DE1113210B - Device for the finest distribution of gases in liquids - Google Patents

Description

Device for the finest distribution of gases in liquids The invention relates to a device for the finest distribution of gases in liquids.

"Gas" should be any gas, both pure and mixed can be understood with other gases. The gas can also be mixed with liquid or be interspersed with dust-like particles.

Known devices for the distribution of gases in liquids consist of a hollow shaft with a hollow hub, which is also used for gas supply, connected to the hollow body, which by means of the vertically arranged shaft are set in rotation in the vessel containing the liquid to be gassed. These rotating hollow bodies usually have the shape of long tubes or hollow wings, the openings on their surface for the passage of the gas and for its distribution have in the liquid. Wing-like ones have proven particularly useful here Hollow body with a streamlined cross-section.

In another embodiment of such a distributor, the rotating Hollow body also used as a pump for sucking in the gas through its hollow shaft, and the outlet openings in the hollow body are arranged so that of these openings a gas-liquid mixture radially outwards against the guide surfaces a stator distributing the gas is thrown.

It is also already known in such gas distribution devices to design the radial guide devices as hollow wedges open at the rear, the each through an intermediate wall into a radial gas supply channel and into one at the rear open wedge cavity are divided. hm Keith cavity then arises during the rotation the guide device a negative pressure, which through openings in the partition wall the Sucks gas from the radial supply channel. With a similarly operating device the radial guide devices are designed as tubes, at their outermost end parts short channel-like sections are set, which also have the task of a local negative pressure in the liquid for the purpose of sucking in the gas through the radial To show tubes The device according to the invention is not distinguished from it only because of a special simplicity, but also because it is an extraordinary one enables fine distribution of gases in liquids and allows configurations, due to the great adaptability to waste-like operating requirements is guaranteed.

A device designed according to the invention for the finest distribution of gases in liquids is known per se with radial to at least one approximately vertical axis of rotation arranged guide devices equipped, the on the side facing away from the direction of rotation, open cavities are different but differ from the known devices in that the guide devices in essentially over their entire radial length as simple, continuous on the back open grooves are formed and rotate at such a high speed that on elongated vacuoles in the liquid on the back of the guide devices develop. The channel-like guide devices can be connected to a gas supply in a known manner Wise hollow hub should be attached, then the radially inner The channel ends open directly into the hub.

To ensure that the gas is distributed as evenly as possible, should the vacuole as possible through the entire cross section of the liquid containing The vessel is therefore moved in a known manner for the liquid a vessel with a Kreisonerschnift in connection with around the central axis of the vessel rotating, radially extending guide devices reaching close to the vessel wall or a star of such guiding devices.

With increasing free cross-section of the vacuole, which is created by means of the channel-like Guide device can be achieved by increasing the profile height of the channel, the momentum of the fluid jets forming the vacuole walls and increase the energy of the eddies leaving behind the vacuole in the vortex braid Liquid.

By increasing the profile, it is therefore possible to pass a larger amount of gas through to transport the vacuole and at the same time this larger amount of gas through the increased Dissolve vortex energy into fine bubbles. Should therefore have a gassing device work with variable gas throughput, according to the invention the shape, in particular the so-called shadow area (stitch height) of the vacuole over the entire length of the vacuole or a part thereof perpendicular to the direction of movement of the vacuole to the respective Gas throughput changed accordingly, this change possibly being immediate can be caused by the forces acting in the vacuole. To this end can For example, the channel-like guide device divided into two parts in the longitudinal direction be that are pivotable about a common axis.

Is the gas throughput with practically the same effect of the division can be varied within wide limits, so it is expedient to use the vacuole generating guide device od the shape of an elastically deformable wing. Like. to give the one on its longitudinal center axis by one with the drive mechanism the distribution device rigidly connected bracket is supported. Will be such If the device is set in rotation, the elastic, which deforms like a channel, forms The wing is the front surface of the vacuole that conducts the gas to the point of consumption. In the steady state that is established, the rotating must be at every point Wing balance of the forces acting on it during rotation exist. These Forces are on the one hand the elastic internal forces of the wing, which the wing seek to bulge up or to level out, and on the other hand it is the pressure of the oncoming Liquid and the negative pressure in the vacuole, which is the radius of the curvature of the Try to reduce the size of the wing.

For a given speed of the guiding device, the Amount of gas flowing into the vacuole (e.g. via a hollow shaft), the Pressure in the vacuole lower; this causes the arching of the wing Forces greater, and there will be a new state of equilibrium with a lower pitch (smaller so-called shadow area) at which the power consumption the device is lower. When the gas supply is increased, the reverse occurs Ratios a. The elastic wing is therefore deformed under the influence of the forces acting automatically and thus adapts to the gas throughput, whereby the power consumption is always in reasonable proportion to the gas throughput.

The gas to be distributed does not have to be supplied via a hollow shaft take place in the guide devices, rather it is possible within the scope of the invention and in some cases even expedient, this gas by means of known devices, z. B. so-called jet pipes, from a lying outside of the guiding devices Make from the vacnoles in the form of coarse bubbles from below through the liquid feed through. The fine distribution of the gas in the liquid comes about caused by the fact that the coarse gas bubbles as soon as they are due to their buoyancy or as a result of the fluid movement caused by the rotating baffles get into the area of action of the guiding devices, to some extent already the contact with the wall of the vacuole formed by the liquid itself turbulent flow, but on the other hand at the rear end of the vacuole or in their pigtail can be dissolved into a multitude of fine bubbles.

Various embodiments are schematically shown in the drawings of the invention shown, on which further features of the invention are explained should be. All details not directly related to the invention, such as drive, supply and discharge of gas and liquid from the vessel to be gassed etc., have been omitted.

Fig. 1 is a cross section through a moving guide device according to the invention and through the vacuole it creates; Fig. 2 is a partially sectioned view Side view and FIG. 3 shows a horizontal section through a two-armed distribution device according to the invention; Fig. 4 shows the plan view of a three-armed embodiment a device according to the invention; Fig. 5 is a cross section through an adjustable one Guide device; FIGS. 6 and 7 show, similar to FIGS. 2 and 3, a different embodiment of the invention; 8 a, 8b and 9 a, 9b explain the structure and the mode of operation the elastically deformable used in the embodiment according to FIGS Guiding device.

In the distribution device according to FIGS. 2 and 3, the is to be distributed Gas is supplied via a pipe al to a hollow hub a, either from below by means of a shaft a2 or from above by means of the in this case at the same time serving as a hollow shaft pipeline is set in rotation. The hollow hub a is through hollow body-like extensions a 'with the channel-like guide devices b connected, the concave or open side of which faces away from the direction of rotation. These Guide devices b extend from the axis of rotation expediently in a straight line to in the proximity of the vessel wall.

The device according to FIGS. 2 and 3 is with two diametrically opposed Guide devices, the device of FIG. 4 with three equally angularly offset Guiding devices equipped. The number of these guiding devices can of course can be increased even further as long as the vacuole generated by a guide device is not disturbed by the following guidance device.

If a distribution device of the type described in the sense of the in 3 and 4 arrows drawn in such a way in rotation that the concave The sides of the guide profiles are turned away from the direction of rotation, so these profiles are or the guiding devices of the liquid surrounding them in that shown in FIG. 1 Way flows around. Form the liquid threads lying closest to the guide profile b a vacuole V, inside the z. B. on the hollow shaft al, the hub a and whose extension a 'through the outlet opening c inflowing gas to the outside moved. Thereby the gas partly already through the vacuole liquid flowing around it dissolved in small bubbles, but essentially only in the The pigtail of the vacuole is crushed into the finest bubbles and mixed with the surrounding fluid mixed.

Should be the amount of gas to be distributed in the liquid at each appropriate power consumption can be varied, the vertical height (so-called Shadow area) of the guide device b generating the vacuole according to FIG. 5 adjustable be set up, for example by making the guide device from two axially symmetrical parts' and b "is produced, which are pivotable about a common hinge axis x.

Even more perfect can the finest distribution of any within further limits of the variable amount of gas in the device according to FIGS. 6 and 7 are achieved will.

6 and 7 are in rotation with that of the axis a1 or a2 offset hollow body a, a 'rod-like arms bl made of resistant material rigid tied together. These arms carry on their front side lying in the direction of rotation elastically deformable wing-like components d, which in the rest state a flat Cross-section according to FIG. 8 a, in the operating state, however, a concavely curved shape have according to Fig. 8b. If this device is set in rotation via the hollow shaft a1, so the elastic wing d is deformed according to the difference between the two Side pressures acting on him. The wing d therefore takes in the liquid those indicated in Fig. 9a (or for an increased gas throughput in Fig. 9b), concave deformed or channel-like shape. The liquid layers are starting from the upstream side, diverted and close at some distance again to some extent. So there is a vacuole V. The height and The length of this vacuole V depends on the amount of gas flowing through the vacuole addicted.

The wing d can be made of rubber or plastic of appropriate elasticity or consist of a thin sheet of metal. If the wing d is made of metal, e.g. B. made of thin leaf spring steel, it is useful with a chemical against Attacks resistant cladding made of rubber, plastic or the like. Provided. The two long side edges of this cladding can then be used as the "backbone" the steel insert (leaf spring) forming the guide surface to reach a larger To achieve flexibility of the wing.

Has one otherwise especially with regard to its resilience against chemical influences Suitable building material has too little resistance against bending, so he can by a resilient device, whose clamping force if necessary can be adjustable, can be made usable for the present purpose.

Claims (6)

PATENT CLAIMS: 1. Device for the finest distribution of gases in liquids with the help of radial to an at least approximately vertical axis of rotation arranged rotating guiding devices, which on the opposite of the direction of rotation Form side open cavities, characterized in that the guide devices essentially over its entire radial length as a single, continuous back open grooves are formed and rotate at such a high speed that on elongated vacuoles in the liquid on the back of the guide devices develop. 2. Apparatus according to claim 1, characterized in that the channel-like Guide devices on a hub which is hollow in a known manner for gas supply are attached, the radially inner channel ends directly into the hub flow out. 3. Apparatus according to claim 1 or 2, characterized in that each channel-like guide device in the longitudinal direction into two parts (b ', b "in Fig. 5), which can be pivoted about a common axis (x), so that the profile height the guide device is changeable. 4. Apparatus according to claim 1, characterized in that each Guide device (l by a support arm (b1 in Figs. 6 to 9) is formed, the a wing-like, elastically deformable plate (d) carries, which is rotated deformed like a channel in the liquid. 5. Apparatus according to claim 4, characterized in that the plate (d) from a metallic reinforcement insert with one above this if necessary protruding cladding made of rubber, plastic or the like. Is. 6. Device according to one of claims 1 and 3 to 5, characterized in that that outside the rotating channel-like guide device in the liquid a known device for supplying coarse gas bubbles to the liquid is provided. References considered: U.S. Patents No. 1,579 355, 2,187,746.