NO121621B - - Google Patents

Description

Apparatus for effecting contact between gases or vapors and liquids.

The invention relates to devices for effecting contact between gases or vapours

and liquids, of the type comprising a

container which has a liquid space and immediately above this a gas space as well as more than

one rotor arranged to provide it

desired contact. Each of these rotors consists of a rotating shaft on which there

distribution devices are installed (spreading

members), e.g. washers, sectors or arms, in such a way that they under the axle

rotation moves alternately in the liquid space and in the gas space. In the case of contact-producing devices of this kind, it is

often of great importance not only that gas

and liquid are properly mixed in the gas space, but also that liquids, resp. liquids which

contains suspended solid particles, becomes

kept in uniform condition during operation, so

their composition remains essentially uniform throughout the liquid space. This is

particularly important in the case of the liquid containing suspended solid particles which are

tend to settle to the bottom. Contact-producing devices of the usual kind

is, with the right construction, well suited for

absorption, purification, or condensation of

gases or vapors in liquids. By these

operations where, in addition to physical processes, chemical reactions can also take place

under very strongly varying temperature conditions. It has been observed that a large

number of physical and chemical operations have

have been difficult to carry out practically in available equipment of the present one

type, which is believed to be due to that relationship

that it has not been possible to hold the liquid

homogeneous in the liquid space. It is also vik-

ensure that the gases are kept mixed with each other. Previously known apparatus has not proved fully satisfactory in this respect, and the purpose of the present invention is to provide a contact-producing apparatus of the above-mentioned type, which fully satisfies the requirements that should be placed on it, in order to able to perform such physical and chemical operations that require great accuracy. It is thus a purpose of the invention to perform and arrange the rotors so that liquids and suspensions that are treated in the container will be so uniform that the composition will be approximately the same in all parts of it, even in such parts that are thrown up into the gas space by the rotors .

In order to fulfill these and other purposes, the invention consists in using at least two rotors to produce the contact, and arranging the rotors in the container in such a way that their axes, which should be mainly parallel to each other, will be mainly vertical to the longitudinal direction of the container, f e.g. perpendicular to the side walls, and that at least one rotor will be substantially located only within one longitudinal half of the container and extend from the side wall about halfway toward the opposite side wall, and at least one rotor will be substantially located only in the other longitudinal half of the container and extends from the opposite side wall approximately halfway towards the first-mentioned side wall, and that at least one of the latter-mentioned rotors is arranged to rotate opposite to at least one of the first-mentioned rotors. The rotors will thus extend V*—% of the way from one side wall to the opposite side wall. Preferably, all rotors in one of the container halves are arranged to rotate in the same direction. In this way, all rotors can be brought to drive the liquid in a closed path around the container. In some cases, it is advantageous to place a dividing wall between the longitudinal halves over part of the length of the container to contribute to the correct circulation of the liquid and avoid deposits on central parts of the bottom.

The invention will now be described in more detail in connection with the drawing, which shows one of many possible embodiments. The drawing illustrates and shows examples of different ways of arranging the rotors according to the invention.

Fig. 1 shows a horizontal section and fig. 2 vertical section of an apparatus or device according to the invention, while fig. 3 shows a rotor in longitudinal section.

In the side walls of a container 1, a number of shafts 2 are mounted in bearings 3. The shafts 2 normally extend approximately only to the center line of the container, but as shown by the shaft at one end, it is also possible according to the invention to let the shafts reach beyond the center line. A shaft 2a extends across the entire container cross-section and is mounted in bearings in both side walls. The shafts 2 are all equipped over their entire length and the shaft 2a over half their length with spreader discs 5, which can be replaced. In this way, it is possible, if necessary, to change the distribution means with regard to diameter and/or length. It is also possible to change the number of discs. It is advantageous to arrange the rotors offset in relation to each other, so that a rotor on one side is directly opposite the space between two neighboring rotors on the other side, but you can, as shown in the drawing, also arrange them straight towards each other. With this arrangement, there are many variation possibilities that can be chosen from in order to satisfy special requirements. Furthermore, a further possibility of variation lies in regulating the speed of rotation of the rotors and possibly changing the direction of rotation, which is included in the invention. It is often appropriate, as shown in the drawing, to let all the rotors on one side run in the same direction, but opposite to those on the other side.

The liquid space 6 is filled with liquid through the inlet 7, and the liquid exits through the outlet 8. The gas enters through the gas inlet 9 and is taken out through the outlet 10. The inlet and outlet can be arranged so that gas and liquid pass each other largely in opposite directions -current. With the help of a level regulator, shown in the drawing in ion of an overflow threshold 15, one can change the height of the liquid space and thus get another possibility of variation. If desired, the rotors can be constructed so that they can be raised or lowered, preferably individually. In this way, it is possible to regulate the device's suspension effect, provided that this effect depends to a large extent on the vertical distance between the distribution member, e.g. a spreading disc, and the bottom of the container

Viewed from one of several possible viewing angles, the invention thus consists in placing the rotor in the container at such a small vertical distance above its bottom that in the water that fills the container's liquid space, a violent flow of the parts of the water that are closest to the bottom and vertically below the rotor, as a result of the rotor's rotation in the water. Thereby, a deposit of solids on the bottom will be prevented, provided that the current is sufficiently strong for the particular goods that are suspended. Thus, e.g. finely divided lime, magnesium carbonate (magnesite) or dolomite, e.g. for the production of cooking acid for the sulphite cellulose process, the distance must be so small that the flow of suspension is strong enough to keep the particles of these substances suspended. Admittedly, the strength of the flow also depends on the diameter of the spreading discs or the like and on their speed of rotation, but it has been established by experiments that the depth gradient of the liquid flow under a rotating disc varies relatively little within the limits of the disc diameter and speeds used in practice, while the horizontal velocity of the liquid near the edge of the discs varies considerably.

The distribution means are conveniently arranged in larger or smaller sections, each of which comprises a tube 11 with an internal diameter that is slightly larger than the diameter of the shaft 2 or 2a, on which it is mounted. The length of the pipe 11 is chosen so that one or more sections can be placed on the axle as desired. Attached to this pipe are a number of disks 12 or entrainment means of another suitable form to lift liquid up into the gas space and drive the liquid around in the vessel. The radial dimensions of these entraining means as well as their mutual distance are chosen in accordance with the requirements for the required treatment. The pipe 11 is equipped with flanges 13 and sockets 14, which make it possible to mount the distributor sections on the shaft in the number and in the places desired. The distributor sections' mechanical design and the way in which they are loaded onto the axle can be changed without affecting their functions.

It will be understood that the apparatus is shown and described only as an example, and that any combination of two or more rotors as shown can be used, provided that there are at least two rotors placed in each half of the container and rotate in opposite directions.

In this connection, it should be noted that a distribution device according to the invention is not the same as or identical to a normal swirler (turbulator) or propeller that works submerged in the liquid. The present spreaders work both in the liquid and in the gas space at the same time. They should be arranged to work in varying depths of liquid and thus also with varying volumes in the gas space. One can replace distribution means and change the speed or direction of rotation to achieve the effects that the prevailing conditions dictate. The distribution principle as such is commonly used, and likewise it is common to use flat, corrugated or differently shaped circular rotating disks, rods or other types of entrainment means that rotate, but in relation to the invention these distribution elements are used in a new and more efficient way than before.

It is thus clear that the distribution devices according to the present invention are in principle not allowed to extend over the entire width of the absorption apparatus, but only over approximately half the width. In this way, the distribution device will work or act on each side in the device's liquid and gas space. When these distribution devices are rotated with suitably determined speeds and directions of rotation and with the desired depth in the liquid and at a suitable distance from the bottom, movements can be achieved in the liquid and gas in the device that cannot be achieved in any other way known to date, and which has a strong and effective effect on the course of reactions. The liquid can e.g. move as shown by the arrows in the drawing.

In order to illustrate how the purposes of the invention can be realized by means of a device according to the invention, an example will now be given.

In a rectangular closed container with length 2.25 m, width 1.5 m and height 2 m, two rotors were arranged which protruded 0.75 m from each side wall near opposite end walls. Each rotor carried ten discs evenly spaced on the rotor shaft. The rotors could be moved vertically.

In one experiment, disks with a diameter of 0.6 m were used, and the rotors were set with the lower edge of the disks approx. 0.15 m from the bottom of the container. The container was filled with water to a height corresponding to a submerged depth of the disks of 0.1 m. The rotors were later set to rotate in opposite directions with a revolution rate of 610 per minute. my. to drive the liquid along the respective sides where the rotors were placed. Lime powder was added in an amount corresponding to 2 percent of the weight of the water. Samples taken from the spray in the gas space, from a surface layer of the suspension and from a layer closer to the bottom gave different values of percentage lime content, and some lime deposited on the bottom.

The rotors were now lowered so that the height from the bottom of the container to the underside of the discs was 0.10 m. Samples from the aforementioned locations now showed practically the same percentage amount of lime, and no sediment was obtained.

Experiments were also carried out with disks of 0.5 m in diameter, and relationships between the number of revolutions, submerged depth and distance from the bottom to achieve uniform suspension could easily be established.

The relationship between disc diameter, number of revolutions, submerged depth and distance from the bottom obviously varies with the material to be slurryed.

In general, however, it can be said that the number and diameter of the spreading elements on each rotor, the submerged depth of the spreading elements in the liquid space below the liquid mirror and the vertical distance of the rotors above the container bottom in an apparatus according to the invention have such an interrelationship that the horizontal velocity of a liquid which fills the liquid space, becomes approximately equal across the entire vertical cross-section of each longitudinal half of the container as the rotors rotate at their operating speed. It has been established that the effectiveness of a given apparatus in making the liquid uniform, and the depth to which the effective agitation reaches, increases significantly up to a given speed. However, increasing the speed beyond this value will not significantly improve the homogenisation of the liquid. The critical speed range depends on the construction of the apparatus and can be easily determined for a given apparatus. The working speed should of course be at least somewhat below the critical speed, and it will be determined to a large extent by the requirements for an efficient spraying of liquid in the gas chamber of the apparatus and by the economic gain from an increase in speed.

The distance between the rotor and the bottom

of the container can also be specified on the basis of how the water or a given suspension, e.g. finely divided lime or magnesite, which fills the liquid space, conditions

themselves. Thus, the device should be arranged in such a way that the parts of the water that are closest

the bottom and vertically below the rotor, when rotating the rotor at its operating speed and with a submerged depth equal to

at least V3 of its radius will be brought to

flow virtually instantaneously

this rotation is started. What a suspension

in that case, the particles that are suspended near the bottom should be brought to the bottom

the specified conditions to move and be held

suspended, so none will occur

deposition.

In the event that the spreading organs, e.g.

have the form of sectors or arms become theirs

diameters to be calculated equal to the radial distances

of the sectors or arms, respectively

outermost points from the center of the rotors.

Claims (6)

1. Contact device for gases or vapors and liquids, comprising a container with a lower liquid space and a gas space arranged on top of this, as well as two or more rotors with parallel shafts arranged to effect contact, each consisting of a rotatable shaft or shaft part and spreading means thus arranged on this, f e.g. in the form of disks, that during the rotation of the shaft they move alternately in the liquid space and the gas space, characterized in that at least one of the rotors (2, 5) in its shaft direction extends mainly over only one half of the cross-section of the container (1), and at least one other extends mainly over the cross-section of only the other half. 2. Apparatus as stated in claim 1, characterized in that at least one rotor (2, 5) arranged in one half of the container's (1) cross-section is arranged to rotate in the opposite direction to at least one rotor (2, 5) arranged in the other half. 3. Apparatus as stated in claim 1 or 2, with a plurality of rotors, characterized in that at least one rotor (2, 5) in one half of the container's (1) cross-section is arranged in the part of this half that lies straight out for the gap between two neighboring rotors (2, 5) in the other half. 4. Apparatus as stated in one of the preceding claims, characterized in that the spreader members (5) on at least one rotor are replaceable with a set of spreader members of a different diameter. 5. Apparatus as stated in one of the preceding claims, characterized in that at least one of the rotors can be raised and lowered in relation to the bottom of the container (1). 6. Apparatus as set forth in one of the preceding claims, characterized in that the rotors (2, 5) are provided with drive devices that allow a change in their rotational speed and/or direction.