KR101261490B1 - Apparatus for dewatering of the fine polluted sediment - Google Patents

Abstract

The present invention relates to a method for continuously removing and purifying fine particles deposited in water. Geotextile tubes used for dehydration are made by connecting two to four geotextiles with different voids to prevent clogging due to particulates introduced into the tubes. Fine particles that can clog can escape through the large geotextiles located above the tubes. In addition, micro sediment is easily filtered through the geotextile tube, and the following devices are sequentially connected in order to inhale and homogenize a certain amount of micro sediment.
2 to 7 small suction pumps, integrated pipe area device that can adjust the suction amount and check its status, a device and a mixing device for injecting a chemical to agglomerate pollutant and fine particles, and a plant seed introduced thereafter Input site device.

Description

Apparatus for dewatering of the fine polluted sediment}

The present invention relates to a micro-contaminated sediment dewatering apparatus, and more particularly, to a micro-contaminated sediment dewatering apparatus using a geotextile tube and a method of dewatering the same.

The present invention relates to a method for efficient dewatering and purification of particulate matter (sludge) containing fine pollutants deposited in water, such as rivers, rivers, lakes, reservoirs. Existing river sediments, such as rivers, rivers, lakes, and reservoirs, are dredged and left in nearby treatment centers using civil dredging equipment as part of dredging. The micro-contaminated sediments that cause problems when left unattended are mostly dewatered using centrifuges, belt presses, or other designed machinery. These methods focus mainly on the efficient removal of large amounts of sediment, and lack of solutions for the dewatering of the fine particles. In fact, it is difficult to remove the water contained between the sediment or sludge particles composed of fine particles, which is expensive and time-consuming and inconvenient to process a large amount. In general, when forced dehydration is not carried out for low cost, it is left in a large sedimentation treatment plant for a long time. However, this also causes a problem of securing the treatment plant, the microparticles of the portion that is not exposed to the surface is very slow drying may be lost by the rainfall.

At present, domestic rivers, rivers, lakes and reservoirs have been built for a long time, and most of the sediment is accumulated under water. In addition, this sediment contains various organic and inorganic contaminants, and the particles are so fine that it is difficult to process them by simply dredging them out of the water with existing simple dredging. Various designs have been proposed to solve this problem, but since the amount of dredging is very large, it is difficult to access easily considering the cost and time for processing. One of the excellent methods for dredging and dewatering many fine sediments inexpensively and easily is to use geotextile tubes. However, in the case of fine particle dehydration, the particles are grown using agglomeration technology and then dewatered into a geotextile tube. However, the state of micro-sedimentary soils varies depending on the environment, and it is difficult to fully aggregate with current limited coagulant technology. Unaggregated particulates often clog the geotextile tubes and stop working.

Geotextile tubes used at this time are fabric fibers woven from one type of fiber, all of which have uniform voids. Therefore, when the sediment is dehydrated from the tube by the flocculation technique, the unaggregated fine particles start to clog pores and stop dehydration. To solve this problem, vibration equipment may be used or left for a long time. Therefore, the existing tube system using one type of geotextile is showing a limitation in the dewatering of fine sediment.

[JP 1] Publication JP 5-23694 Purification of Organic Sediments [Document 2] JP Publication 11-324008 Dam Sediment Removal Method [JP 3] JP Publication 2007-330954 Apparatus for recovering and removing sediment [Paper 4] KP 10-0327749 Stream sludge treatment apparatus and method. KP 20-0289978 Sediment Collection System Using High Pressure Water [Document 6] KP 20-0351197 River Sludge Treatment Plant [Document 7] KP 10-0457383 Treatment System for Water Purification of Lakes and Reservoirs KP 10-0515269 Longitudinal flexible container Document 9 KP Disclosure 10-2009-0111145 Geotextile Tubes Document 10 KP Disclosure 10-2009-0109688 Method of manufacturing geotubes and geotubes, screw-shaped tubes [Document 11] KP Registration 1007783210000 Geotube, Separation Tube with Order Means [Document 12] KP Registration 1009224140000 Environment-friendly Underwater Dredging Device and Construction Method [13] USP 07455773 Package wastewater chemical / biological treatment method [14] USP 07454847 Sediment and sludge dewatering by vacuum bag method 15 USP 07112283 Method and system for processing waste 1 US Pat. No. 56,356,83 A (MCDERMOTT, R. M.) 1997.06.03. [Document 2] JP 10-105775 A 1998.04.24, page 5, line 3-15, drawing 1

The present invention is to solve the above problems, to provide a micro-contaminated sediment dehydration apparatus that can prevent the clogging phenomenon of the geotextile tube by the unaggregated fine particles to facilitate the dehydration operation of the micro-contaminated sediment. do.

The micro-contaminated sediment dewatering device of the present invention comprises a plurality of suction pumps; A plurality of small pipes having one side connected to each of the suction pumps and having a control valve at the other side; A large pipe connected to the small pipes; A confirmation pipe connected to one side of the large pipe so as to check an inside of the large pipe by opening and closing a confirmation valve; Purifying medicine casing, agglomerated medicine casing and seed casing connected sequentially to the large pipe; And a geotextile tube coupled to the distal end of the large pipe, wherein the geotextile tube consists of an upper portion, a middle portion, and a lower portion of which the size of the pores is sequentially reduced, wherein the upper portion, the middle portion, and the lower portion are each 2/6. The upper and lower sides face each other, and 2/6 of the middle parts are disposed so that a pair face each other.
One of the plurality of suction pumps only sucks water, and the other suction pumps suck water and deposits, and adjust the suction pump to suck only the water so that the deposit introduced into the geotextile tube is 10% or less of the water. It is preferable.
Among the large pipes between the purifying chemicals and the coagulant drug, between the coagulant and the seed container and near the terminal side in the seed container is formed in a wave shape by the vertical coupling of the U (magnetic) tube, the It is preferable that all the formed part was formed in the same length.

delete

delete

According to the present invention, two or more types of geotextiles having different sizes of pores are connected to form a tube, which can continuously remove a large amount of fine deposits deposited in water at a constant rate, thereby dredging the contaminated fine deposits. It has the effect of facilitating and purifying the work.

1 is a view showing the device configuration and processing flow of the present invention.
2 shows sediment suction using a small multiple pump
3 is a view illustrating a step in which pipes connected to a pump are adjusted together.
4 is a view showing the order of mixing and mixing the drugs.
5 is a manufactured cross-sectional view of multiple geotextile tubes.

The present invention will now be described in detail with reference to the accompanying drawings.

GT500, GT400, GT300 Geotextiles are made with different pores depending on the size of the textile's tissue, followed by GT500, GT400, and GT300. These consist of polypropylene or polyethylene fibers and are woven into a weaving machine to serve as filters. Different geotextiles have different pore sizes, resulting in different sizes of particles filtered through the tube.

I will explain why the tube consists of three types of geotextiles. The fine sediment is composed of various forms and can be coagulated to a certain size or more by the existing coagulation method and chemicals.However, by using the simple suction coagulation method, a large amount of fine sediment is continuously coagulated to a certain size or more. It was not easy to filter out the tube consisting of. This is very difficult to control the amount of intake when inhaling sediment in water with a single suction pump, and the state of the sediment is slightly different so that it is not agglomerated with a preselected flocculant. It contains a lot of this, which blocks the voids in the upper part of the tube. Sediments in water consisting of fine particles must have a solids content of 10% or less to be sucked into the pump and dewatered from the filter. Solids must be mixed evenly with water even at 10% or less. It is difficult to inhale and dehydrate the micro sediment in such a condition that it is not met.

This can easily cause clogging and extend the working time considerably, and it is inconvenient that the dehydration operation can be continued if fine particles are forced out of the tube by vibrating the tube using a separate machine. You may have to stop working without filling a tube.

Therefore, the tube to be applied in such a case is difficult with a simple type of geotextile. Due to the nature of the fine sediment, it is difficult to completely coagulate the soil, so that a large pore geotextile tube is used to prevent the fine unaggregated fine particles from escaping. For this reason, in recent years, tubes with few voids are mainly used, but in continuous operation, clogging of the tubes due to unaggregated particles occurs. This blockage occurs from one-third to one-half of the height from the bottom of the tube during continuous operation. Geotextile structures with larger voids than from the bottom are preferred from the 1/3 to 1/2 of the height from the bottom so that unaggregated particulates easily exit from the upper position. The connection of geotextile tubes with at least two types of voids can solve this problem.

On the other hand, when continuously pumping the sedimentary soil part composed of fine particles (almost clay) with a pump, the particles are easily dispersed and homogenized. Powerful suction pumps allow some of the suction to disperse and remain in the form of agglomerates that enter the tube in an unaggregated state and cause clogging in the tube, making the task difficult. Therefore, first, as shown in Fig. 2, two to seven small suction pumps are used to suck through each pipe to reduce the intake of solids in the form of agglomerate and to be dispersed in a plurality of small pipes. To the large pipes. X of these small pumps fits only the water, which is in line with the degree that the deposit of solid deposits is introduced into the tube to be 10% or less of the water. In addition, in the pipe as shown in Figure 3 in succession to make a locking device that can control the incoming from the small pipe, and at one end to make a check valve to check the state. This allows the addition of a certain amount of homogeneous mixing with drugs such as flocculants in the next process. Small suction pumps are those that do not exceed the maximum flow rate to the geotextile tube divided by the number of pumps.

In addition, the chemical injection site introduces a pipe with a U-shaped curve as shown in Fig. 3 so that the chemical is continuously mixed in the pipe after the chemical is injected. The oil pipes mix well with the material or chemicals being injected. The order of input is firstly purified chemicals, secondly flocculated chemicals and finally plant seeds. This pipe is made from 4 to 8 places where it is bent at 180 degrees from the inlet of the purification chemicals, and from 2 to 4 places from the place where the flocculant is introduced. Make the same seed input.

Purifying chemicals consist of inorganic chemicals and biodegradable microorganisms, and mainly serve to stabilize and biodegrade fine heavy metals and organic contaminants, respectively. Inorganic chemicals such as hydroxides, oxides, and phosphate compounds may be used as the inorganic purification chemicals, and as biodegradable microorganisms, microorganisms in which carbohydrates, nitrogen compounds, and phosphate compounds are decomposed may be used.

The reason for introducing plant seeds is as follows. Tubes are often used as civil engineering structures containing sediments. In this case, the surface of the tube is made of plastic fiber, which is prone to breakage due to prolonged exposure and is not environmentally friendly. Usually, the geotextile tube is protected by covering another protective sheet or stacking large aggregates or stones. To eliminate this extra work, the method of warming the geotextile tube surface with grass makes the tube both environmentally friendly and protective. Generally, grasses grow naturally due to the voids of the tube, but it takes a lot of time, so putting plant seeds together with sediment cleanses the dehydrated solids, and the tube surface is covered with grasses in a short time to protect the environment. It becomes preferable at the point of doing. Plant seeds to be introduced is preferably used to grow the seeds thin and long leaves.

1: Small submersible suction pump 2: Suction material transporting small pipe 3: Suction volume control valve 4: Suction volume, mixing condition checking pipe 5: Check valve 6: Suction material transporting Large pipe 7: Chemical chemical container 8: Chemical chemical container 9: Seed Tube 10: Input tube 11: Mixed citron tube 12: Mix transport pipe 13: Textile connection 14: Small pore textile 15: Medium pore textile 16: Large pore textile 17: Geotextile tube

Claims (4)

A plurality of suction pumps;
A plurality of small pipes having one side connected to each of the suction pumps and having a control valve at the other side;
A large pipe connected to the small pipes;
A confirmation pipe connected to one side of the large pipe so as to check an inside of the large pipe by opening and closing a confirmation valve;
Purifying medicine casing, agglomerated medicine casing and seed casing connected sequentially to the large pipe; And
Includes; geotextile tube coupled to the end of the large pipe,
The geotextile tube consists of a top, a middle, and a bottom in which the size of the pore is sequentially reduced, wherein the top, the middle, and the bottom occupy 2/6, and the top and bottom face each other, and the center is 2/6. The fine contaminated sediment dewatering device, characterized in that the pair is arranged facing each other by 1/3.
The method according to claim 1,
One of the plurality of suction pumps only sucks water, and the other suction pumps suck water and deposits,
And controlling the suction pump to suck only the water so that the deposit introduced into the geotextile tube is 10% or less of the water.
The method according to claim 1,
Among the large pipes between the purifying chemicals and the coagulant drug, between the coagulant and the seed container and near the terminal side in the seed container is formed in a wave shape by the vertical coupling of the U (magnetic) tube, the The micro-contaminated sediment dewatering device, characterized in that the formed portion is all formed in the same length.
delete

Images