DE2513917A1 - MIXING DEVICE - Google Patents

Description

GENERAL SIGNAL CORPORATION

280 Park Avenue

New York, Nev York «Y, St, A.

Our reference: G 1364

Mixing device

The invention relates to a device for mixing liquid and gas, especially for adding oxygen to industrial waste or sewage, which has a biochemical Have oxygen demand (B0D = biochemical oxygen demand). Mixers treat BOD-containing wastewater in the same way as urban ones Wastewater, biochemically by adding oxygen. This is usually done with the help of a sprinkler ring below of a propeller in a tank. The propeller circulates the wastewater, and the sprinkler ring carries oxygen into the tank, which is to be admixed, see U.S. Patents 3,227,701 and 3,547,813.

In a known biochemical oxidation process that is Wastewater mixed with an oxygen-containing gas such as air and a Paul sludge. The latter essentially consists from aerobic organisms that have the ability in the presence to absorb the biochemically oxidizable organic material of the urban sewage from adequately distributed oxygen and can assimilate and thereby transform the organic material so that it is easily separated from the purified water can be. Under normal conditions they multiply

509841/0899

-2-

Bacteria settle in the aeration tanks during this process step. When the required time for BOD conversion has passed if the mixed liquid is allowed to stand and settle, the purified drainage water is decanted into receiving water and removes the digested sludge from the bottom of the sewage treatment plant.

It has already been pointed out that the use of Sprinkler rings for supplying oxygen-containing gas to the wastewater is known. The sprinkler ring is below a circulating propeller arranged so that the admixed gas migrates to the suction side of the propeller. The propeller rotates generally at a fixed rate. If gas is introduced into the tank via the sprinkler ring, it is for the Rotation of the propeller requires a power that is referred to as liquid-gas power. When the tank is over If no gas is supplied to the sprinkler ring, a power is required for the rotation of the propeller, which is pure liquid power referred to as. The ratio of the liquid capacity to the liquid-gas capacity is given as the K-factor known. In general, the K-factor is quite small because the system uses more power if no gas is added, because for the rotation of the propeller in a liquid a larger one Torque is required than to rotate the propeller in a gas. This is why the engine can suffer damage if it is designed for a propeller that is to work with a predetermined liquid-gas power and if someone happens to be turns off the gas supply and the power consumed increases.

According to the invention a device for mixing liquid and gas can be created, which can work both with gas supply and without gas supply, without overloading of the engine can occur; this device is said to have a high

-3-5QS841 / 0899

Performance work so that the mass transport speed increases will.

This task is in devices for mixing liquid and gas, with a liquid tank, a device for introducing solved by gas and a circulation device in that the device for introducing gas is designed so that they only outside the suction side of the gas circulation device introduces and the latter experiences only the fluid resistance.

According to the invention the device mixes liquid and gas in a vessel, for example a tank. A circulation device, e.g. a submerged propeller, is driven by a motor and circulates the liquid in the tank. A sprinkler ring leads the gas in the tank. This sprinkler ring is arranged below the propeller and has gas supply means, e.g. a number of holes arranged on its top. The gas supply devices are arranged so that the supplied Gas cannot get into the suction area of the propeller and ensures a high mass transport speed is.

The invention is described below on the basis of an exemplary embodiment and described in more detail in connection with the drawing. Show it

1 shows a cross section through a mixing device according to the invention,

Fig. 2 is a bottom view of a propeller of the invention,

3 is a plan view of a sprinkler ring according to the invention and

Fig. 4 is a cross section showing the ratio of the sprinkler ring illustrated to the propeller.

509841/0899 _ ₄ _

As can be seen in Fig. 1, an apparatus mixes a liquid L with gas G. The apparatus comprises a tank 10 which Contains liquid L. A device 20 circulates the liquid L in the tank 10. An admixture or sprinkler ring leads the gas outside the suction area 21 of the circulation device 20 a, so that the circulation device 20 is only exposed to the fluid resistance.

In Fig. 1 a device according to the invention is in cross section shown. This device comprises a tank 10 with side walls 12, with a front and a rear wall (not shown) and a base 14. The tank is generally composed of Concrete. An inlet port 16 leads the liquid L, e.g., municipal sewage, into the tank 10. Further, there is an outlet port 18 provided, through which the liquid can be conducted to a further device, e.g. to a sewage treatment plant, after the liquid has been oxygenated.

The circulation device 20 can have any suitable mixer be an idler, preferably with a curved blade propeller, such as model no. 89Q125, which is used by the Mixing Equipment Company, Rochester, New York. The circulator includes a motor 22, e.g. Induction motor with an output of 125 HP, which turns a drive shaft 24. At the lower end of the drive shaft 24 is a collar 26 is formed, which with a plurality of screws, two of which are shown at 30 in FIG. 4, on a washer 28 is attached. The propeller or turbine blades 32 are with rigidly attached to the disk 28 by suitable means, such as screws or welded connections (not shown). Fig. 2 shows a bottom view of the disc 28 with attached propeller or Turbine blades 32. The drive shaft 24, the disk 28

-5-509841 / 0899

and sheets 32 may be made from "any suitable material be made, e.g. of stainless or galvanized steel. The blades 32 are aligned on the disc 28 so that that the liquid L circulates essentially radially when it leaves the propeller blades. In the exemplary embodiment was a TJmwälzeinrichtung 20 immersed from above is shown, it however, it is also possible to use a circulation device that is immersed from the bottom. Stabilizing rings can also be used or devices, which are not shown, are used to limit the radial movement of the shaft.

As can be seen in Figure 1, a gas is supplied to the tank 10 via an admixture or sprinkler ring 40 which is attached to the tank 10 by suitable means such as brackets (not shown) which in turn are attached to the base 14. The gas is fed to the sprinkler ring 40 with a pump 36 via a gas line 38. The gas As seen from Fig. 1, passes from the gas line 3 ⁸ in a hollow ring 41 of the Kaminer Sprenklerrings 40 and leaves this through a set of apertures 42 in the top 43 of the Sprenklerrings 40.

It was previously common to place the sprinkler ring under the propeller blades to be attached so that the gas from the sprinkler ring reaches the suction area of the leaves. This will increase the density of the Medium which is to be circulated or circulated by the leaves is reduced. This medium with lower density sets the Rotation of the leaves counteracts less resistance. Because the power of the engine is proportional to the rotation of the propeller depending on the resistance of the medium, the motor draws less power when gas is released into the suction area of the leaves will. This may seem desirable, except for the fact that the rate of mass transport is changing with that of the power consumed by the engine decreases.

-6-509841 / 0899

· »Ο · ■

According to the invention, the sprinkler ring introduces gas outside the suction area of the leaves, so that the leaves only experience the resistance of the liquid. This is achieved in that the sprinkler ring is arranged so that it emits gas only within a volume V, which is shown in Fig. 4 by dashed lines. The yolumen V comprises a ring with a radial dimension a and an axial dimension b. The radial dimension a extends from 1 to 1.5 times the diameter Dt of the blades. The axial dimension b extends downward from the disk 28 approximately a distance corresponding to the height of the blades 32. As long as gas is introduced into volume V, it cannot get into the suction area of the leaves. FIG. 4 shows this relationship for the sprinkler ring 40 ^f , but it is pointed out that this principle can also be used for other sprinkler rings, for example that of FIG. 1. The diameter Ds of the sprinkler ring is approximately 1 at the opening. 2 times the diameter Dt of the turbine blades, so the gas is introduced at this location.

The diameter Ds is assumed in this description to be an imaginary circle which is from the radially innermost point each Opening of a group of openings is formed, such as the imaginary circle C for openings 42 '. The diameter Dt, which is in hereinafter referred to as the diameter of the leaves is actually the diameter of a circle which is defined by the outer Tips of rotating blades is formed. By arranging the openings or holes radially outside the turbine blades When they rotate, they only experience the resistance of the liquid. More power is drawn and therefore the Mass transport speed increased. If gas is introduced in the radial direction outside the volume V, the decreases Mass transport speed considerably.

-7-509841 / 0899

If gas is introduced above the volume V, the mass transport rate decreases. Palis gas is introduced below the volume Ύ , it can drift into the suction area of the blades and reduce the power drawn. The gas is preferably introduced approximately in the center of the blades (axially) for the best mass transport.

Fig. 3 shows a plan view of a modified admixture or sprinkler ring 40 '. This ring 40 'is different differs from ring 40 in that it has two sets of holes. A first group of holes 42 'is on the top 43 'of Sprenklerringeε 40' arranged. A second group of Openings 44 'is also arranged on the top 43'. The second group of holes is arranged radially outside the first group. Each group of holes lies on a circle on top of the sprinkler ring, but this is only a matter of simplicity, what matters is that the gas from the Suction area of the propeller blades 32 is directed away.

From Fig. 4 the arrangement of two groups of holes becomes particular clear. The sprinkler ring 40 'contains an annular divider 46 which divides the interior of the ring into two different, hollow sections 41 'and 41 "are divided. A gas can be divided into one of these hollow chambers or both chambers can be inserted. If the inner hollow chamber 4I 'is used, this will be Gas is released into the tank through holes 42 '. If the outer hollow chamber 41 "is used, the gas is discharged through holes 44 ' discharged into the tank. In this way it is possible to change the diameter Ds from Ds (1) to Ds (2), depending on which one Chamber 4I 'or 41 "via line 38 gas is supplied.

It should be noted that an annular slot (or slots) may be used in place of a group of openings

-8-509841 / 0899

can. In addition, while it is easy to use a rectangular cross-section sprinkler ring, it can also be a Hung can be used with any cross-section. Furthermore It is also possible to use a split sprinkler ring to mix one or more gases with the liquid.

example

A rectangular tank about 11.5 x 12.5 m and about 9 m deep contains about 6 m of water. A 125 horsepower induction motor rotates a steel disk at a speed of at least 100 rpm. Each blade has a radius of curvature of about 6 cm, and each blade is inclined at approximately 55 degrees from the radial line from the outer edge of the blade. A gas is at a flow rate of about 85 m / min. fed by a sprinkler ring, the diameter Ds of which is approximately 2.1 m. This diameter Ds has about 24 holes, each about 1.9 cm in diameter and with a pressure drop of about 105 g / cm. The top of the sprinkler ring is about 1.5 cm below the disc. The power drawn when gas was introduced is about 93 »5 HP, while without gas a power of about 9115 HP is drawn, which results in a K-factor of about 1.02.

-9-

509841/0899

Claims (12)

Expectations M.) Device for mixing liquid and gas, with one Liquid tank, a device for introducing gas and a circulation device, characterized in that the device for introducing gas is designed so that it is only outside the suction side of the circulation device Introduces gas and the latter experiences only the liquid resistance. 2. Apparatus according to claim 1, characterized in that the Circulation device comprises a plurality of rotating blades which are immersed in the liquid. 3. Apparatus according to claim 2, characterized in that the blades generate a radial flow. 4 · Device according to one of claims 1 to 3 »characterized in that that the device for introducing gas includes a sprinkler ring. 5. Apparatus according to claim 4 »characterized in that the sprinkler ring is hollow and on its top a number of Has holes which communicate with the cavity. 6. Device according to one of claims 1 to 5 »characterized in that that the sprinkler ring introduces gas at a location which is about 1 to 1.5 times the diameter of the leaves. 7 · Device according to claim 6, characterized in that the sprinkler ring introduces gas at a location about 1.2 times the diameter of the leaves. -10- 509841/0899 8. Device according to one of claims 2 to 5 »characterized in that that the sprinkler ring has 1 to 1.5 times the diameter of the leaves at its holes. 9 · Device according to claim 8, characterized in that the diameter of the sprinkler ring is approximately 1.2 times the Diameter of the leaves. 10. Device according to one of claims 1 to S _1, characterized in that the sprinkler ring introduces gas at a location which coincides with the axial location of the blades. 11. The device according to claim 10, characterized in that the sprinkler ring gas approximately in the axial center of the blades introduces. 12. Device according to one of claims 1 to 11, characterized in that that the leaves are mounted on a rotating disk and the top of the sprinkler ring about in the axial center of the blades is arranged. 509841/0899