HU192008B - Device for uniflow or counterflow mixing fluids and gases - Google Patents

Abstract

Appts. comprises a drive unit, shaft extending into the liquid and pump impellers attached to the shaft. The shaft is surrounded by an inner suction tube. The suction side of one of the impellers is fitted near one end of the inner suction tube. The other end of this tube is in contact with the medium which is to be mixed in. The inner suction tube is located inside an outer suction tube. - The suction side of the second pump impeller is fitted near one end of the outer suction tube, the same end as that of the inner suction tube which is fitted with a pump impeller. The other end of the outer suction tube is in contact with the liquid surrounding it.

Description

(54) Equipment for mixing liquids and gases in direct current or in countercurrent flow (57)

The invention relates to a device for mixing liquids in a direct current or in a countercurrent flow with a gear unit (1), a fluid projecting shaft (3) and pump impellers (4, 5) mounted on the shaft, the shaft (3) being surrounded by an internal suction tube (6) one end of which is fitted with the suction side (25) of one of the pump impellers (4) and the other end of which is in contact only with the medium to be mixed, the inner suction tube (6) being surrounded by a second external suction tube (7) 6) the suction side (26) of the second water pump impeller (5) is fitted to its end in the same position as the mating pump impeller (4) and the other end is in communication with the surrounding fluid.

The invention relates to an apparatus which can be used for mixing liquids and / or gases into liquids by a DC or a countercurrent mixing method.

It is also suitable for mixing equipment slurries and for venting unwanted gases.

Many devices have been developed for mixing liquids and for introducing gas into liquids.

No. 961,795. For example, US Patent No. 5,198 discloses a self-priming aeration device based on the principle of propelling the impeller by means of an upwardly hollow shaft, which is also an air-intake duct. In this solution, the drive motor is located at the top, outside the tank.

A similar technical solution is found in U.S. Pat. No. 168,516. This mixing is performed by a hollow impeller formed by 4-8 paddles rotating about a vertical axis about the bottom of the tank. The paddles have air outlets on the side opposite to the direction of rotation, and they are at an acute angle with the radial planes on its vertices. The apparatus further comprises a stator located at least twelve, fixed between two flat rings, and having stator blades at different angles to the radial direction. The paddle wheel la is mounted on a downward axis of a diving motor and is connected downstream by an air duct fixed by a labyrinth seal, and the stator is mounted by spacer pins on the flange of the diving motor and is mounted on the entire device by means of distance screws.

These devices are suitable for handling liquids in a sealed container and only for one-way flow manipulation.

Another solution is disclosed in U.S. Patent No. 176,363. U.S. Patent No. 4,123,123, which relates to a device for rotating liquids and for introducing gas into a liquid. The apparatus comprises a chamber consisting of two downwardly expanding screw-shaped surfaces. They are V-shaped and the apex of the V-shape is directed outwards. Since the screw-shaped blade has the highest circumferential velocity at the smallest outlet cross-section, the greatest amount of air is added at high speed to the outer edge of the drive means, whereby air can flow into the outer sections of the fluid reservoir. A very large amount of air can be introduced if the radial upper and lower edges intersect at the outlet and if the lower edge extends beyond the half edge in the outer section (as viewed in the axial direction of the hollow shaft).

This unit delivers very large amounts of air or gas into the liquid but is not designed for countercurrent operation.

It is an object of the present invention to provide an apparatus suitable for direct current and counter current mixing, operating at high efficiency and eliminating the drawbacks of known devices.

The present invention is based on the fact that, by using friction on the surface of bubbles, the bubbles can be kept in the liquid for a relatively long period of time, thereby promoting a substantially perfect? \ tes mixing and absorption.

The invention thus relates to an apparatus for mixing liquids and gases directly or indirectly with a gear, a shaft extending to the shaft and pump impellers mounted on the shaft, the shaft being surrounded by a known internal suction pipe having a suction side on one pump impeller the inner suction pipe is surrounded by a second external suction pipe, the end of which is in the same position as the pump impeller fitted to the inner suction pipe and the other end is in communication with the surrounding liquid.

In a preferred embodiment of the device according to the invention, the suction impeller at the end of the inner suction pipe has a deflector on its opposite side to the suction side,

In another preferred embodiment of the device according to the invention, an injector insert is incorporated into the outer suction tube at the pump impeller at the end of the inner suction tube.

DETAILED DESCRIPTION OF THE INVENTION In some embodiments, the invention will be understood from the accompanying drawings, in which:

Figure 2 is a sketch of an apparatus,

Figure 2 shows a schematic detail of a device with an injector insert.

The apparatus shown in FIG. 1 is primarily designed for mixing gases into liquids, but also for mixing liquids. The gear 1 is mounted on the lid 10 of the container 9 of the device, the axis of which is connected by a coupling 2 to the axis 3 of the device.

The shaft 3 is suspended by a sealed bearing 22 in a properly formed part of the lid 10 and extends into the container 9 where the pump impellers 4 and 5 are wedged.

The shaft 3 is surrounded by the inner suction pipe 6 between the cover 10 and the pump impeller 4 closer to it. The inner suction pipe 6 is completely closed and its upper end is secured to the lid 10, whereby the inlet means 11 and 11 are provided for the introduction of the media to be mixed. It has 12 valves that can be closed.

The suction side 25 of the pump impeller 4 is fitted to the lower end of the inner suction tube 6. To the opposite side of the pump impeller 4, a deflector 23 is attached to the shaft 3.

The inner suction tube 6 is surrounded by a second outer suction tube 7 which is secured to the inner suction tube 6 by means of brackets 8. The upper end of the outer suction pipe 7 does not reach the lid 10, but is flushed out.

The suction side 26 of the pump impeller 5 wedged at the end of the shaft 3 is fitted to the lower end of the outer suction pipe 7.

At the bottom of the container 9 there is an inlet nozzle 27 with a valve 19, and in the lid 10 there is a gas outlet nozzle 28 with a valve 21. The operation of the equipment is as follows.

The container 9 is filled with the liquid into which the other medium, liquid or gaseous, is to be mixed. The gear unit 1 is then started, so that the suction effect of the pump impellers 4 and 5 becomes effective. Since the tank 9 is filled so that the liquid covers the upper end of the outer suction pipe 7.

-2192.008, the pump impeller starts to circulate fluids through the outer suction pipe 7 in the direction of arrows 18 and 17.

When the valve 12 for the introduction of the medium to be mixed, such as gas, is opened, the pump impeller 4 draws gas through the inner suction pipe 6 and pushes it into the space between the inner and outer suction pipes 6, respectively.

At this point, the outlet gas on the discharge side of the pump impeller 4 encounters the flow paths from the arrow 16. The gas bubbles are thus affected by impulse and buoyancy.

The magnitude of the impulse force depends on the density of the fluid flowing, the relative velocity between the bubbles and the fluid, the diameter of the bubbles, and a proportional factor depending on a Reynolds number. The size of the felhaj- ^'he force is dependent on the density of the bubbles and the liquid flowing átmérjőtől. The density of the gas at first approximation to that of the liquid is negligible.

The direction and speed of movement of the gas bubbles are determined by the sum of the two forces. Thus, the device 20 can be scaled in three ways, with each bubble moving down or up, or the bubbles flowing in two directions. To do this, you need to change the flow rates, the flow pattern, and the size of the bubbles. All this can be achieved by sizing and designing the pump impellers 4 and 5 and the inner suction pipe 6 and outer suction pipe 7 25, as well as by the appropriate choice of speed.

When the gas bubbles travel downward in the direction of the nozzle 16, the advantageous new condition is that the pump impeller 5 sucks down with the flowing fluid and then shakes the gas bubbles, and since the pump impeller 5 provides intense torque. Composition - the gas bubbles stop and, as a result of the buoyancy force, travel upwardly along the helix between the wall of the container 9 and the outer suction pipe 7. In this way, the gas to be mixed is in intense contact with the liquid over a large surface and over a long distance, promoting the desired purpose, mixing and absorption.

If the gas bubbles travel upward in the direction of arrow 15, they will meet or mix upstream of the liquid coming from arrow 17. Although the absolute velocity of the bubbles in this case is relatively lower, their relative velocity is still high relative to the liquid, and thus the bubbles are disintegrated by the frictional force on their surface and the impulse force acting on them. It is a fact that in this case the distance traveled is relatively short, but due to their lower absolute velocity their residence time in the liquid is longer. The larger contact area and longer residence time facilitate mixing and absorption.

When the mixing process is completed, the container 9 can be emptied through the drain nozzle 27 by opening the valve 19. Unabsorbed gases above the liquid can be discharged through the gas outlet 28 by opening the valve 21.

Fig. 2 shows another design of the portion of the outer suction tube 7 at the pump impeller 4. A suitably sized injection insert 29 is disposed opposite the pump impeller 4.

In such a device, the flow of fluid created by the pump impeller 5 creates an injector effect which facilitates the suction of gas from the inner suction pipe 6.

The apparatus according to the invention can simultaneously mix several gases. This is indicated by the two pipelines with valves 11 and 12 in FIG. Of course, more than two separate inlets can be provided. The device is equally capable of mixing liquids. For example, in the case of water treatment, the necessary chemicals can be introduced and intimately mixed without separate metering pumps.

A further advantage of the device is that the pump impeller 5, by placing the upper end of the outer suction tube 7 at a sufficient distance below the liquid level, sucks the foam from the surface of the liquid. This is particularly advantageous in the case of aeration of wastewater - purification of biology.

Claims

Claims (2)

1. Equipment for DC cutting of liquids and gases · For countercurrent mixing with a gear unit (1), a shaft extending into the liquid (3) and pump impellers (4, 5) fixed to the shaft, z. characterized in that the shaft (3) is surrounded by an internal suction tube (6) known per se, one end of which is fitted with the suction side (25) of one of the pump impellers (4) and the other is connected only to the medium to be swept, the inner suction pipe (6) being surrounded by a second external suction pipe (7), the end of which is in the same position as the pump impeller (4) fitting the inner suction pipe (6), the suction side (26) of the second pump impeller (5) the other end is in contact with the fluid around it. Apparatus according to claim 1, characterized in that the pump impeller (4) at the end of the inner suction pipe (6) has a deflector (23) on the side opposite to the suction side (25). Apparatus according to claim 1 or 2, characterized in that a tip is provided with an injector insert (29) at the end of the inner suction tube (6) at the pump impeller (4) at the end of the inner suction tube (7). 2 pieces of figure National Office of Invention F.k,: Zoltán Himer Code " -3192.008 International Class Number: B01 F at 5/16 feet