid from the housing. Device according to claim 2, characterized in that the liquid inlet is substantially opposite the liquid outlet. 4. Device according to claim 2, characterized in that the liquid inlet is placed in the lower part of the housing near the means to enable the gaseous medium to leave the housing and wherein the liquid outlet is placed in the lower part of the housing near the means for introducing the gaseous medium into the gas-liquid contact space. Device according to claim 1, characterized by at least one dividing wall arranged in the lower part for containing liquid to form a number of liquid-containing compartments i and means for passing the liquid between the compartments. 6. Device according to claim 1, characterized by means for keeping the liquid at a predetermined level relative to the shafts of the impellers. 7. Device according to claim 6, characterized in that the means 8402481 v5 - 17 -> cam the liquid in one. maintain predetermined level, include a liquid inlet disposed in the lower portion of the housing below the means which allows the gaseous medium to exit the housing, and a liquid outlet disposed opposite the inlet in the housing below 5. the means for introducing the gaseous medium into the housing such that the gaseous medium and the liquid are countercurrent through the housing. 8. Device according to claim 7, characterized by at least one dividing wall in the lower part of the housing to form a number of liquid-containing compartments, wherein the surface of the dividing wall closest to the liquid surface is sufficiently immersed in the liquid To allow the flow of liquid between the compartments. Device according to claim 1, characterized by at least four rotatable shafts, each carrying a number of disc-shaped impellers. Device according to claim 1, characterized in that the means for rotating the shafts comprises a means for counter-rotating the immediately adjacent shafts. 11. Device according to conelusion 1, characterized in that the number of rotatable shafts contains at least four shafts and the device further comprises means for rotating the adjacent shafts in the opposite direction. 12. Device as claimed in claim 1, characterized by agitator means arranged in the lower part of: the housing for keeping the liquid moving in a convex motion. 13. A device according to conelusion 1, characterized by means for introducing a gaseous medium into the liquid in order to cause oxidation of the components dissolved in the liquid, as a result of an intimate gas-liquid contact. An apparatus according to claim 1, characterized by anti-condensation agents to prevent loss of liquid spray from the housing, which anti-condensation agents are provided in the means enabling the gaseous medium to leave the housing. 15. Device according to claim 1, characterized in that the disk-shaped impeller, which is a. has a shape by which a liquid spray handle can be formed in the gas-liquid contact currents, having protrusions extending from the side surface thereof. 16. Device for effecting intimate contact between gases and liquids, containing 8402481 W <-V * (-18'-a) an elongated horizontally arranged housing with a lower part for containing a liquid, and an upper part that defines a gas-liquid contact space; b) means for introducing a gaseous medium into the gas-liquid contact space of the housing and means enabling the gaseous medium to leave the housing; c) a plurality of disk-shaped impellers with protrusions emerging from the exterior of their side surfaces, the impellers mounted on at least four rotatable shafts arranged axially in the housing and supported above the liquid so that the lower halves of the impellers are are mainly immersed in the liquid? d1 means for rotating immediately adjacent shafts in opposite directions; e) a liquid inlet resp. exhaust, both installed in the lower part of the house; and f) at least one partition wall in a position between the ends of the bottom portion of the housing to form a plurality of liquid containing compartments. 17. Device according to claim 16, characterized by agitator means arranged in the lower part of the housing to keep the liquid in constant motion. Device according to claim 16, characterized by means for introducing a gaseous medium into the liquid to cause oxidation of the components dissolved in the liquid as a result of an intimate gas-liquid contact. The device of claim 16, characterized by means disposed in the means which allows the gaseous medium to leave the house to prevent loss of liquid mist from the house. 20. Method for washing a gas stream containing impurities which are removable by a liquid, characterized in that a) a gaseous medium containing the impurities is introduced at one end of a gas-liquid contact space located above a liquid reservoir? b) forms a spray of the liquid in the gas-liquid contact space; C) the gaseous medium containing the impurities passes through the liquid spray mist into the gas liquid contact space, thereby producing a depleted gas; 8402481 - 19 - & «I (d) removes the contaminated depleted gas from the other end of the gas-liquid contact space; e) introduces non-contaminated liquid into the reservoir at a point substantially below the point of removal of the pollutant-depleted gas, causing the liquid spray mist formed in the gas-liquid contact space in or at the point of removal of the pollutant-depleted gas , becomes an almost contamination free liquid spray mist? and f) removes the contaminated liquid from the reservoir at a point 10 substantially below the introduction point of the contaminant-containing gaseous medium. Method according to claim 20, characterized in that the liquid is maintained at a predetermined level in the reservoir. 22. A method according to claim 20, characterized in that the liquid is stirred in the reservoir. A method according to claim 20, characterized in that a gaseous medium is introduced into the liquid in the reservoir to cause oxidation of at least some of the impurities in the contaminated liquid. A method according to claim 20, characterized in that liquid is removed which is contained in the gas depleted of impurities. 25. A process for removing sulfur dioxide (SO 2) from a gas stream by using an aqueous calcium-containing compound, characterized in that a) the gaseous medium containing the sulfur dioxide is introduced into one end. of a gas-liquid contact space placed above a reservoir of the calcium-containing water; b) forms a spray of the calcium-containing water in the gas-liquid contact space? c1 the gaseous medium containing the sulfur dioxide passes through the spray of the calcium-containing water into the gas-liquid contact space, thereby producing a low-sulfur dioxide gas? dl removes the low sulfur dioxide gaseous medium at the other end of the gas-liquid contact space, located above a reservoir of. the calcium-containing liquid; each fresh calcium-containing water introduces into the reservoir at a point substantially below the point of removal of low-sulfur gas, 8402481 «- 20. - causing the spray of calcium-containing water to form in the gas-liquid contact space at the point of removal of SO - lean gas is essentially a purified calcium water spray spray; f) introduces air into calcium-containing water in the reservoir to convert 5 calcium sulfur salts contained therein into a gypsum-containing water; g) removes the gypsum-containing water from the reservoir at a point substantially below the introduction point of the SC> 2 containing gaseous medium; and 10 h) the plaster is recovered. A method according to claim 25, characterized in that it is used. Stir calcium water into the reservoir to keep the precipitate of gypsum in suspension. 27. A method according to claim 25, characterized in that the calcium-containing compound is lime. 28. A method according to claim 25, characterized in that the calcium-containing compound is a powdered limestone or lime. 1 8402481