KR100904722B1 - Apparatus for generating micro-buble - Google Patents

Abstract

An apparatus for generating micro-bubbles is provided to treat raw water easily by generating the micro-bubbles in a treating process of the raw water rapidly when the raw water is discharged through a discharge pipe. An apparatus for generating micro-bubbles includes an inlet pipe(10), a flow metering valve(20), a reduced pipe(30), an injection nozzle(40), a discharge pipe(60), a micro-bubble production part(70), and a dissolving tank(80). The reduce pipe includes a first reduced portion(31) of which diameter is smaller than a diameter(D1) of the inlet pipe. The micro-bubble production part is a venture tube having a second reduced portion(71) of which diameter is smaller than the diameter of the discharge pipe. A ration of the diameter of the second reduce portion and the discharge pipe is 1:5 ~ 1:10. The apparatus for generating micro-bubbles further includes a supply pipe(110). The supply pipe is installed on the first reduced portion, and is supplied treatment chemical for treating the raw water.

Description

Apparatus for generating micro-buble}

The present invention relates to a microbubble generating device, and more particularly to a microbubble generating device for easily generating microbubbles in raw water during raw water treatment.

As a method for removing and purifying suspended solids in raw water including polluted water sources, domestic sewage, and plant wastewater, a solid liquid separation method, a physicochemical treatment method, and a biological treatment method are largely used depending on the type and content of the suspended solids in the raw water.

In order to separate and recover the suspended matter in the raw water, a solid liquid separation method is widely used. The solid liquid separation method includes a gravity sedimentation method, a flotation method, and a filtration method.

Gravity sedimentation is a method in which suspended solids are sedimented by gravity, and flotation is a method of treating suspended solids by floating them in water, and filtration is a method of separating and recovering suspended solids by filtering suspended solids in raw water. .

In particular, the flotation method includes a natural flotation method in which floating matters that tend to float in raw water naturally gather on the surface of the water, and an air flotation method that generates fine bubbles in the raw water and floats the floating matters using the lifting force of the fine bubbles.

The air flotation method is effective for floating floats such as fine sludge, which is difficult to float by itself due to its small buoyancy, and it is very important to cause the floating matters to be lifted by the rising force of the fine bubbles by generating microbubbles in raw water. Since the generator uses an air compressor and various control valves, the apparatus is often complicated.

Therefore, there is a need for a microbubble generating device capable of generating a simple and effective microbubble in order to raise the suspended matter in the raw water, in particular during the treatment of raw water.

The present invention has been made in view of the above-described matters, and an object of the present invention is to provide a microbubble generating device which can easily process raw water by generating microbubbles in raw water during raw water treatment.

The microbubble generating device according to the present invention for achieving the above object, the inlet pipe into which the raw water is introduced, provided in the inlet pipe, a flow control valve for adjusting the inflow of the raw water, and any of the inlet pipe A reducer tube provided at a point and having a first reducer having a diameter smaller than a diameter of the inlet tube, an inlet tube connected to the reducer tube and into which gas dissolved in the raw water is injected; A pump which is connected to an end of the pipe and sucks the raw water into the inlet pipe and mixes the gas and the raw water introduced through the injection pipe, and a discharge pipe connected to the pump and discharging the mixed raw water; It is provided at any point of the discharge pipe, and comprises a microbubble generating unit for generating a microbubble in the raw water.

In addition, the microbubble generating unit is a banchu tube having a second reducer having a diameter smaller than the diameter of the discharge pipe, the ratio of the diameter of the second reducer and the diameter of the discharge pipe is 1: 5 ~ 1:10. Is preferably.

In addition, it is preferably provided between the pump and the micro-bubble generating unit, further comprising a dissolved tank containing the raw water containing the gas.

In addition, it is preferable to further include a supply pipe provided in the first reducer, the supplying treatment chemicals for raw water treatment.

First, the microbubble generating device according to the present invention, when the raw water is discharged to the discharge pipe via the banchu tube, the flow rate of the raw water is instantaneously accelerated microbubbles are generated, so it is easy to generate fine bubbles in the raw water to provide.

Second, since the gas dissolved in the raw water is sucked by self-suction during raw water treatment, it provides an effect that can easily dissolve the gas required for raw water treatment.

Third, since the gas injected into the raw water is rapidly mixed by the rotation of the pump, the gas dissolution rate is increased in the raw water and the raw water is kept in the dissolution tank for a predetermined time, thereby providing an effect of increasing the dissolution rate of the gas supplied to the raw water. .

Fourth, it is possible to easily mix the treatment chemicals in the raw water by inhaling the liquid treatment chemicals for the raw water treatment.

The present invention relates to a microbubble generating device for generating microbubbles in raw water, and more particularly, to a microbubble generating device in which gas is sucked into the raw water by self-suction, and microbubbles are generated in raw water passing through the microbubble generating unit. .

Hereinafter, with reference to Figure 1 schematically showing an embodiment of the present invention will be described in detail. Microbubble generating device according to an embodiment of the present invention is the inlet pipe 10, the flow control valve 20, the reducer pipe 30, the injection pipe 40, the pump 50, the discharge pipe 60 ) And a micro bubble generator 70.

The inflow pipe 10 is provided to introduce the raw water 1 into the apparatus from the raw water storage tank 2 in which the treated raw water 1, such as contaminated water supply, domestic sewage, and plant wastewater, is accommodated. The flow control valve 20 is provided in the inlet pipe 10, and adjusts the inflow of the raw water (1).

The reducer pipe 30 is a pipe having a diameter D2 smaller than the diameter D1 of the inlet pipe 10 in some sections, and is intended to be dissolved in the raw water 1 through the injection pipe 40 to be described later. It is provided for injecting the gas self-sufficiently. An arbitrary point of the reducer pipe 30 is provided with a first reducer part 31 having a diameter D2 smaller than the diameter D1 of the inlet pipe 10. The reducer pipe 30 is injected with a gas such as air or ozone to easily generate micro bubbles in the raw water 1 during raw water 1 treatment.

The injection pipe 40 is provided to supply the gas to the reducer pipe 30, and in this embodiment, the injection pipe 40 extends from the first reducer 31. In the embodiment, the injection pipe 40 has a gas flow rate control valve 41 for adjusting the flow rate of the gas injected through the injection pipe 40, and the flow rate gauge 90 for checking the flow rate of the gas is introduced Combined.

In addition, in the present embodiment, the reducer pipe 30 is provided with a supply pipe 110 for supplying a treatment drug such as a fungicide, a flocculant, etc. in a liquid state for chemical treatment of the raw water 1. The supply pipe 110 is coupled to the chemical storage container 120 is the treatment chemicals are accommodated, it is possible to adjust the flow rate of the treatment chemicals by the liquid flow rate control valve (101).

The pump 50 is provided to suck the raw water 1 to the inlet side, and the gas and the supply pipe injected through the injection pipe 40 when the raw water 1 passes through the pump 50 ( The treatment chemical supplied through 110 is rapidly mixed with the raw water 1 by the impeller 51 of the pump 50.

The raw water 1 via the pump 50 is discharged through the discharge pipe 60, and the pressure of the raw water 1 is checked by the pressure gauge 100 when the raw water 1 is discharged from the pump 50. do.

The raw water 1 passes through the microbubble generating unit 70 provided at an arbitrary point of the discharge pipe 60, and microbubbles are generated in the raw water 1 while passing through the microbubble generating unit 70.

The microbubble generating unit 70 is a venturi tube having a second reducer 71 having a diameter D4 smaller than the diameter D3 of the discharge pipe 60, and the second reducer ( The ratio of the diameter D4 of 71 to the diameter D3 of the discharge pipe 60 is preferably 1: 5 to 1:10.

The microbubble generating device according to the present invention further includes a dissolved tank 80, wherein the dissolved tank 80 is disposed between the pump 50 and the microbubble generating unit 70.

The dissolved tank 80 maintains the raw water 1 discharged from the pump 50 for a predetermined time so that the gas injected through the injection tube 40 is sufficiently dissolved in the raw water 1. In addition, when treated chemicals are supplied, the raw water 1 and the treated chemicals react during the residence time.

Hereinafter, the operation of the micro-bubble generating device according to the present invention by the above configuration.

The microbubble generating device according to the present invention is used to generate microbubbles in the raw water (1) in the process of moving the raw water (1) stored in the storage tank (2) to the raw water treatment tank (3).

First, the pump 50 is operated to suck the raw water 1 stored in the raw water storage tank 2 to the inlet pipe 10 side. At this time, by using the flow control valve 20 to adjust the amount of raw water (1) flowing into the inlet pipe (10).

The raw water 1 introduced through the inlet pipe 10 passes through the reducer pipe 30, and the diameter D2 of the first reducer 31 is larger than the diameter D1 of the inlet pipe 10. Since it is small, the flow rate of the raw water 1 is instantaneously increased, and the pressure in the 1st reducer 31 becomes lower than the outside. Therefore, gas is sucked from the injection pipe 40 to the first reducer 31 by self-suction. That is, the end of the injection tube 40 is in communication with the outside, the outside air is absorbed by the self-suction.

On the other hand, in the case of supplying a treatment chemical such as a disinfectant or flocculant into the raw water 1, when the liquid flow rate control valve 101 of the supply pipe extending from the first reducer 31 is opened, the gas is reduced pipe. Similar to the principle of self-inhalation (30), the liquid treatment agent is sucked into the reducer tube 30 by self-suction.

When gas is injected through the injection pipe 40, the flow rate of the gas to be injected is preferably injected at a rate of about 5 to 15% of the incoming raw water (1). If the flow rate of the injected gas is too low, the rate of occurrence of micro bubbles in the microbubble generating unit 70 is low, If the flow rate of the injected gas is too high, the impeller 51 of the pump 50 is turned off and the It may cause failure due to overheating.

The gas sucked through the injection pipe 40 or the treatment chemical supplied through the supply pipe 110 are mixed with the raw water 1 while passing through the first reducer 31 and the pump 50. While passing through the interior of the pump 50 is more rapidly mixed by the impeller 51.

Subsequently, the raw water 1 discharged through the pump 50 stays in the dissolved tank 80 for a predetermined time. When the pump 50 is operated for a predetermined time and the raw water 1 is filled in the dissolved tank 80, for a predetermined time until the raw water 1 is discharged through the discharge pipe 60 connected to the lower end of the dissolved tank 80. The raw water 1 stays in the dissolved tank 80, the dissolution rate of the gas in the raw water 1 becomes high, and reacts with the supplied treatment chemicals during the stay.

Subsequently, the raw water 1 is discharged through the discharge pipe 60 extending from the dissolved tank 80, in which the raw water 1 passes through the microbubble generating unit 70, that is, the banchu tube.

Since the diameter (D4) of the banchu tube second reducer (71) is smaller than the diameter (D3) of the discharge pipe (60), similarly to the reducer pipe (30), the flow rate of the raw water (1) is instantaneously increased. As the pressure in the venturi tube is lowered, the dissolved gas contained in the raw water 1 comes out of the raw water 1 to generate microbubbles.

Subsequently, the raw water 1 in which the fine bubbles are generated is moved to the treatment tank 3. The raw water 1 including the microbubbles facilitates the treatment of the raw water, and in particular, the microbubbles are adsorbed to the suspended matter contained in the raw water 1, so that the microbubbles and the adsorbed suspended matter in the treatment tank 3 are effectively floated. It is possible to handle the floats.

Hereinafter, in order to maximize the generation efficiency of the microbubble, the present inventors specifically test the data while changing the diameter (D3) of the discharge pipe 60 and the diameter (D4) of the banchu tube second reducer 71 in detail. Explain.

Experimental Example D3 (unit mm) D4 (unit mm) D3 / D4 Pressure difference (kg / cm ² ) Actual flow rate (L / min) Micro bubble generation One 25 2.0 12.5 4.8 14.1 U 2 25 2.7 9.3 4.0 18.5 U 3 50 6.8 7.4 4.5 51.2 U 4 50 12.0 4.2 1.0 120.3 radish

Table 1

In [Table 1], the pressure difference is a difference between the pressure in the discharge pipe 60 discharged from the pump 50 and the pressure after passing through the second reducer 71, and the measured flow rate is a banchu tube per unit minute. It is defined as the flow rate of the raw water (1) discharged via.

The presence or absence of microbubbles can be performed by, for example, receiving normal tap water in a raw water tank and then passing the tap water through the microbubble generating device according to the present invention to observe that the clean tap water turns cloudy milky when microbubbles are generated. have.

As a result, in the Experimental Example 4 in which the ratio (D3) of the discharge pipe 60 and the diameter (D4) of the second reducer of the Banturie tube was 4.2, microbubbles were not generated, and in Experimental Example 1 in which the ratio was 12.5, Although micro bubbles were generated, there was a problem that the pressure difference was increased and the pump 50 was overloaded.

Therefore, it is preferable that the appropriate ratio of the diameter D4 of the second reducer 71 and the diameter D3 of the discharge pipe 60 is 1: 5 to 1:10. In addition, the pressure difference is preferably 3.5 ~ 4.5 kg / cm ² . As shown in Experiment 1, even when the pressure difference is 4.5 kg / cm ² or more, microbubbles are generated, but the load applied to the pump 50 becomes excessive and the measured flow rate is uneconomical.

As described above, the microbubble generating device according to the present invention easily dissolves the gas necessary for raw water treatment because the gas dissolved in the raw water is sucked by self-suction during raw water treatment, and when the raw water is discharged to the discharge pipe via the microbubble generating unit, Since the flow rate of is instantaneously generated to generate microbubbles, it is possible to easily generate microbubbles in raw water.

In addition, the gas injected through the injection tube is mixed with the raw water by the pump impeller to increase the dissolved rate of the gas, it provides an effect of increasing the dissolved rate of the gas by remaining in the dissolved tank for a predetermined time.

In addition, since treatment chemicals such as flocculant and disinfectant are sucked in a liquid state by self-sorption for raw water treatment, the treatment chemicals can be easily mixed in raw water to easily aggregate or sterilize the medicines with raw water inhaled. .

As mentioned above, although the present invention has been described in detail with reference to preferred embodiments, the present invention is not limited to the above embodiments, and many other various modifications can be provided without departing from the scope of the present invention.

1 is a schematic cross-sectional view of a microbubble generating device according to an embodiment of the present invention.

<Description of the symbols for the main parts of the drawings>

10 ... Inlet pipe 20 ... Flow control valve

30 ... Reduce Pavilion 31 ... First Reducer

40 ... infusion tube 50 ... pump

51 ... impeller 60 ... discharge pipe

70 ... microbubble generating unit 71 ... second reducing unit

80 ... dissolved tank

Claims (4)

In the microbubble generating device for generating a microbubble, An inlet pipe into which raw water flows; Is provided in the inlet pipe, the flow rate control valve for adjusting the inflow of the raw water; A reducer tube provided at any point of the inlet tube and having a first reducer having a diameter smaller than that of the inlet tube; An injection tube connected to the reducer tube and into which gas dissolved in the raw water is injected; A pump connected to an end of the inlet pipe, for sucking the raw water into the inlet pipe and mixing the gas and the raw water introduced through the inlet pipe; A discharge pipe connected to the pump and configured to discharge the mixed raw water; A microbubble generating unit provided at an arbitrary point of the discharge pipe and generating microbubbles in the raw water; The microbubble generating device is disposed between the pump and the microbubble generating unit, the dissolved tank containing the raw water containing the gas. The method of claim 1, The microbubble generating unit is a banchu tube having a second reducer having a diameter smaller than the diameter of the discharge pipe, The ratio of the diameter of the second reducer and the diameter of the discharge pipe is 1: 5 ~ 1:10 microbubble generating apparatus, characterized in that. delete The method of claim 1, The microbubble generating device is provided on the first reducer, and further comprising a supply pipe to which the treatment chemical for the raw water is supplied.

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