KR200361879Y1 - Media for culturing microorganisms - Google Patents

Abstract

The present invention relates to a microbial carrier for water purification for biologically purifying contaminated river water, and more particularly, to a microbial carrier characterized in that a porous mat is installed in the center of a spherical carrier frame.

The microbial carrier according to the present invention is a spherical carrier frame made by combining the hemispherical upper frame and the lower frame made of a plurality of ribs (skeleton) with each other; It consists of a porous mat interposed between the hemispherical upper frame and the lower frame integrally coupled, characterized in that the opening of a predetermined size is formed in the center of the porous mat.

Description

Microbial carrier for wastewater treatment {Media for culturing microorganisms}

The present invention relates to a microbial carrier for water purification for biologically purifying contaminated river water, and more particularly, to a microbial carrier characterized in that a porous mat is installed in the center of a spherical carrier frame.

Generally, rivers with high concentrations of water pollution have been used as catalytic oxidation methods utilizing microbial carriers as biological treatment methods. The catalytic oxidation method is a method of laminar flow which directly purifies microorganism carriers by flowing river water, and a method of purifying by filling microbial carriers in the coriander site, inner water, or exclusion area by inducing river water from the stream. have. This catalytic oxidation method is suitable for the case of high water pollution due to the high efficiency of removing pollutants, and thus is a suitable method for purifying streams contaminated by inflow of sewage or wastewater.

On the other hand, as the microbial carrier used in the catalytic oxidation method, existing shapes such as gravel, waste tires, crushed stone, and waste wood were used or fibrous materials considering plastic foam or specific surface area were used. However, existing shapes such as gravel and waste tires have a disadvantage in that the size of the purification device is increased because the filling amount of the carrier must be increased due to the low porosity to which microorganisms can be attached. Therefore, recently, various types of plastic carriers have been used. In the case of such plastic carriers, the physical strength of the plastic carriers is easily broken, which may prevent the pipes installed in the treatment plant or cause a failure of the pump. There was. Particularly, when the plastic sphere is filled with a porous medium, the biofilm formed on the carrier is detached due to lack of water permeability due to activated microorganisms after installation, resulting in a blockage phenomenon. In addition, when only plastic is used as the material of the carrier, there is a problem in that the preparation of the carrier is easy, but the biofilm formation is difficult because the surface of the plastic carrier is dense and smooth.

The present invention has been made to solve the problems and deficiencies of the prior art, and the main object of the present invention is to provide high treatment efficiency even at a short reaction time in order to economically handle high pollutant loads for flow rates and flow rates, which are general characteristics of rivers. It is to provide a microorganism carrier exclusively for rivers.

The present invention also provides a high porosity on the surface of the microbial carrier by mixing plastic (PE), ceramic (zeolite) and activated carbon to prevent desorption of biofilms formed on the surface of the carrier and facilitate the microbial adhesion of the carrier. To provide a microbial carrier that maximizes and enhances the physical strength.

In addition, the present invention is to install a porous mat in the center of the spherical carrier frame in order to promote the microbial adhesion, the opening of the predetermined size in the center of the porous mat and the spherical carrier frame is composed of a plurality of rib (rib) By providing a microbial carrier to facilitate the flow of water and bubbles.

In addition, the present invention prevents the microbial carrier from being concentrated on one side of the purification apparatus by the flow or aeration of the river water, and prevents the treatment efficiency from being reduced, and easily adjusts the filling rate of the carrier as necessary. It provides a cartridge-type loading stand.

Biofilm carrier according to the present invention for achieving the above object is a spherical carrier frame made by combining the hemispherical upper frame and the lower frame made of a plurality of ribs (skeleton) with each other; It is composed of a porous mat interposed between the hemispherical upper frame and the lower frame integrally coupled.

The opening of the predetermined size is formed in the center of the porous mat.

The hemispherical frame includes a small ring at the upper side, a large ring formed at a distance from the outside of the lower ring and the lower ring at a predetermined distance, and the small ring at the upper side, the small ring at the bottom, and the large ring connected to each other. It is composed of a plurality of rib (rib) to form a hemisphere.

And at the bottom of the hemispherical upper frame and the hemispherical lower frame is a coupling means for coupling the hemispherical upper frame and the lower frame to each other.

In addition, a cylindrical space portion is formed by a plurality of vertical ribs in the center of the hemispherical frame to facilitate the flow of water and bubbles, and a flat support portion is formed by a plurality of horizontal ribs on the lower part of the hemispherical frame to form a porous mat. It is configured to be fixed.

On the other hand, the present invention is characterized in that at least one ball (Ball) is installed therein to reinforce the buoyancy of the spherical carrier frame.

1 is a perspective view showing a microbial carrier according to the present invention,

Figure 2 is an exploded perspective view showing a microbial carrier according to the present invention,

Figure 3 is a side cross-sectional view and enlarged view showing the coupling means of the hemispherical upper frame and the lower frame of the microbial carrier according to the present invention,

Figure 4 is a perspective view showing an example of a cartridge-shaped loading stand is filled with a microbial carrier according to the present invention.

*** Explanation of symbols for main parts of drawing ***

1: microbial carrier 10: spherical carrier frame

20: porous mat 30: hemispherical upper frame

40: hemispherical lower frame 31,41: small ring at the top

33,43: small ring at the bottom 35, 45: big ring

37, 47: cylindrical space part 38, 48: support part

60: coupling means 63: upper annular frame

64: lower annular frame 99: ball

Hereinafter, a microbial carrier according to the present invention will be described in detail with reference to the accompanying drawings.

First is a perspective view showing a microbial carrier according to the present invention. As shown, the microbial carrier 1 according to the present invention is largely composed of a spherical carrier frame 10 and a porous mat 20 installed in the center of the spherical carrier frame 10. The spherical carrier frame 10 is further divided into a hemispherical upper mold 30 and a hemispherical lower mold 40. In this case, the porous mat 20 is a mat having a loofah-like structure having a predetermined thickness, and an opening 23 having a predetermined diameter is formed therein. And the microbial carrier 1 according to the present invention is interposed between the porous mat 20 between the hemispherical upper mold 30 and the lower mold 40, the hemispherical upper mold 30 and the lower mold 40 It is made by combining with each other. On the other hand, reference numeral 99 is a ball installed in the spherical carrier frame 10 to reinforce the buoyancy of the microorganism carrier (1).

Figure 2 is an exploded perspective view showing a microbial carrier according to the present invention, as shown, the hemispherical upper and lower frames 30, 40, the upper (or lower) of the small ring (31,41) and the lower Small rings (33,43) and the large rings (35,45) formed to be spaced apart a predetermined distance outside the small rings (33,43) of the lower, the small rings (31,41) of the upper, the small of the lower A plurality of ribs (skeleton) connecting the rings 33 and 43 and the large rings 35 and 45 to each other to form a hemispherical body of a predetermined size, and the hemispherical upper mold 30 and the hemispherical lower mold 40 It is composed of a coupling means 60 for coupling.

In addition, cylindrical spaces 37 and 47 are formed in the middle of the hemispherical upper and lower frames 30 and 40 so as to facilitate the flow of water and bubbles, and a flat support portion in the lower (or upper part). 38 and 48 are formed to support the porous mat 20. That is, a plurality of vertical ribs 137 and 147 are formed at predetermined intervals between the upper small rings 31 and 41 and the lower small rings 33 and 43 to form cylindrical space portions 37 and 47 having a predetermined size. In addition, a plurality of horizontal ribs 138 and 148 are formed horizontally in the radial direction between the small rings 33 and 43 and the large rings 35 and 45 of the lower portion (or upper portion) to support the mat 20. The support portions 38 and 48 are formed, and a plurality of arcuate ribs 139 and 149 are formed with a predetermined curvature between the small rings 31 and 41 and the large rings 35 and 45 of the upper portion (or lower portion). The outer portions 39 and 49 are formed.

In addition, a plurality of intermediate vertical ribs 132 and 142 may be vertically installed between the middle of the arcuate ribs 139 and 149 and the middle of the horizontal ribs 138 and 148 to reinforce the strength of the sphere. In addition, if necessary, a plurality of intermediate horizontal ribs (not shown) are horizontally installed between the middle of the arc-shaped ribs 139 and 149 and the middle of the vertical ribs 137 and 147, or the center of the horizontal ribs 138 and 148. It is also possible to further form a plurality of connecting ribs not shown connecting the parts.

On the other hand, one example of the coupling means 60 for coupling the hemispherical upper mold 30 and the hemispherical lower mold 40, the upper annular frame 63 is formed by extending a predetermined length to the lower end of the hemispherical upper mold 30 ), A lower annular frame 64 formed to extend a predetermined length to an upper end of the hemispherical upper frame 40 and to surround the outer circumferential surface of the upper annular frame 63, and an outer peripheral surface of the upper annular frame 63. It consists of a plurality of coupling jaw 66 formed in, and a plurality of coupling holes 68 formed to penetrate the lower annular frame 64 to be inserted into the coupling jaw (66). In this case, the upper annular frame 63 and the lower annular frame 64 are coupled to each other to form a settling portion having a predetermined height on which the annular mat 20 is placed. On the other hand, it is also possible to permanently fix the coupling jaw (66) protruding to the outer peripheral surface of the lower annular frame (64). In addition, it is also possible to heat-bond all the joint portions of the outer peripheral surface of the upper annular frame 63 and the inner peripheral surface of the lower annular frame 64.

On the other hand, the porous mat 20 is to have a scouring pad-like structure of coarse woven with a thin yarn having a thickness of 20 ~ 1000㎛ in order to improve the adhesion ability of the microorganism, has a thickness of approximately 5-20mm. At this time, the yarn is hydrophilic and has high microbial adhesion, corrosion resistance and durable like polyethylene yarn. The scrubber-shaped reticulated weave increases the surface area that microorganisms can stick to per unit area, and allows water and bubbles to communicate smoothly inside the mat. In addition, an opening 23 having a predetermined diameter is formed in the center of the porous mat 20.

On the other hand, the porous mat 20 is interposed between the hemispherical upper mold 30 and the hemispherical lower mold 40 is fixed integrally and is placed in the settled portion formed in the center of the spherical mold 10. At this time, the opening part 23 formed in the center of the mat 20 is integral with the cylindrical spaces 37 and 47 formed up and down at the center of the spherical mold 10.

Forming the opening 23 in the center of the porous mat 20 is, after applying the microbial carrier to the water purification device, the center portion is cut in order to prevent anaerobicization at the center of the mat due to the vigor of the microorganisms. This is to prevent obstruction by allowing water and bubbles to communicate smoothly. In particular, the present invention matches the cylindrical spaces 37 and 47 formed in the spherical frame 10 and the openings 23 of the mat 20 so as to communicate with each other to smoothly pass water and backwash when necessary. Do it.

And the spherical carrier frame 10 is made of a circular or oval to enhance the physical strength, and has a wire frame form by a plurality of ribs spaced at predetermined intervals so as to smoothly pass through the mat (20). In this case, the spherical carrier mold 10 is injection molded into two upper and lower hemisphere molds 30 and 40 by using a predetermined synthetic resin material, and is then integrally coupled through the coupling means 60. And the carrier frame 10 according to the present invention is mixed with a predetermined functional additive in the synthetic resin material to induce the microbial adhesion. For example, as the functional additive, ceramic (zeolite), activated carbon powder and elite are used.

For example, the composition ratio of the carrier frame 10 is 5-15% by weight of zeolite, 5-15% by weight of activated carbon powder, 5-7% by weight of illite and 63-85% by weight of polyethylene as base material. It is characterized by. At this time, zeolite (Zeolite) of the additives serves to separate the ammonia from the river water by the ionization reaction. That is, it is very difficult to proliferate microorganisms (nitrosomonas, nitrobacter) which decompose ammonia nitrogen in a short reaction time (ca. 1.5hr) and biochemically treat it with nitrate. Substituting ammonia, the nitrate microorganisms can be slowly and chemically removed.

The other additive, activated carbon, is to increase the sticking ability because the microorganisms are excellent in sticking power, and the illite is to increase the porosity. However, the composition ratio of the material cost can be changed according to the function of the carrier required, and each material can also be changed. On the other hand, when various additives are added to the plastic substrate as described above, since the buoyancy of the spherical carrier frame 10 is dropped, it is preferable to put one or more balls 99 into the carrier frame to reinforce it. At this time, the ball 99 is a closed ball made of a thin plastic material and has a diameter that can impart sufficient buoyancy while not disturbing the flow of water as much as possible. For example, when the diameter of the spherical carrier frame 10 is 140mm, the diameter of the ball 99 is preferably 70mm or less.

Next, Figure 4 shows an example of a cartridge-shaped loading stand for fixedly filling the microbial carrier according to the present invention. The cartridge holder (70) is a rectangular body frame 74 consisting of a large number of frame angles 71, plastic nets 72 and a plurality of frame bars 73 and the upper surface of the main body frame 74 In addition to the slide cover 80 to move up and down along the guide rod 81 is installed vertically in the main body frame 74, the swing door 90 is installed on one side of the main body frame (74) It consists of. At this time, both sides of the slide cover 80 is formed with a guide ball 83 that slides along the guide rod 81, and one side of the swing door 90 is provided with a hinge 91.

On the other hand, the plastic net 72 installed in the main body frame 74 prevents the microbial carrier 1 filled therein from coming out, and the frame bar 73 prevents the plastic net 72 from sagging. Rather, it is installed at predetermined intervals between the frame angles 71 to secure the main body frame 74. The slide cover 90 is always pressed downward by gravity to adjust the height of the slide cover 80 according to the amount of the microbial carrier 1 filled in the body frame 74 so that the microbial carrier 1 ) Can be fixed. At this time, the slide cover 80 is also preferably provided with a separate fixing means not shown for fixing the cover at a predetermined height. In addition, the opening door 90 may be opened and closed when filling or replacing the microbial carrier, so that the microbial carrier is easily filled out of the purifier and the microorganisms filled with a plurality of microbial carriers are directly introduced into the purifier. Filling of the carrier can be performed quickly.

As described above, the microbial carrier according to the present invention has a structure in which the microbial carriers are easily adhered to the microorganisms, and the water and air can be well flowed even after the microorganisms are easily adhered. The filling rate of the carrier at the scale can be increased, and the efficiency of river water purification by the catalytic oxidation method using a biofilm can be improved.

In addition, the present invention has the effect of preventing the detachment of the biofilm by increasing the strength of the carrier by replenishing the functional additives to the ash of the carrier and the porous surface to enhance the adhesion of the microorganisms.

In addition, the present invention can be filled in a fixed form by using a predetermined cartridge-type loading stand can increase the filling rate of the carrier to improve the purification efficiency and easy maintenance of the carrier.

Claims (9)

A spherical carrier frame formed by combining a hemispherical upper frame and a lower frame composed of a plurality of ribs with each other; Microbial carrier, characterized in that it comprises a porous mat of a predetermined thickness interposed integrally between the hemispherical upper frame and the lower frame. The method of claim 1, The porous mat is a microbial carrier, characterized in that the disk-like structure having a scouring pad-like tissue coarsely woven with fine yarns, the opening having a predetermined diameter formed therein. The method of claim 1, The hemispherical upper and lower frames include a small ring at the upper side, a large ring formed at a predetermined distance from the outside of the lower ring and the lower ring, and the small ring at the upper side, the small ring at the bottom, and the large ring. It is composed of a plurality of ribs (rib) connected to each other to form a hemisphere, and the coupling means for coupling the hemispherical upper frame and the lower frame is further provided at the bottom of the large ring of the hemispherical upper frame and the hemispherical lower frame Microbial carrier. The method according to claim 1 or 3, A cylindrical space portion is formed by a plurality of vertical ribs in the middle of the hemispherical frame to smooth the flow of water and bubbles, and a flat support is formed by a plurality of horizontal ribs on the lower part of the hemispherical frame to form a porous mat. A microbial carrier, characterized in that configured to support. The method according to claim 1 or 3, The hemispherical mold is a microbial carrier, characterized in that injection molded into a synthetic resin material containing a functional additive such as zeolite, activated carbon powder, illite. The method of claim 5, The hemispherical mold is 5 to 15% by weight zeolite, 5 to 15% by weight activated carbon powder, 5 to 7% by weight illite and 63 to 85% by weight polyethylene as a base material. The method according to claim 1 or 2, The porous mat is a microorganism carrier, characterized in that it has a thickness of 5 to 20mm in the form of a loofah-type tissue coarsely woven with a thin yarn having a thickness of 20 to 1000 μm. The method of claim 1, The microorganism carrier, characterized in that one or more balls are added to the inside of the carrier frame to reinforce buoyancy. The method of claim 1, The spherical microorganism carrier is moved up and down along a rectangular main frame consisting of a plurality of frame angles, plastic nets and a plurality of frame bars, and a guide rod installed vertically inside the main body frame while forming an upper surface of the main body frame. A microorganism carrier, characterized in that the plurality of the fixed filling in the interior of the cartridge-shaped loading rack consisting of a sliding cover and a hinged door hingeably installed on one side of the main body frame.