KR20120028065A - The micro jet pump for wastewater treatment - Google Patents

Abstract

PURPOSE: A micro-jet pump for treating wastewater is provided to expand the retention time of gas in water by miniaturizing the bubble of the gas and facilitating the dissolution of oxygen. CONSTITUTION: A micro-jet pump for treating wastewater includes a pumping unit(100), a venturi pipe(200), an inline mixer(300), and a spiral protrusion pipe(400). The pumping unit supplies fluid of high speed. The venturi pipe is in connection with the pumping unit. The fluid passes through the venturi pipe, and the venturi pipe sucks air. The inline mixer is combined with the rear part of the venturi pipe and stirs the fluid and the air to be uniformly treated. The spiral protrusion pipe is in connection with the rear part of the in line mixer. A plurality of protrusions(410) is spirally arranged at the spiral protrusion pipe.

Description

The micro jet pump for wastewater treatment

The present invention relates to a jet aeration apparatus for wastewater treatment, and provides an inline mixer and a spiral protrusion in a venturi structure, and has excellent stirring ability and maximizes oxygen transfer rate.

In general, fluids containing a large amount of various foreign substances such as livestock manure, industrial sludge, environmental wastewater, etc. are mostly organic materials and are discharged untreated or introduced into sewage treatment plants. Has become a source of pollution that lacks dissolved oxygen.

In order to prevent this phenomenon, a method of treating manure harmlessly by actively decomposing organic matter into microorganisms by supplying oxygen in a reaction tank has been widely used.

In this case, a jet aeration pump is conventionally used as a means for supplying oxygen.

However, the conventional jet aeration pump has only a venturi tube or a nozzle attached to the structure mainly performing gas-liquid mixing, and has a limitation in promoting aerobic fermentation due to short diffusion and residence time of air particles.

And it was difficult to achieve efficient stirring, there was a problem that the oxygen and the oxygen transfer rate is not completely mixed with the liquid.

The present invention has been made in order to solve the above problems, by installing the in-line mixer and the spiral projection in the venturi structure for mixing the gas-liquid inside the in-line mixer with a perfect mixing through the stirring action of the gas-liquid In the projection of the micro-aluminum aeration system for wastewater treatment, the gas-liquid mixture is finely decomposed to reduce the film-resistance resistance between the gas and the liquid. Its purpose is to.

In order to achieve the above object, the wastewater treatment micro jet aeration apparatus of the present invention comprises: pumping means for supplying a high speed fluid; A venturi tube connected to the pumping means and sucking air on a venturi principle while the fluid passes therethrough; An inline mixer coupled to the rear end of the venturi tube and uniformly agitating the mixed fluid and air in the venturi tube; and an inline mixer connected to the rear end of the inline mixer, wherein a plurality of protrusions are spirally arranged in the tube. And spiral helix organs that induce vortices.

Here, the protrusion is formed in a fan shape, it is preferable to form a plurality of spiral flow paths along the inner peripheral surface.

 In addition, it is preferable that the protrusion part is arranged to have a relatively large protrusion part and a small protrusion part intersecting each other.

And, it is preferable to further include a level sensor for detecting a change in the level of the fluid, and a control box for controlling the driving of the pump means when the level of the fluid is higher than the set value.

      In addition, it is preferable that an air suction port is installed at a neck portion of which the diameter of the venturi tube is reduced.

According to the present invention having the above configuration, the following effects can be expected.

According to the present invention, the mixing between the gas and the liquid is performed simultaneously with the mixing of the gas and the liquid, and the mixing between the gas and the liquid is well performed and the stirring ability is improved.

As the gas-liquid mixed liquid collides with the spiral protrusion, friction decreases the film resistance between the gas and the liquid, thereby facilitating the dissolution of oxygen, thereby increasing the oxygen transfer rate, and making the bubble of the gas very small. There is an effect that the residence time of the gas is long.

And because it is not a mechanical stirring device, there is no failure factor, so it can be used semi-permanently, and it is possible to operate unattended and noise and vibration do not occur during operation.

1 is a schematic configuration diagram of a wastewater treatment micro jet aeration apparatus according to a preferred embodiment of the present invention.
2 is a cross-sectional view of the in-line mixer according to a preferred embodiment of the present invention.
Figure 3 (a) is a cross-sectional view of the spiral protrusion according to a preferred embodiment of the present invention, Figure 3 (b) is a longitudinal cross-sectional view of the spiral protrusion according to a preferred embodiment of the present invention, Figure 3 (c) Is a partial enlarged view of Fig. 3 (b).

Hereinafter, exemplary embodiments of the present invention will be described with reference to the accompanying drawings.

First, a schematic configuration diagram of a wastewater treatment micro jet aeration apparatus according to a preferred embodiment of the present invention.

As shown, the micro jet aeration apparatus for wastewater treatment according to the present invention includes a pumping means 100, a venturi tube 200, an inline mixer 300, and a spiral stone engine 400.

First, the pumping means 100 will be described.

The pumping means 100 is a means for pumping water or a general fluid by power, and any device capable of sucking and discharging fluid may be used without limitation.

For example, the pumping means 100 is provided with a fluid inlet pipe (not shown) for the inflow of the fluid, and pumps an appropriate amount of fluid by pressure to supply to the venturi tube 200 to be described later.

Next, the venturi tube 200 will be described.

The venturi tube 200 is a component that is connected to the pumping means 100 and sucks air on the Venturi principle while the fluid passes.

Venturi's principle is that when the fluid is transferred to the pump, the pressure decreases due to the increase in the velocity of the fluid in the throat where the diameter of the venturi tube is drastically reduced by Bernoulli's theorem. to be.

 At this time, the air inlet 210 is installed in the neck portion of the venturi tube 200 is reduced in diameter, the air intake amount is changed according to the injection amount of the fluid, it is appropriate to install one or more air inlet 210 When installing two or more air intake openings 210a and 210b, they are installed to be symmetrical.

And it is advantageous to install the air inlet 210 to be perpendicular to the flow direction of the fluid at the point where the air inlet 210 and the venturi tube 200 meets the intake of air.

Preferably, the material of the venturi tube 200 may be made of a corrosion resistant and heat resistant material, and a stainless material is appropriate.

Next, the inline mixer 300 will be described (see FIG. 2).

It is coupled to the rear end of the venturi tube 200, and is a component for uniformly treating the mixed fluid and air in the venturi tube 200.

The fluid and air mixed in the venturi tube 200 are mixed to the perfect level due to the vortex action and the stirring action in the inline mixer 300.

In this case, the element (ELEMENT) installed in the inline mixer 300 has a streamlined twisted structure, and the number and size are determined according to the friction coefficient of the fluid, the pipe area, the pipe flow rate, the viscosity, and the density.

Preferably, the element is composed of a twist screw 310 of the shape of twisting the plate once and a plate screw 320 of the shape of the elliptical plate, and is fixed in contact with the inner peripheral surface of the tube.

Through this, the fluid and air passing through the venturi tube 200 are spiral flow paths s 'formed through the twist screw 310 and arc-shaped flow paths a' formed through the plate screw 320. Iteratively flows through the transitions and mixes them up.

As a result, the stirring process between the fluid and the gas is continued, and the stirring ability is improved, and the shape of the element is curved to minimize the pressure drop in the tube.

The inline mixer 300 can be used semi-permanently because there is no failure factor compared to the mechanical stirring device, it is suitably used in the case of high viscosity as well as a low viscosity of the fluid.

 Next will be described for the spiral stone engine (400). (See Fig. 3)

The spiral protrusion 400 is connected to a rear end of the inline mixer 300, and a plurality of protrusions 410 are spirally arranged in a tube to induce vortex of the fluid.

Preferably, the protrusion 410 has a fan shape or a triangular pyramid shape, and forms a plurality of spiral flow paths along an inner circumferential surface thereof.

The mixture of the fluid and air mixed in the above-described in-line mixer 300 is pulverized finely hit the fan-shaped projection 410, to form a shear stress through friction between the fluid and the projection formed a plurality of spiral flow paths. Therefore, the film resistance between the gas and the liquid is reduced to maximize the oxygen transfer rate.

Preferably, the protrusion 410 has a relatively large protrusion 412 and a small protrusion 414 arranged in the intersection to improve agitation ability (see FIGS. 3A and B), and further, the protrusion 414 is disposed. It is formed to be inclined to one side, it is possible to increase the rotational force of the flowing air and fluid (see Figure 3c).

3 is a schematic configuration diagram of a wastewater treatment jet aeration apparatus according to another embodiment of the present invention.

As shown, the jet aeration apparatus for wastewater treatment according to the present invention includes a water level sensor 500 and a control box 600 in the pumping means 100, the venturi tube 200, the inline mixer 300, and the spiral stone engine 400. More).

Here, the water level sensor 500 and the control box 600 will be further described.

The level sensor 500 detects a change in the level of the fluid in the tank (not shown), and the control box 600 stops the driving of the pumping means 100 when the level of the fluid in the tank is higher than a set value. The controlling component.

The reason for installing the water level sensor 500 and the control box 600 as described above is to prevent secondary pollution caused by overflow of the scum and bubbles that may occur due to the aeration device generally out of the reservoir.

In the present invention, it is not necessary to install the water level sensor 500 in the jet aeration pump to install a watering device or a cutter, or to set a bubble regulator, or when installing a watering device or a cutter, when the water level sensor detects a malfunction. It also serves as a secondary safety device that can cope with a failure.

Preferably, as shown, the water level sensor 500 has a total of three sensors (1) (2) (3), when the scum and foam is filled up to the ① sensor of the pumping means 100 Allow outages.

And when the cold scum and foam is lowered below the sensor ②, the pumping means 100 is restarted again.

As described above, the wastewater treatment micro jet aeration apparatus of the present invention is mixed with wastewater and air in a venturi tube and passed through an in-line mixer and spiral throttle, with a perfect mixing through the stirring action of wastewater and air. In 400), the mixture of fluid and air is finely decomposed to reduce the gas-liquid film resistance, thereby maximizing the stirring efficiency and the efficiency of oxygen transfer rate much better than the conventional jet aeration pump.

Lastly, the present invention is not limited to the above-described embodiments and the accompanying drawings, and in the technical field to which the present invention pertains that substitutions, modifications, and conversions can be made without departing from the technical spirit of the present invention. It will be apparent to those who have knowledge.

100: pumping means
200: Venturi tube
210, 210a, 210b: air intake
300: inline mixer
310: twisted screws
320: plate screw
400: spiral stone engine
410: projection
412: big projection
414: small projection
500: water level sensor
600: control box

Claims (5)

Pumping means for supplying a high speed fluid;
A venturi tube connected to the pumping means and sucking air on a venturi principle while the fluid passes therethrough;
An inline mixer coupled to a rear end of the venturi tube and uniformly agitating the fluid and air mixed in the venturi tube; And
A spiral protrusion connected to a rear end of the inline mixer, the spiral protrusion having a plurality of protrusions spirally arranged in a tube to induce vortex of the fluid;
Wastewater treatment micro jet aeration device comprising a. The method of claim 1,
The protrusion is formed in a fan shape, the micro-jet aeration apparatus for treatment of waste water, characterized in that to form a plurality of spiral flow paths along the inner circumferential surface. The method of claim 1,
The projection portion is a micro jet aeration apparatus for wastewater treatment, characterized in that the relatively large projection and the small projection is arranged in the intersection. The method of claim 1,
And a water level sensor for detecting a change in water level of the fluid, and a control box for controlling the driving of the pumping means when the level of the fluid is higher than a set value. The method of claim 1,
Micro-vented aeration device for wastewater treatment, characterized in that the air suction port is installed in the neck portion of the venturi tube is reduced in diameter.

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