JPH0199693A - Aeration device - Google Patents

Abstract

PURPOSE:To prolong the convection time of air bubbles in in-tank liquid and to enhance the efficiency of dissolution of gas in the liquid by mounting a dispersion plate for dispersing and injecting the gas-liquid mixed liquid mixed in a static mixer part to two flows directed in a diagonal upward direction to the top end of a body pipe. CONSTITUTION:The gas introduced into the body pipe 20 from a gas introducing port 22 in the lower part thereof is risen by buoyance in the pipe 20. The liquid in the tank is sucked by the air lift effect generated by the rise of the gas from a liquid introducing port 24 provided in the lower part of the pipe 20 and the rising flow of the gas-liquid mixed liquid is induced in the pipe 20. The rising air bubbles are finely segmented by the static mixer part 26 disposed in this pipe 20 by which the mixing and dissolving are accelerated. The gas- liquid mixed liquid is injected diagonally upward from an ejection port 42 provided in the lower part of the two slopes 40a of the diffusion plate disposed to close the top end of the pipe 20 by which the liquid is dispersed to the two flows along the slopes 40a. As a result, the efficiency of dissolution of the gas into the fluid is increased.

Description

DETAILED DESCRIPTION OF THE INVENTION [Field of Industrial Application] The present invention relates to an aeration device for dissolving a gas, such as oxygen, in a liquid, and in particular to modifying its dissolution properties.

[Prior Art] Various aeration devices such as aeration tanks for sewage treatment facilities have been proposed.

For example, there are air diffusers, disk differential users, dome differential users, etc. that blow gas into the liquid as small bubbles, and other types that use ejectors that eject a gas-liquid mixture. There are also surface alating machines, etc.

It is also known that a static mixer is placed above the gas inlet to break up the introduced air bubbles.

[Problems to be Solved by the Invention] In such conventional aeration devices, gas dissolution efficiency increases when the diameter of the bubbles blown into the liquid is reduced; In addition, increasing the diameter of the bubbles eliminates the problem of clogging, but there is a problem in that the gas dissolution efficiency deteriorates.

In addition, if a static mixer is installed at the gas inlet, it is possible to finely divide the gas and improve the gas dissolution efficiency to some extent without clogging the gas inlet. Because the air bubbles escape straight upwards,
Its gas dissolution efficiency was not sufficient.

The present invention was made to solve such problems, and by providing a dispersion plate of a predetermined shape above a static mixer and distributing and ejecting a gas-liquid mixture,
It is an object of the present invention to provide an aeration device that provides sufficient stirring and gas dissolution efficiency.

[Means for Solving the Problems] The aeration device according to the present invention includes a main body pipe disposed in a substantially vertical direction in a tank containing a liquid, a gas inlet provided at the bottom of the main body pipe, and a liquid inlet. an inlet; a static mixer section provided in the main body pipe that regulates the flow of liquid and gas introduced from the liquid inlet and the gas inlet and promotes the mixing; and blocking the upper end of the main body pipe. The main body pipe has a diffusion plate having two slopes arranged so as to rise toward the sides, and two spout ports respectively provided below the two slopes of the diffusion plate of the main body pipe. It is characterized in that the gas-liquid mixture is ejected diagonally upward from the two ejection ports.

[Operation] The gas introduced from the gas inlet rises in the upper part of the housing due to buoyancy. Then, due to the air lift effect caused by the rise of this gas, the liquid in the tank is sucked from the liquid inlet, and an upward flow of the gas-liquid mixture is generated in the housing. Further, a static mixer is arranged within the housing. For this reason, the bubbles rising here are fragmented and mixing and dissolution is promoted.

Here, in the present invention, a diffusion plate having two slopes rising laterally is provided at the upper end of the housing. A spout is provided below each of these two slopes. Therefore, the gas-liquid mixture rising inside the housing is dispersed into two flows along these two slopes, and a horizontal flow velocity is imparted to the gas-liquid mixture. As a result, the convection time of the bubbles in the liquid within the tank becomes longer, and the inside of the tank can be effectively stirred.

[Example] An example of an aeration device according to the present invention will be described based on the drawings.

FIG. 4 shows the installed state of the aeration device 100 of this embodiment.

The aeration device 100 is fixed at the center bottom of a tank 10 such as an aeration tank for activated sludge treatment, for example. And this aeration device 10
Air from a blower 14 is supplied to the lower part of the 0 via an air pipe 12.

Next, this aeration device will be explained based on FIG. 1.

The main body pipe 20 is arranged vertically within t111i10. It may be placed and fixed on the bottom of the tank, or it may be supported by a separate guide pipe or the like.

A gas inlet 22 is provided at the lower part of the main body pipe 20, from which gas is ejected S0, and this gas rises within the main body pipe 20, but the lower end of the main body pipe 20 is connected to a liquid inlet Since the pipe 24 is open, the liquid in the tank 10 is sucked in by the air lift effect and rises inside the main pipe 20 as a gas-liquid mixture.

Here, a static mixer section 26 is formed within this main body pipe 20. The static mixer section 2B includes a number of rod-shaped bodies 30 that protrude from the inner surface of the main body pipe 20 toward the center.

In other words, as shown in FIG. 2, the rod-shaped body 30 has a shape similar to that of a cylinder with one part cut off so that the -L plane is flat.

The rod-shaped body 30 has a base portion 30a that is cylindrical and perpendicular to the main body pipe 20, a tip portion 30b that extends obliquely upward through the center, and a distal end portion 30b that extends diagonally upward through the center. It consists of a flange portion 30c for fixing to. Note that FIG. 2A is a cross-sectional view taken along line XX in FIG. 2B.

Such a static mixer section 2δ has a main body pipe 2.
It is preferable to form a hole with a diameter slightly larger than the U portion 30b in the hole, insert the rod-shaped body 3o into the hole, and attach the base portion 30a and the flange portion 30c to the main body pipe 20.

The static mixer section 26 is formed so that these rod-like bodies 30 are shifted by 45 degrees when viewed from the axial direction, so that the whole has a spiral shape. It looks like a spiral passage separated by An example of the arrangement position of such a rod-shaped body 3o is indicated by a circle in FIG.

According to such a static mixer 26, the rod-shaped body 3
0 faces diagonally upward, and because it is cylindrical, there is very little risk of dirt getting caught in it, and the tip 30
Since the thickness of c is small, interference with the neighboring rod-shaped bodies 30 is less likely to occur, and the rod-shaped bodies 30 can be arranged with high density, thereby increasing gas dissolution efficiency and rate.

Then, at one end of the main body pipe 20, the pipes 40 are distributed in such a manner as to close this end. This dispersion plate 40
When viewed from the front, it has a V-shape as shown in FIG. 1, and when viewed from the side, it has a circular shape as shown in FIG. 3. In other words, the dispersion plate 40 has a shape in which a circular plate is bent at a predetermined angle with a line passing through the center as the weave. In this example, the smaller angle, or apex angle, is 120
It is formed to approximately the same degree.

This dispersion plate 40 is fixed to the upper end of the main body pipe 20 so that its center portion (textured portion) protrudes downward. Therefore, two slopes 40a rising laterally are formed on the lower side of the dispersion plate. Further, two spout ports 42 are provided in the second part of the main body pipe 20 below this slope 40a, corresponding to this slope.

A gas inlet 22 is provided in such an aeration device 100.
When more gas is ejected, the bubbles are subdivided by the static mixer section 26 and ejected obliquely upward from the 11r1 outlet 42 as a gas-liquid mixture. Therefore, the gas and liquid ejected from here have a horizontal flow velocity,
Overall, the convection time of the bubbles in the liquid increases and the efficiency of dissolving gases, such as oxygen, increases.

Further, since the dispersion plate has two slopes 40a, dirt does not become entangled with the dispersion plate 40 or the upper end of the main body pipe 20 supporting the dispersion plate 40, thereby preventing clogging.

Here, it is important that this dispersion plate 40 has two slopes 40a facing diagonally upward. In an experiment in which the dispersion plate 40 was simply a horizontal plate, the air bubbles would be hard to collide with each other and become coarse, resulting in poor dissolution efficiency. Furthermore, if the water is dispersed in three or more directions, the dirt will get stuck in the vicinity of the spout 42, causing a blockage. Further, in this case, there is also the problem that it becomes difficult to manufacture the 4° dispersion plate.

According to experimental results, in some rare cases, when the dispersion plate 40 was attached, there was a difference of more than 10% in dissolution efficiency, although it depended on the gas supply meter.

FIG. 4 shows another embodiment of the aeration device of the present invention. In this example, the main body pipe 20 is fixed to the air pipe 12, and the entire aeration device 100 can be pulled up together with the air pipe 12.

[Effects of the Invention] As described in 2 below, according to the aeration device of the present invention, the gas-liquid mixture effectively mixed by the static mixer part is dispersed to form two flows diagonally upward. , it is possible to perform sufficient stirring and also ensure sufficient gas dissolution efficiency.

[Brief explanation of the drawing]

FIG. 1 is a partial cross-sectional front view of an aeration device 100 in the same embodiment, FIG. 2 is a configuration diagram showing the configuration of a static mixer 30 in the same embodiment, and FIG. 3 is a diagram showing the installation of the dispersion temporary 40 in the same embodiment. FIG. 4 is a schematic diagram showing the installed state of one embodiment of the aeration device 100 according to the present invention. FIG. 5 is a side view showing another embodiment of the aeration device 100 of the present invention. 20... Body pipe 22... Gas inlet 24... Liquid inlet 26... Static filter section 40... Dispersion plate 40a... Slope 42... Spout port

Claims (2)

[Claims] (1) A main body pipe arranged almost vertically in a tank containing a liquid; A gas inlet and a liquid inlet provided in the lower part of the main body pipe; and a main body pipe provided in the main body pipe for introducing the liquid. A static mixer part that regulates the flow of liquid and gas introduced from the mouth and gas inlet and promotes the mixing; and two parts that are arranged to close the upper end of the main body pipe and rise laterally It has a diffuser plate having a sloped shape, and two spout ports respectively provided below the two slopes of the diffuser plate of the main body pipe, and the gas-liquid mixture is directed diagonally upward from the two spout ports. An aeration device that emits water toward. (2) The aeration device according to claim 1, wherein the static mixer has a plurality of rod-shaped bodies arranged in a spiral manner and project obliquely upward from the inner surface of the main body pipe.