KR100949346B1 - Apparatus for treating Sludge - Google Patents

Abstract

The present invention relates to a sludge treatment apparatus, the outer cylinder member extending in the vertical direction and having a closed space portion, and is disposed coaxially with the outer cylinder member in the central portion of the outer cylinder member, the upper portion is located in the outer cylinder member and the lower portion is An inner cylinder member extending downward of the outer cylinder member and a lower portion of the outer cylinder member are provided at a lower end of the outer cylinder member so that treated raw water including sludge flows between the outer cylinder member and the inner cylinder member, and a central axis line is disposed at a position not meeting the central axis line of the outer cylinder member. A plurality of inlet pipe members, an inlet provided at an upper end of the inner cylinder member, an outlet provided at an upper end of the outer cylinder member, and a plurality of inlets formed on the inner circumferential surface of the outer cylinder member, and upstream in the flow direction of the treated water introduced between the outer cylinder member and the inner cylinder member; Flow section area of the side part is larger than flow section area of the downstream part A first reduction tube member, a circulation pipe member having one end connected to a lower end of the inner cylinder member and the other end connected to a lower end of the outer cylinder member, an ozone generator connected to the inflow pipe member, and introduced into the inner cylinder member. And a pressurized pump connected to the circulation pipe member to circulate the treated raw water flowing into the lower end of the inner cylinder member into the outer cylinder member, and a first flow control valve for adjusting the flow rate of the treated raw water flowing out through the outlet. And a second flow rate control valve for controlling the flow rate of the raw water circulated through the circulation pipe member.

Description

Sludge Treatment Unit {Apparatus for treating Sludge}

The present invention relates to an apparatus for treating sludge contained in raw water, and more particularly, to a sludge treatment apparatus for solubilizing and atomizing sludge.

Conventionally, water is treated by treating raw water containing sludge, such as food waste, leachate, livestock waste, sewage, etc. of the food waste, to purify the water, and at the same time, the sludge is embedded in the soil in the form of agglomerate or dumped in the ocean. It was. However, in this case, the leachate flows out of the landfill in which the sludge in the form of lumps is landfilled, and the environment is seriously polluted. Therefore, in recent years, by administering ozone or chemicals to the sludge, solubilizing the sludge by a chemical reaction with the sludge or by administering microorganisms to the sludge to reduce the amount of sludge, In addition, research on a process that can energize the sludge has been actively conducted.

On the other hand, the process as described above may be carried out effectively by injecting ozone or chemicals to promote the solubilization of the sludge, and atomize the sludge.

By the way, an apparatus for atomizing while effectively solubilizing the sludge in the raw water has not been developed until now. In particular, when the raw water is raw water containing sludge combined with microorganisms, the sludge is solubilized and atomized because the sludge is stuck to the outermost layer of mucous substances surrounding the cell wall of one microorganism or a group of microorganisms, so that the sludge does not easily fall off. There was a problem that was not easy.

The present invention has been devised in consideration of the above-described matters, and it is possible to easily solubilize and atomize sludge in the raw water, especially when the raw water is treated water containing sludge combined with microorganisms, It is an object of the present invention to provide a sludge treatment apparatus in which sludge can be easily solubilized and atomized by effectively removing a mucus material from a cell wall.

Sludge treatment apparatus according to the present invention for achieving the above object, the outer cylinder member extending in the vertical direction and having a closed space portion, the central portion of the outer cylinder member is disposed coaxially with the outer cylinder member, the upper portion is Located in the outer cylinder member, the lower portion is provided at the lower end of the inner cylinder member so that the raw material including sludge flows between the outer cylinder member and the inner cylinder member extending downward of the outer cylinder member, and between the outer cylinder member and the inner cylinder member. An inflow pipe member having a central axis disposed at a position not meeting the center axis of the outer cylinder member such that the raw water flowing therein is rotated between the outer cylinder member and the inner cylinder member; The treatment raw water introduced between the inner cylinder member is the upper side of the outer cylinder member An inlet provided in the upper end of the inner cylinder member to flow into the cylinder member, and the treatment raw water introduced into the inner cylinder member through the inlet to be discharged from the upper side of the outer cylinder member to the outside of the outer cylinder member; A plurality of outlets provided in the plurality of outlets and the inner circumferential surface of the outer cylinder member, wherein the first cross-sectional area of the upstream portion in the flow direction of the raw water introduced between the outer cylinder member and the inner cylinder member is larger than the flow cross-sectional area of the downstream portion; One end is connected to the lower end of the inner cylinder member and the other end is connected to the lower end of the outer cylinder member so that the tube member and the raw water flowing into the inner cylinder member and flowed into the lower end of the inner cylinder member can be circulated into the inner cylinder member. The circulating pipe member and the oil to supply ozone to the treated raw water flowing into the inlet pipe member. An ozone generator connected to the pipe member, a pressurized pump connected to the circulation pipe member to circulate the treated water flowing into the inner cylinder member and flowing to the lower end of the inner cylinder member into the outer cylinder member, and outflow through the outlet And a first flow control valve for adjusting the flow rate of the raw water to be treated, and a second flow control valve for adjusting the flow rate of the raw water circulated through the circulation pipe member.

In the sludge treatment apparatus according to the present invention, ozone for promoting solubilization is introduced into the raw water, the raw water is rotated and flowed, and cavitation occurs when the raw water flows, so that the sludge in the raw water is easily solubilized and atomized. In particular, even in the case of treated raw water including sludge combined with microorganisms, the sludge bound with the microorganism can be easily solubilized and atomized by effectively removing the mucous substances surrounding the cell wall of the microorganism from the cell wall. Can be.

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

1 is a schematic cross-sectional view of a sludge treatment apparatus according to an embodiment of the present invention, Figure 2 is a schematic perspective view of the main part of the sludge treatment apparatus shown in FIG. 3 is a cross-sectional view taken along line III-III of FIG. 1 to 3 indicate the flow direction of the raw water, and FIG. 1 shows the overall flow direction of the raw water for convenience of illustration, and the raw water flows while rotating as shown in FIG.

1 to 3, the sludge treatment apparatus 1 according to an embodiment of the present invention, the outer cylinder member 10, the inner cylinder member 20, the inlet pipe member 30, the inlet 40, the outlet 50, the first reduction pipe member 61, the ozone generator 70, the circulation pipe member 80, the pressure pump 90, the first flow control valve 100, the second flow control valve 110 Include.

The outer cylinder member 10 has a closed space and extends in the vertical direction.

The inner cylinder member 20 is disposed coaxially with the outer cylinder member 10 at the center of the outer cylinder member 10. The upper portion of the inner cylinder member 20 is located in the outer cylinder member 10 and the lower portion extends downward of the outer cylinder member 10.

The inflow pipe member 30 is provided so that the treated raw water including sludge flows between the outer cylinder member 10 and the inner cylinder member 20. The inflow pipe member 30 is provided at the lower end of the outer cylinder member 10, the raw water flowing between the outer cylinder member 10 and the inner cylinder member 20, the outer cylinder member 10 and the inner cylinder member 20 The inflow pipe member 30 is disposed such that the central axis C2 is placed at a position not meeting the central axis C1 of the outer cylinder member 10 so as to flow while rotating therebetween.

The inlet 40 is provided such that the raw water introduced between the outer cylinder member 10 and the inner cylinder member 20 flows into the inner cylinder member 20 from the upper end side of the outer cylinder member 10. The inlet 40 is provided at the upper end of the inner cylinder member 20. In this embodiment, the inlet 50 is a plurality of holes provided in the upper end of the inner cylinder member 20, through which the treatment sewage flows into the inner cylinder member 20.

The outlet 50 is provided so that the treated raw water introduced into the inner cylinder member 20 is discharged to the outside of the outer cylinder member 10 from the upper side of the outer cylinder member 10, the outlet 50 is the outer cylinder member ( 10) is provided at the upper end.

The said 1st reduction pipe member 61 is arrange | positioned in multiple numbers on the inner peripheral surface of the outer cylinder member 10. As shown in FIG. As shown in Fig. 1, the first reduction pipe member 61 has a larger flow cross-sectional area in the upstream portion in the flow direction A in which the raw water flows, compared to the downstream flow cross-sectional area. Therefore, the treated raw water passing through the first reduction pipe member 61 flows into the wider cross-sectional area on the upstream side in the flow direction A through which the treated raw water flows, and is discharged toward the smaller side of the downstream cross-sectional area. In the present embodiment, three first reduction tube members 61 are provided on the lower end side of the outer cylinder member 10, and three first reduction tube members 61 are provided on the discontinuous side of the outer cylinder member 10. .

The ozone generator 70 is connected to the inlet pipe member 30 to supply ozone to the treated raw water for solubilization of the treated raw water.

The circulation pipe member 80 is provided so that the treated water flowing into the inner cylinder member 20 and flowed to the lower end of the inner cylinder member 20 is circulated into the outer cylinder member 10, and one end thereof is the inner cylinder member. It is connected to the lower end of 20 and the other end is connected to the lower end of the outer cylinder member 10.

The pressurized pump 90 is connected to the circulation pipe member 80 and is provided to circulate the treated raw water flowing to the lower end of the inner cylinder member 20 to the outer cylinder member 10.

The first flow control valve 100 is provided to adjust the flow rate of the raw water flowing out through the outlet 50, the second flow control valve 110 is circulated through the circulation pipe member (80) It is provided to adjust the flow rate of the raw water to be treated.

In the sludge treatment apparatus 1 according to an embodiment of the present invention, the inlet pipe member 30 has a reduction part 31 in which the flow cross-sectional area is gradually narrowed toward the downstream side in the direction in which the raw water flows, and the ozone generator 70 is connected to the reduction part 31.

In addition, the sludge treatment apparatus 1 according to an embodiment of the present invention further includes a second reduction tube member 62.

The second reduction pipe member 62 is provided in plural on the outer circumferential surface of the inner cylinder member 20, and like the first reduction pipe member 61, the flow cross-sectional area of the upstream portion in the flow direction (A) of the raw water to be treated It is larger than the flow cross section of the downstream part. The treated raw water passing through the second reduction pipe member 62 flows in from the larger flow cross-sectional area in the flow direction A of the treated raw water, and is discharged toward the smaller cross-sectional area. In the present embodiment, three second reduction pipe members 62 are provided on the outer peripheral surface of the lower end side of the inner cylinder member 20, and three are provided on the outer peripheral surface of the middle side of the inner cylinder member.

Hereinafter, an example of the operation process of the sludge processing apparatus 1 by the said structure is demonstrated.

First, a raw water supply pump 210 is operated to supply raw water (process water including sludge combined with microorganisms) from the raw water tank 200 to the sludge treatment apparatus 1. When the raw water supply pump 210 is operated, raw water including sludge combined with microorganisms is introduced into the inlet pipe member 30 from the raw water tank 200. On the other hand, the amount of raw water supplied to the sludge treatment apparatus 1 from the raw water tank 200 may be adjusted by the raw water supply control valve 220.

When the raw water flows into the inlet pipe member 30, the raw water passes through the reduction part 31 of the inlet pipe member 30, and the flow cross-sectional area of the reduction part 31 gradually increases in the direction in which the raw water flows. Since the flow rate of the raw water is increased, the cavitation phenomenon occurs, and microbubbles are generated by the cavitation shape.

On the other hand, when the treated raw water passes through the reduced portion 31 of the inlet pipe member 30, the sludge of the treated raw water may be solubilized so that the treated raw water is supplied from the ozone generator 70 connected to the inlet pipe member 30. Ozone is supplied.

Thereafter, the raw water is introduced between the outer cylinder member 10 and the inner cylinder member 20. As shown in FIG. 3, since the inlet pipe member 30 is provided so that its central axis C2 does not meet the central axis C1 of the outer cylinder member 10, the inlet pipe member 30 The introduced raw water is introduced while rotating in the direction of the arrow between the outer cylinder member 10 and the inner cylinder member 20.

While rotating the outer cylinder member 10 and the inner cylinder member 20, the processing raw water gradually flows to the upper end side of the outer cylinder member 10, the inlet 40 is provided in the inner cylinder member 20 the processing raw water To rise).

While the raw water is raised to the inlet 40 of the inner cylinder member 20, the raw water has a larger cross sectional area on the side where the raw water enters in the flow direction (A) of the raw water is larger than that on the side where the raw water flows out. It passes through the first reduction tube member 61 and the second reduction tube member 62.

Thereafter, when the raw water is raised to the inlet 40 of the inner cylinder member 20, the raw water is introduced into the inner cylinder member 20 through the inlet 40.

When the treated raw water flows into the inner barrel member 20, the treated raw water falls to the lower end side of the inner barrel member 20. When the raw water falls, a cavitation phenomenon occurs, and microbubbles are generated by the cavitation phenomenon. Since the bottom face of the inner cylinder member 20 is lower than the bottom face of the outer cylinder member 10, sufficient cavitation may occur with respect to the raw water falling toward the bottom face of the inner cylinder member 20.

The pressurized pump 90 is operated to introduce the treated water reaching the bottom of the inner cylinder member 20 back into the outer cylinder member 10. Then, the raw water reaching the bottom of the inner cylinder member 20 is introduced again between the outer cylinder member 10 and the inner cylinder member 20 through the circulation pipe member 80. The flow rate of the raw water flowing through the circulation pipe member 80 may be adjusted by the second flow control valve 110.

The raw water flowed back between the outer cylinder member 10 and the inner cylinder member 20 through the circulation pipe member 80 is rotated between the outer cylinder member 10 and the inner cylinder member 20 while the inlet port of the inner cylinder member 20 Up to 40).

In the above process, a part of the raw water is moved back to the raw water tank 200 through the outlet 50 provided in the outer cylinder member 10, the flow rate of the raw water moving to the raw water tank 200 is the first flow rate It can be adjusted by the control valve (100).

As a result, the raw water is treated as described above, between the inlet pipe member 30, the outer cylinder member 10 and the inner cylinder member 20, the inlet 40, the inner cylinder member 20, the circulation pipe member 80, The process of moving between the outer cylinder member 10 and the inner cylinder member 20, via the outlet 50, and the raw water tank 200 is repeated.

As described above, since the raw water is passed through the reduced portion 31 of the inlet pipe member 30 before flowing between the outer cylinder member 10 and the inner cylinder member 20, the flow rate of the treated raw water in the process is accelerated, so that the cavitation A phenomenon occurs, and microbubbles are generated by the cavitation phenomenon. The microbubbles are introduced between the outer cylinder member 10 and the inner cylinder member 20 together with the treated raw water, so that the microbubbles are broken while the treated raw water flows, and the sludge is atomized.

In addition, while the raw water passes through the reduction portion 31 of the inflow pipe member 30, the ozone generator 70 connected to the reduction portion 31 supplies ozone to the treatment raw water. Since ozone is supplied from the reduction part 31 which speeds up the flow of raw water, the dissolution rate of ozone can be raised to the raw water. While the raw water is flowing, ozone reacts with the sludge contained in the raw water to solubilize the sludge.

In addition, when the raw water is supplied between the outer cylinder member 10 and the inner cylinder member 20, the raw water is introduced while the raw water is rotated, so that the central axis C1 of the outer cylinder member 10 flows while the raw water is rotated. Since the difference in the rotational speed of the raw water occurs depending on the distance from the center, that is, the rotational speed of the raw water flowing away from the central axis C1 is faster than the rotational speed of the raw water flowing closer to the central axis C1. This difference in rotational speed generates shear force in the sludge, which effectively removes the mucous substances surrounding the cell walls of the microorganisms, thereby atomizing the sludge.

Further, the treated raw water has a large flow cross sectional area on the side in which the treated raw water flows in the flow direction A, and a small flow cross sectional area on the side where the raw water flows out, and the first reduced tube member 61 and the second reduced tube member ( 62, the cavitation phenomenon occurs when the raw water passes through the first reduction tube member 61 and the second reduction tube member 62, and microbubbles are generated by the cavitation phenomenon. While the raw water is flowing, the microbubbles are broken down to atomize the sludge.

When the raw water flows in through the inlet 40 of the inner cylinder member 20 and falls to the lower end of the inner cylinder member 20, the lower end of the inner cylinder member 20 is lower than the lower end of the outer cylinder member 10. Rather than matching the lower end of the inner cylinder member 20 with the lower end of the outer cylinder member 10, the raw water having a relatively large potential energy falls, and microbubbles are generated by the cavitation phenomenon in the process. The microbubbles are broken in the course of the flow of raw water to atomize the sludge.

Thus, the sludge treatment apparatus 1 according to an embodiment of the present invention, by supplying ozone through the ozone generator 70 to the treated raw water introduced into the inlet pipe member 30 from the raw water tank 200, ozone and sludge By reacting, the effect of solubilizing the sludge is provided.

In addition, since the raw water flowing into the inlet pipe member 30 from the raw water tank 200 is raised while rotating between the outer cylinder member 10 and the inner cylinder member 20, the shear force is generated in the fluid during the rotation of the raw water treatment sludge The particles are separated from each other and atomized, and the mucus that surrounds the cell wall of the microorganism is removed. When the sludge particles are separated and the mucus material surrounding the microbial cell wall is removed, and the raw water is introduced into the raw water tank 200 again, the sludge particles can effectively treat the sludge in the raw water tank 200. to provide.

In addition, the sludge treatment apparatus 1 according to an embodiment of the present invention, when the treated raw water passes through the reduced portion 31 of the inlet pipe member 30, the treated raw water is the outer cylinder member 10 and the inner cylinder member ( When passing through the first reduction pipe member 61 provided in 20, the raw water flowing into the inner cylinder member 20 through the inlet 40 of the inner cylinder member 20 of the inner cylinder member 20 Since the cavitation phenomenon occurs when flowing to the lower end, the microbubbles are generated by the cavitation phenomenon, thereby providing the effect that the sludge is atomized while the microbubbles are destroyed. When microbubbles are blown to the microorganisms from which the mucus material is removed, the microorganisms are greatly contributing to atomization of the sludge.

In addition, the raw water is the raw water tank 200, the inlet pipe member 30, between the outer cylinder member 10 and the inner cylinder member 20, the inner cylinder member 20, the circulation pipe member 80, the outer cylinder member 10 ) And the inner cylinder member 20, and passes through the long flow path passing through the outlet 50, so that the sludge is solubilized while the sludge reacts with the ozone supplied through the ozone generator 70, while passing through the flow path, As the microbubbles generated by the cavitation phenomenon are destroyed, the sludge is sufficiently atomized.

On the other hand, the sludge treatment apparatus 1 according to the present embodiment economically and effectively pretreatment of raw water containing sludge, such as wastewater, animal husbandry wastewater, food waste leachate, etc., which is a problem recently, and then, in an anaerobic digestion tank, By increasing the extinguishing efficiency, it is possible to maximize the amount of methane generation, which is a high value added gas, and at the same time, to reduce the amount of landfill waste.

In addition, since the sludge treatment apparatus 1 according to the present embodiment generates fine carbon sources by atomizing the sludge, when it is used in a general sewage treatment plant, general sewage is not provided to provide an external carbon source. Provides the effect of using the treatment plant as an advanced sewage treatment plant.

Hereinafter, the effect of the present invention will be described in more detail with reference to the experimental example experimented by the inventors of the present invention using the sludge treatment apparatus 1 according to the present embodiment.

First, the schematic configuration and terminology of the apparatus used in the experiment will be described as follows.

The raw water tank 200 had a capacity of 42 L, and the outer cylinder member 10 had a capacity of 25 L with a diameter of 200 mm and a height of 800 mm. The capacity of the pump for supplying the raw water is 150 L / min and 750 W, and the capacity of the pressurized pump 90 is 80 L / min and 750 W.

Suspended Solids (SS) is the concentration of solids on the filter paper, and the Chemical Oxygen Demand (COD) represents the concentration of organic matter in chemical oxygen demand, while the SOOD (Soluble Chemical Oxygen Demand) is a soluble chemical oxygen. As required, the microfilter (1 μm in diameter) is used to represent the COD of the material filtered through the microfilter.

[Experimental Example]

Under the above conditions, the ozone (ozone injection rate is 0.05 gO ₃ / gSS) is introduced into the sludge treatment apparatus 1 according to the present invention through the ozone generator 70 in the initial treatment water of SCOD 100 mg / L. After 3 hours of treatment, the SCOD increased significantly to 1,300 mg / L. This treated raw water means that the sludge is destroyed and solubilized, thereby increasing the substance of 1 μm or less in the treated raw water. As a result of the exhaustion test using the solubilized sludge, the nitrogen removal rate was improved by 20% or more than methanol. Gas generation amount increased.

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

For example, in the present embodiment, six first reduction tube members 61 are provided on the inner circumferential surface of the outer cylinder member 10, and six second reduction tube members 62 are provided on the outer circumferential surface of the inner cylinder member 20. The number of the first reduction tube member 61 or the second reduction tube member 62 may be appropriately changed.

In addition, the present embodiment has been described in the case where the raw water is treated raw water including sludge combined with microorganisms, sludge not combined with microorganisms, for example, a simple slurry precipitation process in various water treatment processes (precipitation process without microorganisms) It is also applicable to raw water containing sludge generated from. Also in this case, the raw water is treated between the inflow pipe member 30, the outer cylinder member 10 and the inner cylinder member 20, the inner cylinder member, the circulation tube member 80, the outer cylinder member 10 and the inner cylinder member 20. In between and via the raw water tank 200, the sludge is solubilized and atomized as described above.

1 is a schematic cross-sectional view of a sludge treatment apparatus according to an embodiment of the present invention.

FIG. 2 is a schematic perspective view of the main part of the sludge treatment apparatus shown in FIG.

3 is a cross-sectional view taken along line III-III of FIG.

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

1 ... sludge treatment unit 10 ... outer cylinder member

20 ... Inner tube member 30 ... Inlet pipe member

31 ... Reduction 40 ... Inlet

50 ... outlet 61 ... first reduction tube member

62 ... second reduction tube member 70 ... ozone generator

80 ... Circulation pipe member 90 ... Pressure pump

100 ... 1st flow control valve 110 ... 2nd flow control valve

200 ... Raw water tank 210 ... Raw water supply pump

220 ... Raw water supply control valve

Claims (3)

An outer cylinder member extending in a vertical direction and having a closed space; An inner cylinder member disposed coaxially with the outer cylinder member at a central portion of the outer cylinder member, an upper portion of which is located in the outer cylinder member, and a lower portion of which extends below the outer cylinder member; It is provided at the lower end of the outer cylinder member so that treated raw water including sludge flows between the outer cylinder member and the inner cylinder member, and the treated water flowing between the outer cylinder member and the inner cylinder member flows while rotating between the outer cylinder member and the inner cylinder member. An inflow pipe member having a central axis disposed at a position not meeting the central axis of the outer cylinder member; An inlet provided at an upper end of the inner cylinder member such that the raw water introduced between the outer cylinder member and the inner cylinder member through the inlet pipe member flows into the inner cylinder member from an upper end side of the outer cylinder member; An outlet provided at an upper end of the outer cylinder member such that the raw water introduced into the inner cylinder member through the inlet is discharged from the upper side of the outer cylinder member to the outside of the outer cylinder member; A plurality of first reduction pipe members disposed on an inner circumferential surface of the outer cylinder member and having a flow cross-sectional area of an upstream portion in the flow direction of the raw water introduced between the outer cylinder member and the inner cylinder member larger than a flow cross-sectional area of the downstream portion; The circulation pipe member having one end connected to the lower end of the inner cylinder member and the other end connected to the lower end of the outer cylinder member so that the raw water flowed into the inner cylinder member and flowed into the lower end of the inner cylinder member can be circulated into the inner cylinder member. ; An ozone generator connected to the inlet pipe member to supply ozone to the raw water flowing into the inlet pipe member; A pressure pump connected to the circulation pipe member to circulate the raw water flowing into the inner cylinder member and flowing to the lower end of the inner cylinder member into the outer cylinder member; A first flow control valve for controlling the flow rate of the raw water flowing out through the outlet; And And a second flow rate control valve for adjusting the flow rate of the raw water circulated through the circulation pipe member. And the inflow pipe member has a reduction portion in which the flow cross-sectional area is gradually narrowed toward the downstream side in the flow direction of the raw water in the inflow pipe member, and the ozone generator is connected to the reduction portion. delete 2. The second reduction pipe according to claim 1, wherein a plurality of second pipes are disposed on an outer circumferential surface of the inner cylinder member, and the flow cross section of the upstream portion in the flow direction of the raw water introduced into the inner cylinder member is larger than the flow cross section of the downstream portion. A sludge treatment apparatus further comprising a member.

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