NO129359B - - Google Patents

Description

Method for processing liquid on rotating surfaces in an apparatus for establishing contact between gas and liquid, as well as device for carrying out the method.

The present invention relates to a

method for distributing liquid on

rotating surfaces in a contact zone in a

rotor which is arranged to provide intimate

contact between gas and liquid. The invention also includes a device for

implementation of this procedure.

The mentioned surfaces are placed on a rotor in an apparatus, which in the following for

for simplicity's sake should be called a centrifugal absorber, regardless of whether the device

used as an absorption device, desorption device, distillation device, heat exchanger or dust resp. droplet separator.

The invention can be applied to all of these

categories of appliances with horizontal,

vertical or inclined axis of rotation, but

in the following, as a practical example, only the embodiment which

has a vertical axis of rotation. Furthermore, it must

it is mentioned that the term "gas" in this connection must also include steam. The type of

devices to which the invention relates consist

of a rotor which is rotatable about a

shaft and surrounded by a fixed casing. The peripheral part of the rotor, the contact zone, contains the surfaces over which the gas is brought

intimate contact with the liquid that flows forward on the surfaces. The liquid is supplied

to the part of the contact zone that is located

closer to the shaft and is caused to flow over the surfaces in the direction towards the periphery of the rotor by means of centrifugal force. The gas is made to flow in counter or co-flow with respect to the liquid in the spaces between the surfaces. Above-

the surfaces, which can be arranged irregularly or regularly, consist of e.g. of filler cells of suitable type, or of lamellar arranged fixed surfaces, which may either be parallel or nearly parallel to the axis of rotation or also perpendicular or nearly perpendicular to this axis, but may also form any other angle from 0° to 90° with the axial plane. The fixed surfaces may be smooth or suitably corrugated or folded, or otherwise designed with an uneven surface structure. They can be flat or curved and parallel to each other or form an angle with each other.

Many types of such centrifugal absorbers have been proposed and tested, but the result has so far not lived up to expectations. The investigations that have led to the present invention have now shown that the unsatisfactory results are largely due to the fact that the liquid has not been sufficiently continuously and evenly distributed on the surfaces of the contact zone. On closer reflection, it also turns out to be natural with regard to the strong centrifugal force, which quickly drives the liquid towards the periphery of the rotor, that the liquid must be fed evenly at every moment, both along the entire inner periphery of the contact zone, and over its entire height if you will achieve that the surfaces of the contact zone must be continuously moistened as evenly as possible.

It is also clear that there will be a significant deterioration in the efficiency of the centrifugal absorber -■ the number of theoretical bottoms - already if a smaller part of the contact zone is not constantly wetted with the liquid, because gas in this case can pass sere these non-moistened parts without coming into contact with the liquid.

The way in which the problem of supplying liquid to the contact zone has been solved has so far consisted in arranging one or more fixed points within the inner periphery of the annular contact zone, at which the liquid flows out towards the outer periphery of the contact zone. In order that the distribution of the liquid along the periphery will not be too bad, several such points have been arranged underneath, which must then be supplied with equal amounts of liquid. In order for the liquid not to be distributed too poorly in the height direction, one has e.g. let the liquid flow out through spreading nozzles or have arranged at the relevant points vertical pipes with several holes which are directed towards the contact zone or with a longitudinal slot directed in the same direction. In this way, however, a fully continuous and even distribution of the liquid cannot be achieved, and further, the parts of the contact zone which are closer to the center will lose part of the applied liquid during the passage from one feeding point to another. The disadvantages of an uneven liquid distribution are particularly evident with late-trifugal absorbers of the type where the contact zone consists of gaps between flat or curved plates. In the case of horizontal (perpendicular to the axis of rotation) plates, it is therefore absolutely necessary that the liquid is distributed completely evenly in height, as the liquid cannot move from one gap to another during the passage through the contact zone. Even with vertical or almost vertical plates, however, an even distribution is extremely important, as the above-mentioned investigations have shown that liquid, which is concentrated at a point, has a very small tendency during the flow towards the periphery to distribute upwards and downwards on the plate.

The above-mentioned, hitherto attempted ways of distributing the liquid also have the following disadvantages, which in some cases can be of decisive importance. As the liquid is supplied to fixed points, while the inner periphery of the contact zone passes by these points during the rotation at high speed, a strong impact occurs between the liquid and the passing contact surfaces, which thereby breaks the liquid into fine droplets, which - when the gas passes in countercurrent to the liquid — easily carried away by the gas stream and carried out of the absorber. Attempts have been made to prevent this phenomenon by arranging horizontal plates attached to this periphery immediately within the inner periphery of the contact zone, on which the liquid slides up to the rotational speed of the rotor. However, satisfactory results have not been achieved in this way.

The purpose of the present invention is to remove the disadvantages mentioned above. The method according to the invention is mainly characterized by the fact that the liquid near the center of the rotor is supplied to one or more spreaders, which are given a rotational movement independent of, but about the same geometric axis as the rotor of the device, and that the liquid during its movement outward from the spreader's axis of rotation is accelerated up to a high ere peripheral speed, after which the liquid, using the centrifugal force, is spread in a direction approximately parallel to the axis of rotation by means of guide surfaces which are connected to the spreader and rotate with it, and/or tubular bodies to be thrown from these towards the rotor of the apparatus, distributed over its entire height and inner periphery. A device for carrying out this method appropriately according to the invention consists of a round a shaft with the same center as the rotor, but independently of this rotor rotatable, flat, almost flat and/or bowl-shaped plate or similar, along whose outer periphery a number of wreath-shaped arranged, with the axis of rotation mainly parallel or in the direction outwards from this inclined guide surfaces and/or pipes.

The spreader's rotation speed can be higher or lower than that of the rotor, but can also possibly be as great as that of the rotor. The rotation can take place in the same or opposite direction compared to the rotation of the rotor.

As close to the center of the spreader as may be practically appropriate, the liquid is supplied to the bottom of the spreader, which is approximately level with the lower edge of the contact zone placed on the rotor. This bottom can optionally be provided with rails or similar bearing surfaces, which can be parallel to a plane which is perpendicular to the axis of rotation or in certain cases can completely or partially form an angle with this plane. At these driving surfaces, or possibly just by the friction against the bottom, the liquid is accelerated during its passage from the center towards the periphery of the spreader to higher and higher peripheral speed — often approximately the same as the spreader has at corresponding points. The liquid is then made to rise along those arranged in the periphery of the spreader, e.g. vertical or almost vertical control surfaces, which are of such a nature — e.g. in that they are inclined and/or have an upward taper, e.g. triangular shape and/or is provided with inclined slots and/or with channels — that the liquid leaves these surfaces uniformly along the entire height, which is approximately equal to the height of the contact zone, during which the uniform distribution in height can be either continuous or discontinuous, but in the latter case, the distance between the points where the liquid leaves the almost vertical control surfaces is shortened.

In certain cases, when the contact zone consists of e.g. of vertical or nearly vertical plates with intermediate slots, it is in most cases necessary that the spreader rotates at a generally higher speed than the rotor. It must then be provided with a special shaft which can lie inside or outside the rotor's shaft, or be introduced into the absorber from the opposite side of it.

Optionally, several spreaders can be arranged along the axis of rotation to spread the liquid over the height and inner periphery of the rotor. Furthermore, the rotor can be completely or partially made to rotate with the help of the liquid droplets' living power, when these leave the spreader and hit the rotor with a greater peripheral speed than the rotor has, where the liquid droplets hit it.

Some embodiments of a device according to the invention are schematically shown in the attached drawings. Figs 1 and 2 show in side view, partly in section respectively. top view of an embodiment, fig. 3 and 4 similarly show another embodiment, fig. 5 and 6 in a similar way, a third embodiment, fig. 7 and 8 in a similar way, a fourth embodiment, and fig. 9 and 10 in a similar manner a fifth embodiment. Fig. 11 and 12 as well as 13 show a part of the spreader's outer periphery seen from the side according to some different embodiments.

In the drawing, fig. 1 and 2 show the part 1 of the ring-shaped rotor which is closest to the axis of rotation, i.e. the inner part of the contact zone, in this case consisting of lamellae, although other filling bodies can of course also come into play. The drive shaft for the rotor is not shown. The spreader, located inside the rotor 1, consists of a plate or plate 2, designed to be brought into rotation with the desired number of revolutions in the desired direction (e.g. in the direction of the arrow P) by means of a shaft 3. Around the shaft 3 there is a supply pipe 4 for the liquid. This pipe opens at the bottom near the center of the plate 2. Further out on the plate, a mainly cylindrical, conical or cup-shaped surface 5 is arranged to distribute the liquid evenly along the periphery of the spreader. This surface consists, according to fig. 1 and 2 of a number of ring-shaped, mainly triangular guide surfaces, with its bottom so arranged that the liquid evenly distributed over the bottom is caused to rise upwards along the triangular surface in the direction towards its tip 6. The bottom of the plate 2 can be provided with showed fixed entrainment surfaces, which impart to the liquid a velocity equal to or nearly equal to the plate's peripheral velocity. A roof can possibly be placed above these carrier surfaces to prevent the liquid from splashing up.

The 5 triangular sides of the control surfaces can have the same slope as each other, but can also, as shown in fig. 1, be arranged with one side 5a mainly vertical and the other side 5b, which lies furthest forward in the direction of rotation, inclined. On the inner side of the guide surfaces facing the shaft 3, there can be arranged channels or tracks, which are suitably parallel or almost parallel to the shaft 3. As can be seen from fig. 1 clear the surfaces 5 slightly outwards from the shaft. On the side of the guide surfaces facing the periphery, guide surfaces 7 are arranged which are parallel or almost parallel to the shaft 3.

During the spreader's rotation, the supplied liquid flows outwards on the bottom of the plate 2 and is distributed evenly along its periphery at the bottom of the triangular surfaces 5, while the liquid during its outward movement acquires approximately the same peripheral speed as the plate. The liquid rises up along the surfaces 5, and flows onto the guide floats 7 and is evenly distributed on these in a vertical direction, after which the liquid is thrown towards the inner periphery of the rotating rotor 1, and is distributed on the surfaces of the rotor along the entire periphery and out along the entire height of the contact zone. At the same time, the gas is carried over the surfaces of the rotor which are thus coated with thin layers of liquid in contact with these and in co-flow or counter-flow in relation to the flow of the liquid towards the periphery of the surfaces 1.

The guiding surfaces 7 can be radial or form an angle with the radius. The surfaces 5 do not of course have to end with a point at the top, but can also be more or less rounded at this point. In the same way, the 5 side edges of the surfaces do not have to be straight, but can be curved or uneven.

Fig. 3 and 4 show a somewhat modified embodiment in which the rotation shaft 3 is connected to the plate on its underside. Each control surface is connected to a bottom plate, from which the guide surface 7 extends and each control surface has on the inside a multi-

numbers run 11.

Furthermore, 10 denotes the surfaces which limit the channels 11. 9 denotes a bottom plate belonging to the guide surfaces 5 by means of which the surfaces are attached to the plate 2.

Fig. 5 and 6 show how the channels described above can be formed between la-

knit 12 on the inside of faces 10.

Fig. 7 and 8 show how these lamella

clay can be formed from a folded plate that is clamped between the base plate and a clamping

call 21, which is provided with tracks. Each clean-

ne 11 is carried out with holes 22 through which the liquid is thrown towards the guide surfaces. To get

the best distribution of liquid in the height direction, the holes in the corresponding channels in the different sectors can be slightly offset in the height direction so that they intersect with each

others, as can be seen from fig. 7. Pla-

ten's slope can be varied with differ-

equal diameters of the groove in the clamping ring.

Fig. 9 and 10 show another embodiment,

where the channels are replaced by pipes 14 with a possibly mainly horizontal part 15

at the end of which the pipes open up to the lead-

surfaces 16, which correspond to the guide surfaces 7 described above. The pipes preferably open at a different height near the inner periphery of the rotor 1, so that the liquid mostly

is divided evenly along the height of the contact zone in the rotor. This device of pipe mouth-

genes at different heights correspond in principle to the 5 parts of the control surfaces described above

dende edge 5b. Below, a roof 13 can be arranged slightly above the bottom of the plate 2 to prevent liquid splashing. This roof can be connected towards the center to a wall 13a directed obliquely upwards. Fig. 9 and 10 show how the bottom of the plate 2 can be provided with carrier rails 17 under the roof 13. The inner ends of the pipes 15 open up to these rails 17. The pipes 15 have in this

do not fold the vertical part 14.

Fig. 11, 12 and 13 show an embodiment with the guide surfaces 19. 19a resp. 19b (before denoting

net 7 resp. 16) provided with grooves or channels 20 perpendicular to the axis along part or all of its length, in order to prevent

ken during its flow towards the periphery must deviate upwards or downwards.

Claims (11)

1. Method for distributing liquid on rotating surfaces in a contact zone in a rotor which is designed to provide intimate contact between gas and liquid, characterized in that the liquid near the center of the rotor is supplied by one or more spreaders you, which is given a rotational movement independent of, but around the same geometric axis as the rotor of the device, and that the liquid during its movement outwards from the axis of rotation of the spreader is accelerated up to a higher and higher peripheral speed, after which the liquid, using the centrifugal force, is spread in an approximately parallel direction with the axis of rotation by means of control surfaces which are connected to the spreader and rotate with it and/or tubular members to be thrown from these towards the rotor of the apparatus, distributed over the entire height and inner periphery of the contact zone. 2. Method as stated in claim 1, characterized in that the liquid, when distributed in a vertical direction, leaves the guide surfaces and/or pipes at the periphery of the spreader, is intercepted by guide surfaces that are parallel or nearly parallel, with a plane through the axis of rotation, and arranged radially or at an angle with the radius, which guide surfaces are firmly connected to the spreader, under which the liquid from the outer edge of these surfaces is thrown towards the apparatus's rotor. 3. Method as stated in one of the claims 1-2, characterized in that the rotor is made to rotate in whole or in part by means of the living force of the liquid droplets ejected from the spreader when these leave the spreader and hit the rotor with a greater peripheral speed than the rotor has at those points where the liquid droplets hit this. 4. Device for carrying out the method according to one of the claims 1-3, characterized in that it comprises a number around an axis with the same center as the rotor (1), but independent of this rotor rotating plane, almost plane or bowl-shaped plate or plate (2), along the outer periphery of which a number of ring-shaped arranged, with the axis of rotation mainly parallel or in the direction outwards from this inclined guide surfaces (5) or tubes (14) are attached. 5. Device as stated in claim 4, characterized in that the plate (2) is provided with entrainment surfaces (17), designed to, during the passage of the liquid towards the periphery, impart to this liquid an equal or almost equal peripheral speed to the peripheral speed of the plate, under which these surfaces upwards, if necessary, is fully or partially limited by a roof (13) to prevent liquid from splashing up. 6. Device as stated in claim 4, characterized in that the guide surfaces (5) with the axis of rotation parallel to or in relation to this, sloping outwards from the plate are mainly triangular or taper upwards, with the bottom so arranged towards the periphery of the plate that the liquid is brought to to rise upwards along these tapering surfaces, evenly distributed over their bottoms. 7. Device as stated in claim 6, characterized in that the mainly triangular control surfaces (5) are provided with parallel or almost parallel grooves or channels (11) in relation to the axis of rotation, intended for utilizing the even distribution of the liquid at the triangular surface (5) bottom to direct the liquid over the triangular surfaces in such a way that it leaves the surface substantially uniformly distributed in the vertical direction. 8. Device as stated in claim 4, characterized in that the tubes (14, 15, fig. 9-10) sloping outwards from the plate, with the axis of rotation parallel or in relation to this, open at different heights near the inner periphery of the rotor (11) , with a view to ensuring that the liquid is mostly evenly distributed over the height of the contact zone. 9. Device as stated in claim 4 or 8, characterized in that a number of In the axis of rotation, parallel or almost parallel guide surfaces (7, 16, 19) are thus arranged next to the outer periphery of the guide surfaces (5) or until the outer mouths of the pipes (14, 15), that these guide surfaces distribute it from resp. control surface or pipe mouth outflowing liquid in a vertical direction before it is thrown towards the inner periphery of the contact zone (1). 10. Device as stated in claim 9, characterized in that the guide surfaces (7, 16, 19) are radial or form an angle with the radius. 11. Device as stated in claim 10, characterized in that the guiding surfaces (19) over part of or all of their height are provided with mainly perpendicular or almost perpendicular grooves or channels (20) to the axis of rotation, designed to prevent the liquid during its flow towards the periphery deviates upwards or downwards.