JPH10235384A - Microbe immobilization support - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a microbe immobilization support which can maintain sufficient property for water to flow in the inside and which can retain a sufficient amount of microbe. SOLUTION: This microbe immobilization support 1 is formed by randomly intertwining thermally melted fibers 2 of polypropylene and carries microbe on the thermally melted fibers 2. The thermally melted fibers 2 have 50-3000 denier thickness and 750-2000g/m<3> fiber density. The outer shape of the microbe immobilization support 1 is an approximately rectangular parallelopiped shape with 10-100mm one side length. Consequently, without deteriorating water flowing property in the inside of the support by activated sludge adhering to the surface, a sufficient amount of microbe can be deposited. The support has a large surface area and carries much more microbe and provides high purification treatment performance. Due to high rolling resistance, the support hardly moves in the treatment tank and scarcely flows out.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a microorganism-immobilized carrier for retaining microorganisms in a process for purifying suspended substances and oils and fats in wastewater using microorganisms.

[0002]

2. Description of the Related Art Conventionally, there is a method for purifying organic wastewater such as food factory wastewater, kitchen wastewater of hotels and restaurants, general sewage, domestic wastewater, and paper mill wastewater by using microorganisms. By the way, the size of microorganisms used in this treatment is very small, one micron of which is several microns.
It is difficult to always keep only microorganisms suspended and dispersed in a free state in the treatment tank. For this reason, the following two methods have been used to hold microorganisms in the treatment tank.

The first method is a standard activated sludge / long-time aeration method. According to this method, a coagulated body formed in a water tank by the cohesive force of microorganisms is used as activated sludge. Since this method does not use a carrier, the effective volume of the treatment tank is large, which is preferable from the viewpoint of volumetric efficiency. However, since the agglomeration of the microorganisms is left to the natural assembly of the microorganisms themselves, not only does it take time to form the agglomerates, it is difficult to reliably form the agglomerates, and the processing efficiency and reliability are reduced.

[0004] The second method is a catalytic oxidation method. In this method, a material to which microorganisms are liable to adhere, such as a porous carrier, is charged into a water tank, and a microbial film is formed on the surface of the material to perform a drainage treatment. However, in the case of using a porous carrier as described above, even if the surface area of the carrier is large, a part that is not effectively used is formed inside, and the carrier itself reduces the effective volume of the treatment tank, and the treatment efficiency is reduced.

Under such circumstances, for example, Japanese Patent Application Laid-Open No. 6-55187 attempts to maintain the effective volume of a treatment tank by using spherically entangled fibers as a carrier and carrying microorganisms inside or on the surface. The disclosed method for immobilizing microorganisms is disclosed.

[0006]

However, in the conventional microorganism-immobilized carrier, depending on the thickness and fiber density of the fiber,
It has been difficult to maintain a sufficient amount of microorganisms while maintaining sufficient water flow. If the fiber thickness is thin and the fiber density is high, it is possible to attach a large amount of microorganisms,
Since the space between the fibers is also narrow, the water flow into the carrier is deteriorated within a short period of time due to clumps of microorganisms and attached activated sludge. On the other hand, if the fibers are thick and the fiber density is low, the water flow can be maintained, but the microorganisms cannot be carried in a sufficient amount for the treatment, and the treatment capacity becomes insufficient.

[0007] Further, since the conventional microorganism-immobilized carrier is spherical, the production process tends to be complicated and the cost tends to be high. Further, since the sphere is a sphere, it easily moves in the processing tank, and may flow out of the processing tank through the discharge hole. An object of the present invention is to provide a microorganism-immobilized carrier that can maintain sufficient water flow into the carrier and can retain a sufficient amount of microorganisms.

Another object of the present invention is to provide a microorganism-immobilized carrier which can be produced relatively easily and is hardly moved in a treatment tank.

[0009]

SUMMARY OF THE INVENTION The object of the present invention is to provide a microorganism-immobilized carrier comprising heat-fused fibers of polypropylene randomly entangled and carrying microorganisms on the heat-fused fibers. fibers have a thickness of 50 to 3000 denier, achieved by microorganism immobilization pellets and having a fiber density of 750~2000g / m ^3.

[0010] Thereby, a sufficient amount of microorganisms can be held without impairing the water flow into the carrier due to the activated sludge attached to the surface. In the microorganism-immobilized carrier described above, the outer shape has a length of one piece of 10
It is desirably a substantially rectangular parallelepiped shape of about 100 mm. Thus, after a large mass is first formed from the heat-fused fibers, it is only necessary to cut the mass vertically and horizontally, so that the production is easy. In addition, the surface area is large, so that more microorganisms can be supported, and a high purification treatment capacity can be obtained. Further, since the rolling resistance is large, it is hard to move in the processing tank and does not flow out.

In the carrier for immobilizing microorganisms described above, it is desirable that the heat-fused fibers have a thickness of 1000 to 2300 denier. In addition, the above-mentioned microorganism-immobilized carrier desirably has a fiber density of 1000 to 1500 g / m ³ . In the carrier for immobilizing microorganisms described above, raw water may be stored and charged into a water tank to which air or oxygen is supplied, and the raw water in the water tank may be purified by the microorganisms carried.

In the above-described catalytic oxidation type biological treatment apparatus using the microorganism-immobilized carrier, the microorganism-immobilized carrier is charged into a water tank, and air or oxygen is supplied into the water tank to remove the raw water in the water tank. Purification treatment is performed by microorganisms carried on the microorganism-immobilized carrier.

[0013]

DESCRIPTION OF THE PREFERRED EMBODIMENTS A microorganism-immobilized carrier according to one embodiment of the present invention will be described with reference to the drawings. FIG. 1 is an external perspective view of the microorganism-immobilized carrier according to the present embodiment.
As shown in the figure, the microorganism-immobilized carrier 1 is composed of a large number of fibers 2 randomly entangled, and has a substantially cubic outer shape. In consideration of the use environment to be described later, the fiber 2 has a high water resistance without being degraded by hydrolysis and has a shape that is not changed or loosened by a water flow in a water tank. What is used, for example, a heat fusion fiber typified by polypropylene is used. This utilizes the properties of the heat-fused fibers, such as melting by heating, after forming the base material of the microorganism-immobilized carrier, by heating, partially melted between the entangled fibers and integrated, This enhances the holding force of the carrier shape.

The fibers 2 used preferably have a thickness of 50 to 3,000 denier and a fiber density of 750 to 2,000 g / m ³ from the viewpoint of ensuring the flow of water after the formation of the carrier. . More preferably, the fibers 2 used have a thickness of 1000 to 2300 denier,
It is desirable to have a fiber density of 1000~1500g / m ^3.

The reason why the thickness of the fibers 2 is set in the above-mentioned range is that when the microorganism-immobilized carrier 1 is formed by the fibers 2 which are too thin, so many fibers are exposed on the surface of the carrier, and in the wastewater treatment process, Granular agglomerates of microorganisms are formed on the surface of the carrier relatively early,
Because the spacing between the fibers is small, the activated sludge adhering to the surface impairs the water flow into the inside of the carrier, and the central part of the carrier is not treated by microorganisms, so that the treatment capacity is reduced as a whole.

On the other hand, when the microorganism-immobilized carrier 1 is formed by the fibers 2 which are too thick, the flowability of raw water into the carrier 1 is improved, but the degree of entanglement between the fibers 2 is reduced. This is because microorganisms are less likely to adhere. This is the same for the fiber density as well.
In 200 g / m overcrowding that ³ more than microbe immobilizing carrier 1, the processing capacity in order to water flow of the carrier central portion is impaired is low, conversely, the sparsely populated state as less than 750 g / m ³ This is because the microorganism-immobilized carrier 1 hardly adheres microorganisms, and similarly has a low processing capacity.

The microorganism-immobilized carrier 1 composed of such fibers 2 has a side of 10 to 100 mm in consideration of the capacity of the existing wastewater treatment tank and the action of purifying the wastewater of attached microorganisms.
It is formed in a substantially cubic shape. With this shape, the surface area can be increased even when compared with a spherical carrier having the same weight, and a higher purification treatment capacity can be obtained by supporting more microorganisms. Further, since this shape has a high rolling resistance, it is difficult to move in the processing tank and does not flow out.

The true specific gravity of the microorganism-immobilized carrier 1 of the present invention is lower than that of water (0.90 to 0.91). However, when the microorganisms start to adhere and proliferate, the true specific gravity becomes close to 1 and almost all of them are in a state of flowing and flowing in water, thereby exhibiting the processing ability. Next, the method for producing the microorganism-immobilized carrier according to the present embodiment will be described with reference to FIG.

First, as shown in FIG. 2 (a), a large amount of randomly-curved polypropylene fiber 2 is prepared as a raw material, put into a carrier base material mold 3, and pressed while applying vibration. . Thereby, the fibers 2 are complicatedly entangled in the mold, and the carrier base material 4 having the shape of the carrier base material 3 is formed. Next, as shown in FIG.
While being held in the base material mold 3, it is carried into the heating furnace 5,
Heating. As described above, since the polypropylene fiber 2 is a heat-fused fiber, the surface thereof is melted when heated, and the fibers are intertwined with each other, and
Joined via the melted fiber part. As a result, after cooling, the bonding force between the entangled fibers 2 is increased, the rigidity of the entire carrier base material 4 is improved, and the shape retention force is increased.

After the carrier base material 4 thus formed is obtained, the carrier base material 4 is cut by the cutter 7 in the vertical and horizontal directions and in the horizontal direction. Thus, a substantially cubic microorganism-immobilized carrier 1 as shown in FIG. 1 is finally obtained. Next, a contact oxidation type biological treatment apparatus using the microorganism-immobilized carrier according to the present embodiment will be described.

FIGS. 3 and 4 show waste water purification tanks 8 and 9 which are contact oxidation tanks using the microorganism-immobilized carrier 1 according to the present embodiment. 3 (a) and 4 (a) are plan views, and FIGS. 3 (b) and 4 (b) are cross-sectional views. The drainage purification tank 8 shown in FIG. 3 uses a cylindrical casing 30. The waste water purification tank 8 is connected to the raw water pipe 31 through
OD (biological oxygen demand), SS (suspension), n-
Organic wastewater H containing H (animal / vegetable fat) is supplied continuously or intermittently. Wastewater septic tank 8
The microorganism-immobilized carrier 1 according to the present embodiment and microorganisms are charged therein. At the bottom of the cylindrical casing 30,
Oxygen is supplied from outside via the air supply pipe 32.

The waste water purification tank 9 shown in FIG. 4 uses a rectangular parallelepiped casing 40. Organic wastewater H including BOD (biological oxygen demand), SS (suspension material), nH (animal / vegetable fat) is continuously supplied to the wastewater purification tank 9 via a raw water pipe 41. Or it is supplied intermittently. The microorganism-immobilized carrier 1 according to the present embodiment and microorganisms are charged into the wastewater purification tank 9. Oxygen is externally supplied to the bottom of the rectangular parallelepiped casing 40 via an air supply pipe 42.

As described above, in the wastewater purification tanks 8 and 9, the microorganisms adhere to the microorganism-immobilized carrier 1 dispersed in the wastewater and form granulated agglomerates. Then, the microorganisms supported on the microorganism-immobilized carrier 1 are activated by the oxygen dissolved in the wastewater, and decompose each component of the wastewater described above. The treated wastewater is taken out of the casings 30 and 40 via the treated water discharge pipes 33 and 43 installed at the bottom, and sent to the subsequent treatment process.

The present invention is not limited to the above embodiment, and various modifications are possible. For example, in the above embodiment, the microorganism-immobilized carrier has a substantially cubic shape, but may have another shape such as a substantially rectangular parallelepiped shape.

[0025]

EXAMPLES In order to confirm the effect of the present invention, wastewater was purified by a wastewater purification tank using a conventional microorganism-immobilized carrier and a wastewater purification tank using the microorganism-immobilized carrier 1 according to the present invention, and various types of raw water were purified. The components and the components in the treated water were compared.
The comparison results are shown in Table 1 below. The wastewater purification tanks used were the same in size, and the treatment time was the same.

[0026]

[Table 1]

As apparent from Table 1, BOD, S
In all the components of S and n-H, when the microorganism-immobilized carrier according to the present invention was used, it was recognized that there was a remarkable purifying action as compared with the case where the conventional microorganism-immobilized carrier was used. Was. Thus, it was confirmed that the use of the carrier of the present invention enhances the purifying action of microorganisms.

[0028]

As described above, according to the present invention, there is provided a microorganism-immobilized carrier comprising heat-fused fibers of polypropylene randomly entangled and carrying microorganisms on the heat-fused fibers. The fused fibers had a thickness of 50 to 3000 denier and a fiber density of 750 to 2000 g / m ³ , so that the activated sludge deposited on the surface allowed the water to flow into the carrier. Can maintain a sufficient water flow without being impaired, and can retain a sufficient amount of microorganisms.

According to the present invention, the microorganism-immobilized carrier is formed in a substantially rectangular parallelepiped shape having a length of one piece of 10 to 100 mm, so that it can be manufactured relatively easily. It is hard to move and can be prevented from flowing out.

[Brief description of the drawings]

FIG. 1 is an external perspective view of a microorganism-immobilized carrier according to an embodiment of the present invention.

FIG. 2 is an explanatory diagram illustrating a method for producing a microorganism-immobilized carrier according to one embodiment of the present invention.

FIG. 3 is a view showing a cylindrical contact oxidation tank using a microorganism-immobilized carrier according to an embodiment of the present invention.

FIG. 4 is a view showing a rectangular parallelepiped contact oxidation tank using a microorganism-immobilized carrier according to an embodiment of the present invention.

[Explanation of Signs] 1 ... Carrier for immobilizing microorganisms 2 ... Heat-fused fiber 3 ... Carrier base material type 4 ... Carrier base material 5 ... Heating furnace 6 ... Heater 7 ... Cutter 8,9 ... Drainage purification tank 30, 40 ... Casing 31 , 41 ... raw water pipe 32, 42 ... air supply pipe 33, 43 ... treated water extraction pipe

Claims (6)

[Claims] 1. A microorganism-immobilized carrier in which heat-fusible fibers of polypropylene are randomly entangled and carry microorganisms on the heat-fusible fibers, wherein the heat-fusible fibers have a denier of 50 to 3000 deniers. A microorganism-immobilized carrier having a thickness and a fiber density of 750 to 2000 g / m ³ . 2. The microorganism-immobilized carrier according to claim 1, wherein the outer shape is a substantially rectangular parallelepiped shape having a length of one piece of 10 to 100 mm. 3. The microorganism-immobilized carrier according to claim 1, wherein the heat-fused fibers have a thickness of 1,000 to 2,300 denier. 4. The microorganism-immobilized carrier according to claim 1, wherein the microorganism-immobilized carrier has a fiber density of 1000 to 1500 g / m ³ . 5. The microorganism-immobilized carrier according to any one of claims 1 to 4, wherein the raw water is stored and charged into a water tank to which air or oxygen is supplied, and the raw water in the water tank is loaded. A microorganism-immobilized carrier, which is subjected to a purification treatment by using a microorganism. 6. The microorganism-immobilized carrier according to any one of claims 1 to 4 is charged into a water tank, and by supplying air or oxygen into the water tank, the raw water in the water tank is removed. A catalytic oxidation type biological treatment apparatus, wherein a purification treatment is performed by microorganisms carried on a microorganism-immobilized carrier.