KR101478713B1 - Self cleaning membrane system - Google Patents

Abstract

A treatment device for reuse of purified water and wastewater treatment water is provided with a TiO ₂ membrane for treating inflow water containing particulate matter, organic matter and refractory substances in an upflow type treatment tank, and has a wastewater inlet and a treatment water outlet Treatment tank; A microwave supply device for supplying microwaves to the treatment bath to decompose organic matter; And an electrodeless discharge lamp installed in the treatment tank to assist OH radical generation in the TiO ₂ membrane.

Description

Self cleaning membrane system < RTI ID = 0.0 >

The present invention relates to a self-cleaning separation membrane system using a TiO ₂ separation membrane, which minimizes clogging by decomposing a substance causing clogging occurring in a separation membrane process.

The membrane process is a technique to physically separate and remove contaminants from the membrane. Membrane process is a process that is small in area and requires little use of chemicals and can be automated. It can easily form a hybrid system with other physicochemical treatment process, so it can add appropriate treatment process It has the advantage of meeting water quality standards. Therefore, it is currently applied to wastewater treatment and water treatment processes, and its utilization rate is gradually increasing.

The membrane process can selectively separate the target water with a small energy, but it may result in a decrease in the membrane permeation flux due to membrane contamination which deteriorates the performance of the membrane, which may limit the application of the membrane separation process.

The contamination of the membrane is caused by the suspended substances contained in the wastewater or the substances easily adsorbed on the surface of the membrane, which are scattered on the surface of the membrane and in the air to interfere with the flow of the fluid, thereby reducing the permeability. In general, the decrease in the permeability in the membrane separation process is caused by the decrease of the permeability due to the membrane contamination and the deterioration of the separation function due to the change of the membrane characteristics and the increase of the concentration of the solute at the membrane surface when the solution passes through the membrane due to the concentration polarization. The effective pressure decreases and the transmittance decreases.

Further, when the solute is continuously concentrated on the membrane surface, the osmotic pressure increases due to the high solute layer on the membrane surface, and the permeability decreases.

Therefore, various methods for preventing concentration polarization phenomenon should be suggested. The most problematic phenomenon in this membrane separation process is biofouling, which is organic fouling due to organic matter and high molecular substance (EPS) generated by microorganism growth.

This phenomenon occurs mainly in the purification process using the membrane separation process and in the process of reuse of the wastewater treatment water. Therefore, there is a need for management to prevent such problems, and there is a conventional management method using the chlorination agent as a conventional technology for this. Can cause secondary contamination due to the injection of additional chemicals and has a problem in that the salt removal rate can be lowered by widening the pores of the membrane by acting directly on the separation membrane.

The present invention was conceived in view of the above problems, and it is an object of the present invention to dissolve a high concentration of organic material layer and biofouling generated near a film by irradiating TiO ₂ membrane with UV light to remove the foulant of the membrane, It is an object of the present invention to provide an improved membrane module system for further decomposing and increasing the decomposition efficiency by UV.

In order to achieve the above object, a self-cleaning separation membrane system according to the present invention is characterized in that a TiO ₂ membrane for treating particulate matter, organic matter and refractory substances is disposed inside the treatment tank, Treatment; A microwave supply device for supplying microwaves to the upflow treatment tank to decompose organic matter; And an electrodeless discharge lamp installed in the upflow treatment tank to assist OH radical generation in the TiO ₂ membrane.

The apparatus may further include a heat exchanger for exchanging heat with the inflow water flowing into the upflow treatment tank to increase the temperature of the inflow water.

The microwave apparatus may include a microwave supply unit for generating a microwave of a specific frequency and supplying the generated microwave to the treatment tank.

The microwave supply unit may include a microwave generator for generating the microwave; A waveguide for transmitting the microwave generated from the microwave generator to the treatment tank; A fluororesin pipe installed in the treatment tank and irradiating microwaves transferred through the waveguide into the treatment tank; And an untreated water conveying unit for re-supplying unprocessed wastewater to the treatment tank inflow section in the treatment tank.

According to the self-cleaning membrane separation system of the present invention, the recovery rate of the membrane separation process is increased and the operation time of each separation membrane is optimized by increasing the inhibition of the organic fouling occurring in the sewage reuse and water purification process.

In addition, the existing developed TiO ₂ membrane has been developed in order to prevent hydrophobic organic matters from being contaminated by providing hydrophilic surface characteristics of the surface of the separation membrane. When a light source such as UV is irradiated thereto, The degree of friendliness is increased so that film contamination due to organic matter can be prevented and the membrane can be easily cleaned.

On the other hand, TiO ₂ can be used as a catalyst in the photooxidation process using UV, and its effect can be increased by microwave irradiation. The organic layer formed in the membrane separation process of the membrane can be decomposed by UV irradiation and microwave irradiation under the TiO ₂ catalyst to inhibit organic foaming.

As a result, it is possible to prevent the reduction of the transmittance due to the concentration polarization on the surface of the film due to the organic matter generated during operation and the decrease of the recovery rate thereof, and it is possible to operate for a long time without additional operation, .

FIG. 1 is a schematic diagram showing a self-cleaning separation membrane system according to an embodiment of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, a self-cleaning membrane system according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

Referring to FIG. 1, a self-cleaning membrane separation system 10 according to an embodiment of the present invention includes a TiO ₂ membrane 110 installed in an upflow type treatment tank 100, a microwave supply unit An apparatus 118 and an electrodeless discharge lamp 123 installed to assist OH radical generation in the TiO ₂ membrane 110 installed in the treatment tank 100.

The upflow treatment tank 100 is connected to a TiO ₂ membrane (not shown) to remove particulate matter, organic substances (nitrogen, phosphorus), and refractory substances contained in the inflowed surface water (lake water, river water, 110) as the main treatment.

The raw water inlet 50 is connected to a raw water supply path 20 to supply raw water and a supply pump 30 may be installed on the raw water supply path 20.

The upflow treatment tank 100 has a treatment tank inflow section 101 and a treated water discharge section 102.

The treatment tank 100 is an upflow type reaction tank for treating the microwave supply device 110, the electrodeless discharge lamp 123 and the TiO ₂ membrane 110, Organic material, and refractory material are introduced into the TiO ₂ membrane reaction tank and oxidized and filtered in the TiO ₂ membrane 110 by microwave irradiation and UV-vis irradiation, thereby finally performing a treatment process.

The electrodeless discharge lamp 123 is installed inside the fluororesin pipe 121 installed in the upflow type treatment tank 100. Electrode discharge lamp 123 can be protected from the waste water by making the surface water and the wastewater treatment water come into contact with the outside of the fluororesin pipe 121 and the electrodeless discharge lamp 123 can protect the OH of the TiO ₂ membrane 110 The fouling of the TiO ₂ membrane 110 can be suppressed by assisting in radical generation. That is, when the electrodeless discharge lamp 123 is installed inside the fluororesin pipe 121, the electrodeless discharge lamp 123 is protected by the fluororesin pipe 121 having relatively few foreign substances, So that a uniform microwave UV-vis irradiation can be performed.

Since the electrodeless discharge lamp 123 is a structure that can be easily understood from the known art, a detailed description thereof will be omitted.

The TiO ₂ membrane 110 may be branched into a plurality of pipe structures in the upflow type treatment tank 100. The TiO ₂ membrane 110 may be branched from the treatment tank 100 through the treated water discharge unit 102, Lt; / RTI > The TiO ₂ membrane 110 may be variously selected depending on the type and concentration of contaminants to be treated, such as an ultrafiltration membrane, a microfiltration membrane, a nanofiltration membrane, and the like. Can be applied.

The untreated untreated water in the treatment tank 100 can be supplied to the treatment tank 100 by the untreated conveyance unit 80 and supplied again. That is, the untreated transport unit 80 transports the untreated raw water to the treatment tank 100 in order to delay the residence time in accordance with the increase in the concentration of the contaminant in the treatment tank 100 and minimize the stagnation zone in the treatment tank 100 So that it can be reprocessed. The untreated conveyance unit 80 includes an untreated conveyance path 70 for connecting the untreated water discharge unit 104 and the raw water supply path 20 and a conveyance pump 60 provided on the untreated conveyance path 70 do.

The microwave supply device 118 includes a microwave generator 119 for generating and supplying a microwave (915 ± 100 MHz, 2,450 ± 100 MHz).

The microwave supply unit 118 includes a microwave generator 119 for generating a microwave, a waveguide 120 for delivering the microwave generated from the microwave generator 119 to the upflow type treatment tank 100, And a fluorine resin pipe 121 installed in the processing vessel 100 and irradiating the microwave transferred through the waveguide 120 into the processing vessel 100.

Further, it is preferable to further include a heat exchanger 40 for exchanging heat between the temperature of the treated water supplied through the treated water discharge unit 202 and the raw water introduced through the raw water supply path 30. Since the heat exchanger 40 exchanges the heat of the high-temperature treated water and the relatively low-temperature inflow water generated when the organic matter is decomposed by the microwave irradiation, the temperature of the incoming source water supplied to the upflow- So that the treatment efficiency in the upflow type treatment tank 100 can be increased.

1, reference numeral 105 denotes an upflow type treatment tank 100, which represents a waste gas generated during a water treatment process and a gas discharge port for discharging air, respectively.

As described above, according to the self-cleaning membrane separation system 10 according to the embodiment of the present invention, for the purification of water containing the particulate matter, the organic substance, the refractory substance, and the wastewater treatment water reuse, ).

In the treatment tank 100, particulate, organic, and refractory materials can be effectively removed through the TiO ₂ membrane 110, the microwave irradiation, and the electrodeless discharge lamp 123. In particular, the TiO ₂ membrane 110, Since the organic material that is attached to the surface and causes fouling is decomposed and removed by microwave irradiation, ultimately the membrane fouling can be suppressed, and the membrane replacement cycle and the life span can be prolonged, and the maintenance cost can be drastically reduced.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. Those skilled in the art will readily appreciate that many modifications and variations of the present invention are possible without departing from the spirit and scope of the appended claims.

10. Self-cleaning membrane separation system 40. Heat exchanger
80. Untreated water conveying unit 100. Upflow type treatment tank
110 ..TiO ₂ membrane 118 .. microwave supply device
119. Microwave generator 120. Waveguide
121 .. Fluoropolymer pipe 123 .. Electrode discharge lamp

Claims (5)

A treatment tank provided with a TiO ₂ membrane for treating particulate matter, organic substances and refractory substances in the treatment tank and having a raw water inlet and a treated water discharge portion;
A microwave supply device for supplying microwaves to the treatment bath to decompose organic matter; And
And an electrodeless discharge lamp installed in the treatment tank to assist OH radical generation in the TiO ₂ membrane,
And a heat exchanger for exchanging heat with the raw water flowing into the treatment tank to raise the temperature of the raw water. delete The microwave apparatus according to claim 1,
And a microwave supply unit for generating a microwave of a specific frequency and supplying the generated microwave to the treatment tank. The method of claim 3,
The microwave supply unit,
A microwave generator for generating the microwave;
A waveguide for transmitting the microwave generated from the microwave generator to the treatment tank;
And a fluorine resin pipe installed in the treatment tank and irradiating microwaves transferred through the wave guide to the inside of the treatment tank. The method according to claim 1,
And an untreated water conveying unit for re-supplying the untreated wastewater into the treatment tank inflow section in the treatment tank.

Images