KR102199304B1 - System for improving the reuse efficiency of anthracite and activated carbon - Google Patents

Abstract

The present invention relates to a system for improving the reuse efficiency of anthracite and activated carbon. More specifically, a sand pump is used to pump water, anthracite, and filtering materials in filter paper through a pump inlet hose and supply them to a rotary aggregate sorter. By the rotation of the rotary aggregate sorter, the filtering materials such as activated carbon, anthracite, fine filter yarn, and coarse filter yarn are pumped together with the water in the filter paper. The vortex phenomenon of the sand pump and the rotational force of the rotary aggregate sorter separate the filtering material and foreign substances. At the front end of the rotary aggregate sorter, fine powder can be discharged, and at the rear end, a cleaning agent such as hydrogen peroxide, chlorine, ozone, ethanol, etc. are diluted in water and injected from the front or rear end of the sand pump to separate the filtering materials and the foreign substances well, improve cleaning power, and sterilize microorganisms, green algae, etc., bacteria, and viruses contained in the filtering materials. The rotation of the rotary aggregate sorter maximizes the cleaning and sorting efficiency by washing suspended matter separated by the friction of the filtering materials once more. In the activated carbon, impurities not removed during washing and sorting are repeatedly washed by rotating an activated carbon washer again to filter fine powder and then filtering cleaning agent components in which hydrogen peroxide, ethanol, etc. are diluted in water to maximize washing and sorting efficiency.

Description

System for improving the reuse efficiency of anthracite and activated carbon}

The present invention relates to a system for improving the reuse efficiency of anthracite and activated carbon, and more particularly, to pump water, anthracite, and filtration material in a filter paper using a sand pump so as to be introduced through a pump inlet hose, and a rotary aggregate separator Filter materials such as activated carbon, anthracite, fine filter yarn, and coarse filter yarn are separated from the filter material with the water in the filter paper by the vortex phenomenon of the sand pump and the rotational force of the rotary aggregate separator by rotating the rotary aggregate separator. Fine powder can be discharged at the front end of the rotary aggregate sorter, and a detergent such as hydrogen peroxide, chlorine, ozone and ethanol is diluted in water and injected at the front or rear end of the sand pump to facilitate separation of filtration material and foreign matter. It is achieved, improves cleaning power, sterilizes microorganisms, green algae, bacteria and viruses contained in the filter material, and maximizes washing and sorting efficiency by washing the floating matter separated by friction of the filter material once more by rotating the rotary aggregate separator. , Activated carbon can be washed repeatedly by rotating the activated carbon washing machine to repeatedly wash the impurities that were not removed during washing and sorting, and then filtered and discharged detergent components diluted in water such as hydrogen peroxide and ethanol to maximize washing and selection efficiency. It relates to a system for improving the reuse efficiency of anthracite and activated carbon configured to be so.

In general, water treatment is a process of purifying water and consists of a series of processes including water intake, chemical treatment, coagulation, precipitation, filtration, disinfection, and storage. Water treatment starts with water intake, and water is obtained by water intake from a water source. At this time, wood chips and garbage are filtered during the flow. If the water source is groundwater, it is filtered as it is absorbed through the surface. In the case of groundwater, there are cases where the purification process is not necessary. For chemical treatment, chemicals such as aluminum sulfate and chlorine are added to the water. This settles the solids in the water. And let the water and chemicals mix well. In agglomeration, a drug such as aluminum sulfate administered is attached to impurity grains in water to form a large lump, which is called agglomeration. Sedimentation, the water containing the aggregated flows into the settling basin. Here, the agglomerated thing sinks and separates from the water. In filtration, water is filtered and flowed from the settling basin. The filtration device is made of a layer of sand and gravel, which serves as an excuse to remove the solids remaining in the water. Disinfection involves the addition of some chlorine or other chemicals to kill any remaining germs and keep them safe during transport until they are supplied to people. In some water systems, especially with groundwater as the source of water, only this treatment may be performed. Storage The treated water is stored in a reservoir called a tank or a water purification pond. Here, the chlorine spreads and mixes throughout the water, resulting in complete disinfection. Then it flows through a pipe that sends water.

During the water treatment process as described above, most of the suspended matter is removed during the precipitation process, and the unremoved suspended matter is removed during the filtration process.In general, if the filtration is continued for 1 to 2 days in a rapid filter, impurities and the filtration layer are clogged and filtration is not possible. Does not. At this time, the filtration function is restored by surface washing and countercurrent washing of the filter layer.If the number of times is accumulated, the layers of coarse gravel, fine gravel, coarse sand, and fine sand are sequentially stacked from the bottom layer, and the layer division is sparse and impurities It mixes up to this depth and drops the turbidity and chromaticity and loses the water purification function. Sand filter paper is mainly used for marine sand with a high silica sand content, and high quality aggregates are consumed in large quantities to replace the filter sand.

Therefore, there is a problem in that the natural environment for collecting the filter sand is destroyed, and at the same time, the cost of replacing the filter fiber increases due to logistics costs by transporting it from a far shore area.

On the other hand, anthracite is a filter medium using anthracite as a raw material, which means that anthracite is decomposed into a very small size and made into a filter medium. It is a filter medium in the form of particles or powder, which is used for physical treatment in water and sewage treatment.When anthracite is used as a filter medium, it saves maintenance costs because it takes a long time to filter, and because the specific gravity is smaller than that of sand, it is suspended during backwashing. It has the advantage of easy separation of materials.

Activated carbon has strong adsorption properties, and most of its constituent materials are carbonaceous, and is used as an adsorbent to absorb gas or moisture or as a decolorizing agent. It is manufactured by treating and drying wood or lignite with chemicals such as zinc chloride.

Conventional prior art related to the reuse and reuse of filter yarns as described above include Korean Utility Model Gazette No. 20-0167949, Domestic Utility Model Gazette No. 20-0167950 and Domestic Utility Model Gazette No. 20- No. 0167951 proposes a filter yarn cleaning device for a mobile vehicle, but there is a problem in that economical efficiency is poor due to the use of complex processes such as vacuum vehicles, inclined conveyors, washing tanks, underwater vibration pumps, and vibration screens, and expensive devices. In addition, the Korean Patent Application Publication No. 10-2008-0097047, previously applied by the applicant of the present invention, was not severely contaminated with the environment, so only water was used to wash and select the filter yarn.

However, from the past to the present, environmental pollution has become more severe and it has become difficult to wash the filter yarn with only water, so the present invention has been completed with a technical configuration of washing the filter yarn and anthracite by mixing water and a detergent.

The present invention was invented to solve and supplement the problems of the prior art, and the present invention is in addition to washing filter yarns such as activated carbon, anthracite, fine filter yarn, and coarse filter yarn using only water in the existing prior art. By operating the sand pump, the filter material is pumped with water using the pump inlet hose, and the filter material and the foreign material are separated by the vortex phenomenon of the sand pump, and the foreign material of the filter material is further separated and sterilized using various detergents. Washing and sorting efficiency is maximized using a washing and sorting machine, and the selected filter material is packaged and loaded in a ton bag, and a tank of a certain size is formed after the block or strainer of filter paper is repaired and repaired. It is an object of the present invention to provide a system for improving the reuse efficiency of anthracite and activated carbon, which can significantly reduce the cost of new input of a filter material by inputting filter yarn, fine filter yarn, anthracite, and activated carbon in order.

The main body (1), which is a solution to the system for improving the reuse efficiency of the anthracite and activated carbon of the present invention, is connected to the inlet hose 210 connected to the water of the filter paper 100 and the inlet hose 210, and the filter paper 100 The sand pump 200 located in the water of the anthracite regeneration unit 700 connected to one side of the inlet hose 210, and a detergent injection valve connected to the rear end of the anthracite regeneration unit 700 to inject a detergent ( 405 and the cleaning agent injection valve 405, a circulation pipe 630 through which the cleaning agent moves, and another side of the circulation pipe 630 are connected to each other to spray the cleaning agent, and the cleaning agent injection nozzle 680 and the cleaning agent injection nozzle ( The activated carbon regeneration unit 600 to which the 680 is connected to the upper end and the circulation pipe 630 to which the detergent injection valve 405 and the detergent injection nozzle 680 are connected are connected to the detergent supply pump 650 to supply the detergent, The cleaning agent supply pump 650 is continuously connected to a filtration unit 620 for filtering water and a cleaning agent supply unit 610 for supplying a cleaning agent, and a circulation pump 660 is connected to an upper end of the filtration unit 620, , A washing water recovery tank 6025 for recovering washing water is formed at a lower end of the anthracite regeneration unit 700 and a lower end of the activated carbon regeneration unit 600, and the circulation pump 660 is a washing water recovery tank ( It comprises supplying the washing water recovered in 6025) to the filtering unit 620.

The anthracite reproducing unit 700 has a front and rear blocking flow wall 710 formed at the center to separate the regeneration unit front end 705 and the regeneration unit rear end 706, and the regeneration unit front end 705 and the regeneration unit rear end The discharged water of the 706 is not mixed, the filtering material and the foreign matter are separated by the rotational force of the anthracite regeneration unit 700, and the regenerated anthracite 1041 formed at the lower end of the anthracite regeneration unit 700 The anthracite regenerated by the anthracite regeneration unit 700 is accumulated, and the activated carbon regeneration unit 600 forms a conveyor belt 800 on one side to store the activated carbon 105 discharged from the anthracite regeneration unit 700. A cleaning agent spraying nozzle 680 is formed at the top of the activated carbon regeneration unit 600 to spray the cleaning agent, and an activated carbon discharge port 690 is formed at the other side of the activated carbon regeneration unit 600 to regenerate located at the bottom. The activated carbon 105 regenerated in the activated carbon regeneration unit 600 is accumulated in the activated carbon 1051.

The cleaning agent supply unit 610 for supplying a cleaning agent is connected to the filtering unit 620 and the filtering unit 620 for filtering the cleaning water supplies the cleaning water of the cleaning water recovery tank 6025 by a circulation pump 660 Received and filtered, the detergent supply pump 650 is connected to the filtering unit 620 to supply the detergent to the rear end of the anthracite recycling unit 700 through the circulation pipe 630, and to the activated carbon recycling unit 600. And the washing water discharged from the rear end of the anthracite recycling unit 700 and the activated carbon recycling unit 600 is recovered to the washing water recovery tank 6025.

The present invention operates a sand pump to pump the filter material with water using a pump inlet hose, separates the filter material from the foreign material by vortex phenomenon of the sand pump, and further separates and sterilizes the filter material by using various detergents. In addition, since the rotary aggregate sorting machine is used, it is possible to maximize the cleaning of the filter material and the screening efficiency of the filter material, and by diluting a cleaning agent such as hydrogen peroxide, chlorine, ozone, and ethanol in water to wash foreign substances of the filter material and prevent bacteria and viruses. Because it is sterilized and sterilized, the efficiency of cleaning and sterilization is high.Since the filter material is separated by type using a rotary aggregate sorter and stored in a tone bag for reuse, the cost of the filter material can be significantly reduced. It has the effect of improving the regeneration efficiency of the site and activated carbon.

1 is an overall configuration diagram of a system for improving reuse efficiency of anthracite and activated carbon according to the present invention.
2 is a block diagram of an anthracite regeneration unit and an activated carbon regeneration unit of the system for improving the reuse efficiency of anthracite and activated carbon according to the present invention.
3 is a block diagram of a cleaning agent supply unit of a system for improving the reuse efficiency of anthracite and activated carbon according to the present invention.
4 is a block diagram of an activated carbon regeneration unit according to another embodiment of a system for improving the reuse efficiency of anthracite and activated carbon according to the present invention.
5 is a block diagram of a cylindrical activated carbon regeneration unit according to another embodiment of a system for improving recycling efficiency of anthracite and activated carbon according to the present invention.
6 is a block diagram of a cylindrical horizontal activated carbon regeneration unit according to another embodiment of a system for improving the reuse efficiency of anthracite and activated carbon according to the present invention.
7 is a block diagram of a horizontal activated carbon regeneration unit that is another embodiment of a system for improving the reuse efficiency of anthracite and activated carbon according to the present invention.
8 is a block diagram of another embodiment of a system for improving reuse efficiency of anthracite and activated carbon according to the present invention.
9 is a view showing a cleaner injection unit of another embodiment of a system for improving the reuse efficiency of anthracite and activated carbon according to the present invention.
10 is a view showing a washing and sorting unit of another embodiment of a system for improving the reuse efficiency of anthracite and activated carbon according to the present invention.
11 is a view showing a water tank of another embodiment of a system for improving the reuse efficiency of anthracite and activated carbon according to the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings, and when it is determined that detailed descriptions of related known functions or configurations may unnecessarily obscure the subject matter of the present invention in describing the present invention. Detailed description thereof is omitted.

In addition, terms to be described later are terms defined in consideration of functions in the present invention, which may vary according to the intention or custom of users or operators. Therefore, the definition should be made based on the contents throughout this specification.

When described in detail with reference to FIGS. 1 and 2 and 3,

The main body (1) is connected to the inlet hose (210) connected to the water of the filter paper (100) and the inlet hose (210), and the sand pump (200) and the inlet hose (210) located in the water of the filter paper (100). An anthracite regeneration unit 700 connected to one side, a cleaning agent injection valve 405 connected to the rear end of the anthracite regeneration unit 700 to inject a cleaning agent, and a circulation pipe through which the cleaning agent moves to the detergent injection valve 405 630 and another side of the circulation pipe 630 are connected to the cleaner spray nozzle 680 for spraying the cleaner, and the activated carbon regeneration part 600 to which the cleaner spray nozzle 680 is connected to the upper end, and the cleaner injection The circulation pipe 630 connected to the valve 405 and the detergent injection nozzle 680 is connected to the detergent supply pump 650 to supply the detergent, and the detergent supply pump 650 is a filter unit 620 for filtering water. And a cleaning agent supply unit 610 for supplying the cleaning agent, and a circulation pump 660 is connected to the upper end of the filtering unit 620, and the lower end of the anthracite recycling unit 700 and the activated carbon recycling unit ( A washing water recovery tank 6025 for recovering washing water is formed at the lower end of the 600), and the circulation pump 660 supplies the washing water recovered in the washing water recovery tank 6025 to the filtering unit 620. It constitutes containing.

The inlet hose 210 and the inlet hose 210 connected to the water of the filter paper 100 having a perforated block structure are connected to the sand pump 200, and the inlet hose 210 is an anthracite regeneration unit 700 and Connect.

The anthracite reproducing unit 700 is divided into a reproducing part front end 705 and a reproducing part rear end 706, and the reproducing part front end 705 and the reproducing part rear end 706 are the central part of the anthracite reproducing part 700. The front and rear blocking flow walls 710 are formed and separated, and a detergent injection valve 405 is formed at the upper end of the regeneration section rear end 706 of the anthracite regeneration section 700 to form a detergent ( 415). A reproducible anthracite 1041 is formed at the lower end of the anthracite reproducing unit 700 to accumulate the anthracite reproduced by the anthracite reproducing unit 700.

Unlike the anthracite regeneration unit 700, an activated carbon regeneration unit 600 is formed. Activated carbon 105 is supplied to the front portion of the activated carbon regeneration unit 600 using a conveyor belt 800. The activated carbon 105 is introduced into the activated carbon regeneration unit 600 through the activated carbon inlet 670. A cleaning agent spraying nozzle 680 is formed at the upper end of the activated carbon regeneration unit 600 to supply and spray a cleaning agent 415 inside the activated carbon regeneration unit 600. An activated carbon discharge port 690 is formed in the rear portion of the activated carbon regeneration unit 600 to accumulate the regenerated activated carbon 105 in the regenerated activated carbon 1051 located at the lower end of the activated carbon regeneration unit 600.

A cleaning agent 415 is supplied to the anthracite recycling unit 700 and the activated carbon recycling unit 600 using a circulation pipe 630, and the circulation pipe 630 is connected to a detergent supply pump 650, and the The detergent supply pump 650 is connected to the filtration unit 620, and a circulation pump 660 is connected to the upper end of the filtration unit 620, and a detergent supply unit 610 is formed at one side of the filtration unit 620. .

The cleaning agent 415 supplied from the cleaning agent supply unit 610 is supplied to the anthracite recycling unit 700 and the activated carbon recycling unit 600 through a circulation pipe 630.

A washing water recovery tank 6025 is formed at the lower ends of the anthracite regeneration unit 700 and the activated carbon regeneration unit 600 to recover the cleaning agent 415. The circulation pump 660 formed on the upper end of the filtering part 620 is installed inside the washing water recovery tank 6025.

The filtering material of the anthracite 104 and the activated carbon 105 at the bottom of the filter paper 100 flows in through the inlet hose 210, and moves to the anthracite regeneration unit 700 through the inlet hose 210, The vortex phenomenon of the sand pump 200 and the rotational force of the anthracite regeneration unit 700 separate the filtration material and foreign matter, discharge fine powder to the regeneration stage 705, and hydrogen peroxide, chlorine, and the like in the regeneration stage 706 A cleaning agent 415 such as ozone or ethanol is diluted in water and sprayed to help separate the filter material and foreign matter and improve cleaning power. In the central part of the anthracite material part 700, a front and rear cutoff flow wall 710 is formed so that the discharged water from the regeneration part front end 705 and the regeneration part rear end 706 is not mixed, so that microorganisms contained in the filter material and It sterilizes green algae, bacteria and viruses, and maximizes the efficiency of washing and sorting by washing the suspended matter separated by friction of the filter material once more.

The activated carbon 105 is moved to the activated carbon regeneration unit 600 using the conveyor belt 800 and washed in the anthracite regeneration unit 700 by repeatedly circulating the impurities not removed during selection by using a cleaning agent 415 for cleaning. And can maximize screening efficiency.

When described in detail with reference to FIG. 4,

Activated carbon 105 is the activated carbon regeneration unit 600 after washing and sorting, using a detergent 415, which is the diluted water of the detergent stock solution 400 of Fig. 3, such as hydrogen peroxide, ethanol, etc. After the fine powder is repeatedly washed several times in the filter unit 620 and then the detergent 415 is discharged using purified water, the activated carbon 105 with improved filtration capability can be regenerated.

The activated carbon regeneration unit 600 has an activated carbon inlet 670 formed at the top, a cleaning agent spraying nozzle 680 connected to the cleaning agent supply unit 610 on the outside, and an activated carbon discharge port 690 at the bottom. , The detergent 415 flows out to the inner bottom surface, passes through the filter unit 620 on the outside, is filtered, and is circulated back to the detergent supply unit 610 along the circulation pipe 630.

The activated carbon 105 is loaded inside the activated carbon regeneration unit 600 to be cleaned by a circulating cleaning agent 415.

When described in detail with reference to FIG. 5,

As another embodiment of the activated carbon regeneration unit 600 described in FIG. 6, the cylindrical activated carbon regeneration unit 600-1 has an activated carbon inlet 670 formed at the upper end to regenerate particles of a predetermined standard or more, and the inner upper end A washing water injection nozzle 680 is formed in the washing water injection nozzle 680, and the washing water injection nozzle 680 is connected to an external detergent supply unit 610 and a detergent supply pump 650. That is, the cleaning agent supply unit 610 receives the control of the cleaning agent supply pump 650 and puts it into the inner activated carbon 105 through the washing water spray nozzle 680.

The washing water after washing the activated carbon 105 is filtered by the filtering unit 620 formed outside and is fed back to the cleaning agent supply unit 610 along the circulation pipe by the circulation pump 660.

The washed activated carbon 105 is discharged to the outside through the activated carbon discharge port 690 and the regeneration process of the activated carbon 105 is completed.

When described in detail with reference to FIG. 6,

As another embodiment of the activated carbon regeneration unit 600 described in FIG. 6, the cylindrical horizontal activated carbon regeneration unit 600-2 forms a reduction motor 6023 at the upper end of the washing water spray nozzle 680, and at the lower end A cleaning agent 415 in which purified water is mixed with hydrogen peroxide or ethanol and the like by rotating the cylindrical horizontal activated carbon regeneration unit 600-2 formed in a cylindrical shape after the washing water recovery tank 6025 is formed and activated carbon 105 for regeneration is inserted Is injected into the cylindrical horizontal activated carbon regeneration unit 600-2 through the cleaning agent supply unit 610.

The reduction motor 6023 controls the speed at which the cylindrical horizontal activated carbon regeneration unit 600-2 rotates.

The washing water supplied through the washing water spray nozzle 680 as described above is collected in the washing water recovery tank 6025 and passes through the filtering unit 620, and the washing water filtered by the filtering unit 620 is again used as a detergent. It is injected into the supply unit 610. Meanwhile, the activated carbon 105 washed from the inside of the cylindrical horizontal activated carbon regeneration unit 600-2 is discharged to the outside through the activated carbon discharge port 690.

The washed activated carbon 105 is discharged to the outside through the activated carbon discharge port 690 and the regeneration process of the activated carbon 105 is completed.

When described in detail with reference to FIG. 7,

As another embodiment of the activated carbon regeneration unit 600 described in FIG. 6, the horizontal activated carbon regeneration unit 600-3 is formed in multiple stages, and a vibration unit 6032 at the lower end of each horizontal activated carbon regeneration unit 600-3 ) To provide vibration to the horizontal activated carbon regeneration unit 600-3 to flow the activated carbon 105 inside.

The horizontal activated carbon regeneration unit 600-3 constitutes a vibrating unit 6032 at the lower end by forming a screen jaw 6035 on one side to regenerate particles of a predetermined standard or more. A washing water spray nozzle 680 is formed inside the screen tank 6035, and a washing water recovery tank 6025 is formed at a lower end of the horizontal activated carbon regeneration unit 600-3.

A cleaning agent 415 in which an activated carbon for regeneration 105 is loaded inside the horizontal activated carbon regeneration unit 600-3 formed with a screen tank 6035, operates the vibration unit 6032, and mixed purified water with hydrogen peroxide or ethanol Is introduced into the horizontal activated carbon regeneration unit 600-3 through the cleaning agent supply unit 610.

The washing water supplied through the washing water spray nozzle 680 as described above is collected in the washing water recovery tank 6025 and passes through the filtering unit 620, and the washing water filtered by the filtering unit 620 is again used as a detergent. It is injected into the supply unit 610. And the activated carbon 105 washed from the inside of the horizontal activated carbon regeneration unit 600-3 is discharged to the outside.

The washed activated carbon 105 is discharged to the outside of the horizontal activated carbon regeneration unit 600-3, and the regeneration process of the activated carbon 105 is completed.

When described in detail with reference to FIGS. 8 to 11,

Figure 8 is a configuration diagram of another embodiment, the inlet hose 210 connected to the water of the filter paper 100 and the inlet hose 210 is connected to one side of the detergent injection part 450, and of the detergent injection part 450 The upper end is connected to the detergent supply tank 410, the other side of the detergent injection part 450 is connected to the sand pump 200, and the upper end of the sand pump 200 and the washing sorting part 300 are outlet hose 220 Use to connect.

The gravel 101 and the coarse filter thread 102 and the fine filter thread 103 at the bottom of the filter paper 100 configured as described above are introduced through the inlet hose 210. At this time, the detergent is supplied to the detergent injection unit 450 from the detergent supply tank 410, and the gravel 101, the coarse filter thread 102, and the fine filter thread 103 are introduced into an inlet hose using a sand pump 200. It flows in through 210 and moves to the washing and sorting unit 300 through the outlet hose 220.

The filter yarn at the bottom of the filter paper 100 is composed of gravel 101, a coarse filter thread 102 and a fine filter thread 103, and the filter material is a process of purifying the contaminated water in the filter paper 100. As it is rough, it is mixed with foreign substances and contaminated.

The filter material contaminated as above and mixed with foreign matter is washed and used again.

9, the inlet hose 210 is connected to one side of the detergent injection part 450, and a detergent injection port 455 is formed at the top of the detergent injection part 450, and the detergent injection port 455 is a detergent injection hose 401 Is connected to the cleaning agent supply tank 410, and the other side of the cleaning agent injection unit 450 is connected to the sand pump 200, and the sand pump 200 is coupled to the driving motor 205 and the sand pump 200 The top of the outflow hose 220 and connect.

The detergent 415 formed on the inside of the detergent supply tank 410 is completed by diluting the detergent stock solution 400. When the detergent 415 is injected from the detergent supply tank 410 to the detergent injection unit 450, the detergent injection valve 405 formed in the central portion of the detergent injection hose 401 is controlled.

The inlet hose 210 is coupled by a detergent injection unit 450 and a first connection flange 201, and the detergent injection unit 450 and the sand pump 200 are connected by a second connection flange 202 And, the sand pump 200 is coupled by the outlet hose 220 and the third connection flange 203.

The sand pump 200 is operated by a driving motor 205, and the sand pump 200 sucks or inflows the filtering material through the inlet hose 210.

The detergent 415, which is the diluted water of the detergent stock solution 400, which will not affect other water quality such as hydrogen peroxide, chlorine, ozone water, and ultrasonic waves in the detergent supply tank 410, is fed through a detergent injection hose 401. The cleaning agent 415 is supplied to the cleaning agent injection unit 450 while controlling the injection amount of the cleaning agent 415 using 405.

The cleaning agent injection part 450 is installed at the front end of the sand pump 200 to better separate foreign substances mixed in the filter yarn, improve cleaning power, and sterilize various bacteria such as microorganisms or green algae contained in the filter material. Make it possible.

In Fig. 10, since most of the pollutants of the filter material are mainly attached to the fine filter thread 103, the washing sorting unit 300 operated in a rotational manner is configured with a fine filter thread sorting washing tank 330 at the front end to improve cleaning power. Then, a coarse filter yarn sorting washing tank 340 is constructed, and next, a gravel sorting washing tank 350 is constructed. A primary ring bar 301, a secondary ring bar 302, and a tertiary ring bar 303 are provided at the front ends of the fine filter yarn sorting washing tank 330, the coarse filter yarn sorting washing tank 340, and the gravel sorting washing tank 350, respectively. It is formed to rotate the filter material for a certain period of time to improve washing and sorting, and at the bottom, each of the fine filtered historical alveoli 360, the coarse filtered historical algae 370 and the gravel algae 380 are configured, and the gravel sorting washing tank At the rear end of the 350, a gear motor 310 is formed that constitutes a rotating chain 320 and generates power to rotate the washing and separating unit 300, and the filter yarns are rotated by the rotation of the washing and separating unit 300. The floating matter separated by friction can be washed and sorted to maximize the washing and sorting efficiency, and the washed and sorted filter material can be packaged and loaded in a tone bag.

In FIG. 11, a prefabricated water tank 500 of a certain size is formed and installed at the time of work to perform the work, and when the work is finished, it can be withdrawn, and a waterproof water tank 510 such as vinyl is used inside to facilitate movement to other sites. In the prefabricated water tank 500 formed with a reinforcing structure 550 on the outside and a structure fitting 570 to facilitate assembly and disassembly, water, gravel, coarse filter and fine filter are in order 500), water and filter material are put back into the filter paper using a sand pump.

In the present invention, the above embodiments are merely examples, and the present invention is not limited thereto. Anything that has substantially the same configuration as the technical idea described in the claims of the present invention and achieves the same operation and effects is included in the technical scope of the present invention.

1. Main body 100. Filter paper
101. Gravel 102. Coarse filter thread
103. Fine filter company 104. Anthracite
105. Activated carbon 200. Sand pump
201. First connection flange 202. Second connection flange
203. 3rd connecting flange 205, drive motor
210. Inlet hose 220. Outflow hose
300. Washing and sorting part 301. Primary ring bar
302. Secondary ring bar 303. Third ring bar
310. Gearmotor 320. Rotating chain
330. Fine filter yarn sorting and washing tank 340. Coarse filter sorting and washing tank
350. Gravel sorting and washing tank 360. Fine filtration historic site
370. Coarse filtered historical algae 380. Graveled algae
400. Cleaner stock solution 401. Cleaner injection hose
405. Cleaning agent injection valve 410. Cleaning agent supply tank
415. Cleaner 450. Cleaner injection
455. Cleaner injection port 500. Assembled water tank
510. Waterproof water tank 550. Reinforcement structure
570. Structure fitting 600. Activated carbon regeneration unit
600-1. Cylindrical type activated carbon recycling unit 600-2. Cylindrical horizontal activated carbon regeneration unit
600-3. Horizontal activated carbon recycling unit 610. Cleaning agent supply unit
620. Filter part 630. Circulation piping
650. Cleaning agent supply pump 660. Circulation pump
670. Activated carbon inlet 680. Cleaner spraying nozzle
690. Activated carbon outlet 700. Anthracite regeneration unit
705. Regeneration section 706. Regeneration section
710. Front and rear cutoff flow walls 800. Conveyor belt
1041. Recycled anthracite 1051. Recycled activated carbon
6023. Reduced motor 6025. Washing water recovery tank
6032. Vibration unit 6035. Screen jaw

Claims (4)

An inlet hose 210 connected to the water of the filter paper 100 and an antra connected to the inlet hose 210 and connected to the sand pump 200 located in the water of the filter paper 100 and one side of the inlet hose 210 A cleaning agent injection valve 405 connected to the rear end of the site regeneration unit 700 and the anthracite regeneration unit 700 to inject a cleaning agent, a circulation pipe 630 through which the cleaning agent moves to the cleaning agent injection valve 405, and the Another side of the circulation pipe 630 is connected to the cleaning agent spraying nozzle 680 for spraying the cleaning agent, the activated carbon regeneration part 600 to which the cleaning agent spraying nozzle 680 is connected to the upper end, and the cleaning agent injection valve 405 The circulation pipe 630 to which the cleaning agent injection nozzle 680 is connected is connected to the cleaning agent supply pump 650 to supply the cleaning agent, and the cleaning agent supply pump 650 supplies a filter unit 620 for filtering water and a cleaning agent. It is continuously connected to the detergent supply unit 610, and a circulation pump 660 is connected to the upper end of the filtering unit 620, and at the lower end of the rear end of the anthracite regeneration unit 700 and the lower end of the activated carbon regeneration unit 600 A main body comprising supplying the washing water recovered in the washing water recovery tank 6025 to the filtering unit 620 to form a washing water recovery tank 6025 for recovering the washing water ( 1),
The anthracite reproducing unit 700 has a front and rear blocking flow wall 710 formed at the center to separate the regeneration unit front end 705 and the regeneration unit rear end 706, and the regeneration unit front end 705 and the regeneration unit rear end The discharged water of the 706 is not mixed, the filtering material and the foreign matter are separated by the rotational force of the anthracite regeneration unit 700, and the regenerated anthracite 1041 formed at the lower end of the anthracite regeneration unit 700 A system for improving reuse efficiency of anthracite and activated carbon, characterized in that the anthracite regenerated by the anthracite regeneration unit 700 is accumulated. delete The method of claim 1,
The activated carbon regeneration unit 600 forms a conveyor belt 800 on one side to enter the activated carbon 105 discharged from the anthracite regeneration unit 700 into the interior, and sprays detergent on the upper end of the activated carbon regeneration unit 600 A nozzle 680 is formed to inject a cleaning agent, and an activated carbon discharge port 690 is formed on the other side of the activated carbon regeneration unit 600, and the activated carbon regenerated in the activated carbon regeneration unit 600 in the regenerated activated carbon 1051 located at the bottom ( 105) a system for improving the reuse efficiency of anthracite and activated carbon, characterized in that. The method of claim 1,
The cleaning agent supply unit 610 for supplying a cleaning agent is connected to the filtering unit 620 and the filtering unit 620 for filtering the cleaning water supplies the cleaning water of the cleaning water recovery tank 6025 by a circulation pump 660 Received and filtered, the detergent supply pump 650 is connected to the filtering unit 620 to supply the detergent to the rear end of the anthracite recycling unit 700 through the circulation pipe 630, and to the activated carbon recycling unit 600. And recovering the washing water discharged from the rear end of the anthracite regeneration unit 700 and the activated carbon regeneration unit 600 to the washing water recovery tank 6025, improving the recycling efficiency of anthracite and activated carbon. For the system.

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