KR19990045908A - Purifying material of a waste water and manufacturing method therefor and purifying system using therefor - Google Patents

Abstract

Disclosed is a wastewater purifier capable of purifying wastewater with minerals activated by far-infrared emissivity through a heat treatment process, a manufacturing method thereof, and a purification system using the wastewater purifier. The waste water purifying agent has a case 10 having a plurality of through-holes 12 communicating with the outside and a space having a predetermined volume therein, and granite 22 accommodated inside the case 10 and having particles having a predetermined size. ) And the sedimentary rocks 24 are mixed with the far-infrared emitting portion 20 to emit far infrared rays.

The far-infrared emitter 20 activates the emissivity of far-infrared radiation at a wavelength of approximately 7 to 20 μm through a heat treatment process in which two kinds of granite 22 and sedimentary rock 24 are heated at a high temperature of about 150 ° C. or more.

According to the present invention, the far-infrared radiation improves the purification rate of wastewater, suppresses and sterilizes the growth of perishable bacteria, and enables the purification of the wastewater within a short time, as well as the replacement of the purification agent.

Description

Purifying material of a waste water and manufacturing method therefor and purifying system using therefor}

The present invention relates to a wastewater purifier, a method for manufacturing the same, and a purification system using the wastewater purifier, and particularly, a wastewater purifier for heat treating granite and sedimentary rocks to activate far-infrared rays, and then mixing them in an appropriate ratio to purify the wastewater. And a method for producing the same and a purification system using the wastewater purification agent.

In general, related technologies for purifying wastewater include active sludge methods based on biological treatment methods and treatment methods for microorganisms to decompose organic matter by proliferating and cultivating aerobic microorganisms. There are many ways, such as law.

The above methods require secondary sedimentation tanks, including aeration tanks, to remove suspended solids from wastewater from the primary sedimentation tanks and to grow and grow aerobic microorganisms, leading to the enlargement of facilities and complexity of the structure.

Wastewater purified by such biological treatment of wastewater does not decompose completely organic matters, but increases the water pollution by eutrophicating the water quality of the discharge water system under the influence of residual nitrogen and phosphorus (P) compounds. In order to solve this problem, a separate tertiary wastewater treatment facility is required.

In addition, the microbial treatment method, although the microorganism is cultured after a certain time in a certain volume, the cultured microorganism takes a long time in the process of decomposing, fermenting, and oxidizing organic matter dissolved in the waste water, nitrogen, By producing components such as sulfur oxides and merkatosan, there is a disadvantage in that odor is generated.

Meanwhile, another example of purifying wastewater is disclosed in Korean Utility Model Publication No. 91-4472, “Waterway-type Wastewater and Wastewater Purification Facility and Method Using Purified Material Coal,” and as shown in FIG. Filtration tank (6) formed by stacking activated coal (9), which has been processed directly on the tank), and the channel (1) opens a modified channel (2) separately and enters the channel change dam (3). The control dam 4 is provided.

In addition, the filtration tank 6 includes lower filtration tanks 8 arranged to form a constant thickness according to the size of the coal lumps in consideration of the nature of wastewater and the amount of water treatment efficiency, and a plurality of upper filtration walls installed according to the size of the coal lumps. It consists of (7), and the filtration tank 6 has a structure supported by the auxiliary wall 10 with a good water permeability.

The above example utilizes activated coal 9 as a material for purifying wastewater, and has a function of purifying wastewater using filtration of contaminants and properties of coal masses.

The aforementioned methods have their advantages, but have the following problems.

First, not only takes a long time to purify the waste water, there is a problem that the odor due to the gas generated according to this.

Second, there is a disadvantage in that replacement work is cumbersome when it is a simple filtering function rather than a natural purification.

Third, due to incomplete purification of wastewater, residual organic matter may be propagated and water quality may be contaminated.

The present invention was created in view of the above-mentioned problems, and its purpose is to purify wastewater within a short time, and to improve the purification function due to the suppression of propagation of perishable bacteria and to simplify the replacement work after a long time use. The present invention provides a wastewater purification agent, a method of manufacturing the same, and a purification system using the wastewater purification agent.

1 is a perspective view showing a conventional wastewater purification agent,

2 is a cross-sectional view showing a preferred embodiment of the waste water purification agent according to the present invention,

3 is a block diagram showing a schematic configuration of the purification system of the present invention;

Explanation of symbols on the main parts of the drawings

10: case 12: through hole

20: far infrared emitter 22: granite

24: sedimentary rock 30: secondary case

40: blower 50: purifier

100: first processor 200: second processor

300: third processor

In order to achieve the above object, the present invention provides a wastewater purifying agent, a method for manufacturing the same, and a purification system using the wastewater purifying agent, in which a plurality of through holes having a predetermined size are formed on an outer circumferential surface thereof and have a predetermined volume of space therein, and the inside of the case. It is accommodated in, characterized in that it comprises a far-infrared emitter, the mineral of granite and sedimentary rock heat-treated to a predetermined temperature in order to emit far-infrared light is mixed at an appropriate ratio.

Another feature of the present invention is a heat treatment step of activating the far-infrared emissivity of minerals by applying heat above a predetermined temperature to the minerals of granite and sedimentary rock having a porosity, and mixing the heat-treated minerals in an appropriate ratio according to the components of the waste water And a crushed stone step of crushing the mixed mineral into a particle of a predetermined size.

Another characteristic element of the present invention includes a first processor that heat-treats and purifies the purified material composed of minerals activated with far-infrared emissivity in a predetermined amount of wastewater to capture and settle contaminants of the wastewater, and to discharge the vaporized gas. And a second processor for promoting and neutralizing the redox reaction of the wastewater supplied by passing through the first treatment unit by precipitating a predetermined amount of the purified water and assisting bacterial growth, and the wastewater supplied by the second treatment unit by precipitating a predetermined amount of the purifying agent. It is a purification system equipped with a third processor for activating the water molecules of the bacteria to suppress and sterilize the growth of contaminating bacteria.

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

As shown in FIG. 2, the wastewater purifying agent according to the present invention includes a case 10 having a plurality of through-holes 12 communicating to the outside and a space having a predetermined volume therein, and housed inside the case 10. The granite 22 and the sedimentary rocks 24 having particles of a predetermined size are mixed with the far infrared ray emitting part 20 to emit far infrared rays.

In more detail, the far-infrared emitter 20 undergoes a heat treatment process in which the two kinds of granite 22 and the sedimentary rock 24 are heated at a high temperature of about 150 ° C. or more, thereby adjusting the emissivity of the far infrared ray to a wavelength of about 7 to 20 μm. It is activated.

In addition, granite (22) is a porous rock containing a plurality of mineral components, such as biotite, feldspar, silica, etc., the main components are SiO₂, AL₂O₃, Na₂O, MgO, FeO, etc. .

In addition, it is preferable that the sedimentary rocks 24 also adopt a porous one containing a plurality of kinds of mineral components.

In addition, an auxiliary case 30 in which minerals having a different size from particles of the far infrared ray emitting part 20 is accommodated is provided in the case 10, and a through hole 12 having a predetermined size is formed on an outer circumferential surface of the auxiliary case 30. Formed.

One or more of the auxiliary cases 30 may be provided according to the pollution detection concentration of the waste water.

In addition, the lower surface of the case 10 is provided with a blower 40 (BLOWER) for circulating the waste water in the case 10, a separate blower 40 for circulating the entire waste water outside the case 10 is provided It would be desirable to be prepared.

The manufacturing method for manufacturing the wastewater purification agent 50 having such a configuration includes a heat treatment step of applying high heat to the porous granite 22 and the sedimentary rock 24 to activate radiation of far infrared rays, It consists of a mixing step of mixing at an appropriate ratio according to the pollution concentration, and a crushing step of crushing the mixed two kinds of minerals to a predetermined size.

The above steps can be executed in any order.

Meanwhile, the wastewater purification system using the wastewater purification agent is composed of minerals (granite (22) + sedimentary rock (24)) activated by far heat (approximately 150 to 800 ° C) and activated with far infrared radiation as shown in FIG. Precipitant 50 is precipitated in a predetermined amount of waste water to capture and settle contaminants of the waste water, and is decomposed, and a predetermined amount of purifier 50 is precipitated to discharge the gas to be vaporized. The second processor 200 for promoting and neutralizing the redox reaction of the wastewater supplied through the N2 and assisting bacterial growth, and the predetermined amount of the purifier 50 is precipitated and the water of the wastewater supplied from the second processor 200. It is provided with a third processor 300 for activating the molecules to suppress and sterilize the growth of contaminating bacteria.

Unexplained reference numeral 400 denotes a flow path through which wastewater flows in and out.

The first, second, and third treatment units (100,200,300) are classified into collection tanks, reaction tanks, and aeration tanks, respectively, according to their functions. It captures and precipitates fats, phenols, etc., and has functions such as partial coagulation, neutralization and water molecule electromagnetic wave activity.

In addition, vaporized gases such as emulsified ammonia and carbon monoxide are discharged.

Subsequently, the second processor 200 promotes the redox reaction of the wastewater supplied from the first processor 100 through the flow path 400 to assist bacterial growth by the precipitation of the first processor 100 and the neutralization of the water quality. Done.

In addition, the third processor 300 spreads the bacteria capture and photosynthetic energy of the wastewater supplied from the second processor 200 through the flow path 400 and fills and balances the active functions (resonance, resonance, absorption, etc.) of the water molecules. It has the function of inhibiting and sterilizing the propagation of perishable bacteria.

At this time, each of the first, second, third processing units (100, 200, 300) as the blower 40 of the purifier 50 is operated to rotate the waste water from the lower side to the upper side, bubbles are generated to vaporize the discharge and active function of water molecules It will assist in the expansion.

In addition, the far-infrared rays emitted from the purifier 50 select and culture a common anaerobic soil bacteria group, and the culture bacteria inhibit the propagation of the perishable bacteria group so that BOD (biochemical oxygen demand), COD (chemical oxygen demand), and MLSS ( By controlling the concentration of suspended solids), the waste water can be used as recycled water.

Therefore, waste sludge from wastewater is reduced, and activated sludge is stably induced and purified.

The present invention as described above is to be able to purify the waste water using the mineral activated by the far-infrared emissivity by heat treatment, according to the present invention is as follows.

First, by purifying the waste water within a short time, it has the effect of improving the purification of the waste water.

Second, due to the activation of water molecules in accordance with the far infrared emission has the effect of inhibiting, disinfecting and deodorizing the decaying bacteria.

Third, the replacement of the purification agent has the effect of simplifying.

Claims (6)

A case having a plurality of through holes having a predetermined size formed on an outer circumference thereof and having a predetermined volume of space therein; And a far-infrared emitter, which is accommodated inside the case and has a granite and minerals of sedimentary rock that have been heat-treated at a predetermined temperature to emit far-infrared rays at an appropriate ratio. The waste water purification agent according to claim 1, further comprising a blower provided at one side of the case to rotate the waste water therein to generate bubbles. The wastewater purification agent according to claim 1 or 2, further comprising at least one auxiliary case accommodating granite and sedimentary rock having particles of a different size from the mineral in the case. A heat treatment step of activating far-infrared emissivity of minerals by applying heat above a predetermined temperature to minerals of granite and sedimentary rock having porosity; A mixing step of mixing the heat-treated minerals at an appropriate ratio according to the components of the wastewater; And a crushed stone step of crushing the mixed mineral into a particle size of a predetermined size. A first processor for heat treatment to precipitate a purifier composed of minerals activated with far-infrared emissivity in a predetermined amount of wastewater, to capture and settle contaminants in the wastewater, and to discharge the vaporized gas; A second processor for assisting bacterial growth by accelerating and neutralizing a redox reaction of the waste water which is precipitated by a predetermined amount and supplied through the first processor; And a third processor for inhibiting and sterilizing the propagation of contaminating bacteria by activating the water molecules of the wastewater supplied from the second processor by precipitating a predetermined amount of the purifier. The purification system using wastewater purification agents according to claim 5, wherein the first, second and third treatment units are each provided with a blower for rotating the wastewater.