KR101464045B1 - Rain Water Tank having Water Quality Control System And cleaning System Without Power - Google Patents

Abstract

The present invention relates to a rainwater storage tank with a non-motorized water quality management facility and a cleaning facility, which comprises a concrete storage structure, a wall screen for capturing and dewatering the scum, a lattice type multi hopper for collecting the settled sludge, A sludge suction facility for sucking and removing the collected sludge, and a cleaning facility for cleaning the fouling residue.
Accordingly, the present invention can collect dirt trapped on the wall screen without motion, dehydrate the dirt, clean the dirt and harmful gas from entering the tank, prevent maintenance and management, It is effective.

Description

{Rain Water Tank Having Water Quality Control System And Cleaning System Without Power}

The present invention relates to a rainwater storage tank having a non-motorized water quality management facility and a cleaning facility. More particularly, the present invention relates to a rainwater retention tank having a square screen, a grid- The sludge suction facility and the washing facility are installed to collect debris trapped on the wall screen without motive power, and it can be cleaned without entering people into the tank where odor and noxious gas are generated. It is easy to maintain, And a rainwater storage tank in which a cleaning facility is installed.

Urbanization and regional development are accompanied by degradation of storm water retention due to surface packing and straightening of the flow path, which increases the flood discharge rate. In the early period of rainfall, highly polluted rainwater flows out due to contaminants accumulated on the surface of the ground or sewage.

Rainwater storage facilities are needed in order to prevent floods and to clean contaminated rainwater. Rainwater storage facilities installed in urban areas and other development areas are required to be installed in underground tanks Concrete cascades are often used.

In the rainwater storage facility installed in the development area, it is important not only to secure the site, but also to manage pollutants that have flowed in together with rainwater.

Contaminated rainwater contains a large variety of particulate contaminants such as dirt, dust, and soil, which can clog the screen, float on the bottom of the storage tank or float, cause clogging of the inlet and outlet, deteriorate water quality, Odor and harmful gas generation, storage capacity due to sedimentation, and the like.

To solve these problems, concrete rainwater storage tanks installed in urban areas are equipped with flood prevention facilities and water purification facilities. Rainwater inflow, drainage, ventilation, management manholes, and drainage pumps are installed in these facilities.

Conventional flood prevention reservoirs are installed to allow rainwater to flow into natural watersheds. Most facilities do not have screen facilities for pretreatment to remove contaminants. In order to reduce construction costs, floors are installed horizontally. A person enters the inside of a storage facility and performs dredging using equipment, vehicles, and so on.

Conventional water storage tanks have non-point pollutant storage facilities and combined sewer water storage facilities. These facilities are generally installed to flow into natural waters. However, in low areas, storage facilities are installed at high places, I can not.

If the water quality of the sewage sludge is large or the water quality is bad, such as the sewage sludge in the combined sewer system, a pretreatment facility is a sludge collection method for dredging the sedimentation sludge by installing a screen for removing contaminants in front of the sludge storage facility. A washing water dropping device for sloping and storing some rainwater at a high place in the storage facility to drop a large amount of water at a time to move sedimentation sludge to the lower side or a movable washing water spraying device A sludge cleaning device or a sludge collector in the form of a scraper that moves by a chain is installed in the tank or an agitation facility which continuously agitates to prevent sedimentation of solids is used. However, these methods have the following problems Have.

Conventional flood prevention reservoirs have the adverse effects such as clogging in the drainage pump due to inflow into the tank in a state in which the impurities such as refuse are not removed and the sedimentation sludge spreads on the floor. There is also no need for people to dredge into odor and toxic tanks and to perform dredging work by separating the dirt from the dredged sludge and finally disposing them.

In a water purification tank, a pretreatment facility, an automatically operated screen, is installed in some facilities. However, in a facility without such a screen, problems similar to the flood prevention reservoir during sedimentation sludge dredging occur.

However, in the place where the screen of impurity is installed, the site for the screen installation is required, and the screen of impurity is an automatic operation facility, and the installation cost and the maintenance cost are high. Moreover, the filtration area of the screen is small and the mesh size of the screen is 50 mm In the case of the removal of sedimentation sludge accumulated on the bottom of the storage tank, the mechanical washing device, the sludge collecting device, the sludge collecting device, And agitation device. However, there is a problem that the installation cost is high and the operation management is difficult due to the complexity of these devices and frequent breakdowns and the necessity of professional manpower.

In order to solve these problems, it is an object of the present invention to reduce the installation cost of apparatuses for dirt removal and sedimentation sludge dredging, and the operation cost of these apparatuses, and to provide a rainwater storage tank which does not enter a tank, The present invention aims to provide a non-powered water quality management device capable of cleaning effectively.

To achieve the above object, according to the present invention,

A rainwater storage tank 1a in which a first partition 2 is formed at a predetermined position in a box-shaped water storage tank in which a top plate 11 is covered and a rainwater inflow port 13 is formed at an upper part of the side wall, And a manhole 12 is provided in an area of the upper plate 11 of the sludge suction tank 1b and the rainwater storage tank 1a separated by the sludge suction tank 1b formed with the rainwater storage structure 4 1);

A wall screen 20 installed in the form of a fence surrounding the rainwater inflow port 13 at a predetermined distance from the rainwater inflow port 13 to capture various contaminants introduced through the rainwater inflow port 13;

The wall surface screen 20 is located between the wall surface screen 20 and the rainwater inflow port 13 of the rainwater storage tank 1a and is provided at a lower portion of the wall surface screen 20 so that a contaminant filtered by the wall surface screen 20 flows into the V- A dewatering box (30) having a plurality of dewatering holes (33) formed therein so as to be naturally dewatered;

The sidewall portion has a slope so that the sludge that has passed through the wall surface screen 20 slides and is discharged to the lower portion and the sludge discharge port 41 is provided at a lower portion of the sidewall portion A plurality of hoppers 40 connected in a lattice form to unit hoppers 42 of a funnel type;

A sludge inlet 51 is formed at a position corresponding to the sludge discharge port 41 of the multiple hoppers 40 and is integrally formed with the plurality of the hoppers 40 so that one end of the sludge inlet 51 is connected to the first partition 2 A sludge passage pipe 50 penetrating the sludge suction pipe 1b and located in the sludge suction tank 1b;

There is provided a rainwater storage tank with a non-powered water quality management facility and a cleaning facility provided with a discharge means (60) installed in the sludge suction tank (1b) so as to discharge the rainwater introduced into the rainwater storage tank (1a) to the outside.

The sludge sucking tank 1b includes a foot 70 installed at a predetermined height of a middle portion of the sludge suction tank 1b, A washing water storage chamber 1e and a drain pump chamber 1d may be provided at one side and at the other side by providing a second partition 3 at a lower portion of the foot plate 70 .

The rainwater storage structure 1 includes a ventilation pipe 14 provided at least one in each of the rainwater storage tank 1a and the upper plate 11 of the sludge suction tank 1b, A manhole cover 15, a fall prevention railing 16 standing upright on the upper side of the manhole 12, a ladder 17 installed in the lower direction of the manhole 12, An inspection port 18 provided on the upper plate 11 and a grating lid 19 covering the inspection port 18 may be further provided.

And a suction and discharge assisting member 90 installed at a predetermined position on the ceiling in the sludge suction tank 1b.

One end of the sludge passage pipe 50 may protrude above the foot plate 70.

The wall surface screen 20 may be provided as a linear screen or a lattice screen and a perforated screen, which are erected in a lattice pattern.

The wall screen 20 may be installed as a full inclined screen inclined from the lower side to the upper side toward the rainwater inflow port 13.

The wall screen 20 may be provided with a narrow mesh screen 21 on the lower side and a wide mesh screen 22 on the upper side.

The bar 23 of the wall screen 20 may be formed by selecting any one of circular, square, narrow front side, wide rear side triangle, narrow front side, and wide rear side shape so that backwashing can be performed by spraying high pressure water have.

The dewatering box 30 may be provided with a V-shaped channel 31 having a sloped side and inclined bottom and a perforated box 32 connected to a lower portion of the channel 31.

The dewatering box 30 may be further provided on the side of the rainwater inflow port 13, the front side, and the rear side.

The sludge passage pipe 50 may be provided by connecting a vertical pipe 52 at a position corresponding to the sludge discharge port 41 formed at the bottom of the multiple hoppers 40.

The discharge means 60 may be provided with a drain pump 61, a discharge pipe 63, and a pump inlet pipe 62.

The washing means 80 may be provided with a washing water supply pump 81, a supply pipe 82, a water spray nozzle 83, a valve 84, and a distribution bottle 85.

The suction and discharge assisting member 90 includes a rail 91 attached to the ceiling of the sludge suction tank 1b and a roll cylinder 92 connected to the rail 91 to be movable, And a sludge suction pipe 93 inserted into the sludge passage pipe 50.

The sludge suction pipe 93 connects a front end pipe 94 to the front end of the sludge suction pipe 93. The front end pipe 94 may be made of stainless steel, plated steel, aluminum or plastic having durability and corrosion resistance. have.

The sloping screen 101 is used at a depth sufficient to receive the supernatant in the rainwater storage tank 1a in front of the washing water storage chamber 1e provided in the sludge suction tank 1b, A washing water intake pump 102 installed in the upper water intake space 105 and a sludge suction tank 1b installed in the upper water intake space 105. [ And a horizontal filtration facility 100 formed of a granular material 103 of sand and gravel and a collecting plate 104 between the lower part of the foot 70 of the washing water storage room 1e and the upper part of the washing water storage room 1e.

A supply pipe 82 equipped with a water spray nozzle 83 may be installed in the upper water intake space 105 so that the water splash screen 101 can be sprayed with pressure water and backwashed.

A box-shaped rainwater storage structure 10 having at least one manhole 12 in a predetermined area of the upper plate 11, a rainwater inlet 13 at an upper portion of one side wall and a drainage port 4 at a lower portion of the other side wall, and;

A wall screen 20 installed in the form of a fence surrounding the rainwater inlet 13 at a predetermined distance from the rainwater inlet 13 of the rainwater storage structure 10 to filter various contaminants introduced through the rainwater inlet 13 )and;

A dewatering box 30 provided at a lower portion surrounded by the wall surface screen 20 and having a plurality of dewatering holes 33 formed therein so that the dirt trapped in the wall surface screen 20 is gathered and naturally dewatered;

A unit hopper 42 having a sludge outlet port 41 formed at a lower portion thereof so that the sludge having flowed through the rainwater inlet 13 together with the rainwater and passing through the wall screen 20 slides and is discharged downward, A plurality of hoppers 40 connected to the rainwater storage structure 10 at predetermined intervals upward from the bottom of the rainwater storage structure 10;

One end of the hopper 40 is located at the lower end of the multiple hopper 40 and the other end of the hopper 40 is connected to the first hopper 2 through the right end of the multi hopper 40 A sludge inlet 51 is formed at a position corresponding to the sludge outlet 41 of the multi-hopper 40 so that the sludge introduced through the sludge inlet 51 is connected to the outside And a sludge passage pipe 50 provided to be discharged.

The rainwater storage structure 10 includes a ventilation pipe 14 provided on at least one top plate 11, a manhole cover 15 covering the manhole 12, A ladder 17 installed in a lower direction of the manhole 12 and an inspection port 18 provided in an area of the upper plate 11 and a grating lid 19 covering the inspection port 18 ) May be further included.

As described above, according to the present invention, in the contaminated rainwater storage tank

First, there is no need to take site for screen installation, which is a pretreatment facility for removing contaminants,

Second, the impurities trapped on the screen are collected by non -

Third, the sludge deposited on the bottom of the reservoir structure or the rainwater storage tank is collected with no force,

Fourth, since the device structure of the screen, the sludge suction device, and the cleaning device is simple, the installation cost of these devices is low,

Fifth, it is possible to clean without entering people into the tank where odor and harmful gas are generated,

Sixth, it is easy to maintain, and water quality management and cleaning costs are cheap.

1 is an internal plan view of a rainwater storage structure according to the present invention;
2 is a cross-sectional view taken along the line AA 'in FIG. 1
FIG. 3 is a cross-sectional view taken along line BB of FIG.
4 is a cross-sectional view taken along the line CC '
5 is a cross-sectional view taken along the line DD '
Fig. 6 is a plan view
7 is an enlarged cross-sectional view of a state where a suction pipe is inserted into a sludge passage pipe according to the present invention
8 is an internal plan view of another first embodiment according to the present invention.
9 is a longitudinal sectional view of another second embodiment according to the present invention
10 is a longitudinal sectional view of another third embodiment according to the present invention
11 is a sectional view taken along the line EE of Fig. 10

A rainwater storage tank with a non-motorized water quality management facility and a cleaning facility according to the present invention includes a concrete storage structure, a wall screen for capturing and dewatering the contaminants, a lattice type multi hopper for collecting the settled sludge, a sludge collected as a tank cleaning facility A sludge suction facility for suction and removal, and a cleaning facility for cleaning the fouling residue.

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

1 is a sectional view taken along the line AA 'in FIG. 1, FIG. 3 is a sectional view taken along the line BB' of FIG. 1, and FIG. 4 is a sectional view taken along the line CC ' , FIG. 5 is a cross-sectional view taken along line DD 'of FIG. 1, and FIG. 6 is a plan view of the present invention.

As shown in FIGS. 1 to 6, the rainwater storage tank having the non-motorized water quality management facility and the cleaning facility according to the present invention includes a rainwater storage structure 1 having a concrete structure and a rainwater collecting structure 1 for capturing a contaminant flowing through the rainwater inflow port 13 A dewatering box 30 formed with a plurality of dewatering holes 33 for dewatering the dirt trapped in the wall surface screen 20 and a sludge passing through the wall surface screen 20 A plurality of hoppers 40 slid down to the lower portion of the multi hopper 40 and connected to the outer hopper 40 through a sludge discharging unit 40, A sludge passage pipe 50 piped to discharge the sludge to the outside by suction means, a discharge means 60 for discharging the rainwater introduced into the rainwater storage structure 1 to the outside, And a plurality of hoppers 40, Consists of a cleaning means 80 for cleaning the contaminated debris on the dewatering box (30).

The rainwater storage structure (1) is a relatively large-sized concrete rectangular structure to be installed for flood prevention and water purification, and is installed as a structure that combines an on-site concrete structure or a PC building structure and a PC structure.

A rainwater storage tank (1a) is formed at one side of a first partition (2) formed at a predetermined position in a storage structure, and the other side is connected to a sludge suction tank (1b).

A plurality of manholes 12, a manhole cover 15, a fall prevention railing 16, an inspection port 18 and a grating lid 19, a ventilation pipe 14, And lighting facilities.

The size of the rainwater storage structure (1) is determined according to the storage amount, and it is advantageous to make the rainwater storage structure elongated in the flow direction of water advantageous for sedimentation.

The rainwater storage structure (1) is preferably installed so that the rainwater flows into the natural watershed. In most cases, the rainwater storage structure (1) is stored at a water level lower than the discharge water.

Most of the rainwater storage structure 1 is used as the rainwater storage tank 1a, but a part of the space at a distance from the rainwater inlet 13 is blocked by a wall to block odor, noxious gas, .

A footrest 70 is provided at a predetermined height in the sludge suction tank 1b and a second partition 3 is installed under the footrest 70 to divide the footrest 70 into two equal parts. (1c). One side of the lower space is used as a drain pump chamber (1d) and the other side is used as a washing water storage room (1e).

A manhole cover 15 covering the manhole 12 and the manhole 12 is provided in the upper plate 11 of the rainwater storage tank 1a and the sludge suction tank 1b. And a grating lid 19 covering the inspection port 18 and the inspection port 18 are respectively formed on the upper part of the manhole 12 and the lower part of the manhole 12 in the lower part of the manhole.

The wall screen 20 is installed in the form of a fence surrounding the rainwater inflow port 13 to filter various kinds of contaminants introduced together with the rainwater through the rainwater inflow port 13.

The wall screen 20 is installed from below the rainwater inlet 13 of the inner wall surface of the concrete storage structure to the upper part of the storage water level to capture various kinds of impurities and waste.

The wall screen 20 can be constructed by attaching a screen capable of capturing and trapping contaminants in the inflow water in a rectangular structure to a wall having the rainwater inlet 13 or connecting a screen to another adjacent wall for securing a wide filtering area The screen is backwashed at the central part of the tank, so that a sloping screen inclined upward toward the wall above the screen is installed to allow the obstacles on the screen to fall down to the floor, and the obstacles falling from the screen to the floor are moved to one side A V-shaped water channel 31 inclined at the bottom is provided between the lower portion of the screen and the wall and a wall is provided between the lower portion of the screen and the wall, and a debris dewatering box 30 formed of a perforated plate box 32 is installed at the end of the downstream water channel 31.

The screen of the full inclined screen can be a rod or rod screen, a lattice screen, or a perforated plate. It is preferable to use as large a porosity as possible. The smaller the pore size of the screen, the smaller the size of the impurities can be captured. The smaller the pore size, the larger the trapped amount and the faster the screen is faded. Therefore, the best method is to secure a large area while reducing the pore size.

In the present invention, the wall surface is maximally used in order to secure a wide screen area while reducing the size of the pore size of the screen. However, the installation area in the lateral direction of the wall screen 20 in the interior of the quadrilateral tank has priority over the wall surface having the inlet port, Use both sides of the wall adjacent to the opposite wall.

The drainage box 30 is installed below the rainwater inflow port 13 slightly higher than the running water level after the rainwater stored in the tank is drained, 20) to the lowest level exposed above the water surface.

After the wall screen 20 is drained by installing the wall screen 20 on the water level, the debris drip tray 30 is exposed and the captured debris is naturally dewatered by the non-dynamic force.

The cross-sectional shape of the wall screen 20 is a full-inclined form in which the upper portion of the screen is inclined toward the rainwater inflow port 13 and a full-inclined form in which the upper portion is inclined toward the central portion of the tank 13 away from the rainwater inflow port 13. However, The impurities in the inflow water are caught on the screen and then fall down by gravity. In addition, water is sprayed on the back side of the screen at the center of the tank to facilitate backwashing.

The smaller the pore size of the screen, the larger the trapping effect of the particulate pollutants. However, if the size of the screen is too small, the trapped particles are clogged quickly. Therefore, it is selected in consideration of the characteristics of contaminated rainwater, the kind and quantity of pollutants, The mesh size of the screen is determined so that the particle contaminants are too large to block the hopper holes and prevent the sludge suction cleaning process.

In addition, the mesh size of the screen is relatively narrow and the mesh screen 21 is used on the lower side. However, in order to prevent the screen from being stopped when the screen is clogged due to the delay in cleaning the screen, A mesh screen 22 is used.

In the case of using a bar or bar screen, the sectional shape of these members is a polygonal such as a circle, a triangle, or a quadrangle. In the case of a triangular bar screen using a plurality of triangular bars, the front side is narrow, the back side is wide, The sludge clogging phenomenon is small because the size of the pores increases as the size of the pores increases. Also, when the high pressure water is sprayed from the back side, the backwashing structure is good.

The dewatering box 30 is composed of a V-type water channel 31 whose side is inclined and inclined downward and a perforated box 32 connected to a lower portion of the water channel 31.

 The inclined V-shaped water channel 31 is a water channel for conveying the impurities, which is installed between the lower portion of the screen and the wall to incline the bottom, and collects the falling impurities from the screen by the pressure water and collects them into the downstream portion.

The inclined V-shaped channel 31 is a V-shaped channel 31 having a slightly smaller bottom width in the cross section. The bottom or side of the channel is made of a smooth material so that the conveyance of the impurities can be smoothly performed. Install a pressure water jet nozzle upstream and above the water channel.

The impregnated dewatering box 32 is a box of a rectangular or hopper type which is attached to an end of a sloping V-shaped channel 31 and collects and discharges the impurities conveyed through the water channel 31, I make it.

The collection of the contaminants in the water channel (31) is performed after the stored water in the tank is drained. The contaminants are collected by the perforated plate box (32) Using a vehicle equipped with a tongs picking up scrap pieces from the upper part of the structure, or picking up the scum by using the tongs that have been changed to suit the conditions of the site, they are taken out to the outside, A sieve vertical drawing device or the like may be installed on the workpiece 32 to draw out the impurities.

The inclined V-shaped channel 31 and the perforated plate box 32 are arranged at a spacing distance between the screen and the wall which are installed in a full inclined form so that a human can pass therebetween. The inclined V-shaped channel 31 and the perforated plate box 32 are capable of conveying, They shall be installed firmly so that they are not damaged by the falling energy of the influent and the equipment used for the collection work.

If necessary, a net or plate is to be installed below the rainwater inflow pipe to trap fallen energy that falls in the inflow water and fallen facilities that can be damaged.

On the other hand, it is possible to form a wall by a slope screen slightly away from the wall surface of the rainwater inflow side, and to use the front part of the storage tank as a storage room for the silt or impurities. At this time, a small hopper is formed on the floor, .

The lattice type multiple hoppers 40 are provided at predetermined intervals in the upward direction from the bottom in the rainwater storage tank 1a and have sloped surfaces so that the sludge that has passed through the screen screen 20 slips and is discharged downward And a funnel-shaped unit hopper 42 having a sludge discharge port 41 formed in the lower part thereof.

Since the multiple hoppers 40 are installed in a wide tank to deepen the required tank depth, a plurality of small unit hoppers 42 are connected in a lattice form to disperse the sludge precipitated at a low tank depth It is a facility to collect.

The unit hopper 42 is a funnel-shaped structure having a wide upper part and a narrow inner space at the lower part. Particulate contaminants in the contaminated water stored on the upper part of the hopper are deposited and contacted with the hopper slope 43, As the sludge layer thickens, the accumulated sludge moves downward along the slope with gravity and collects the sludge to the bottom of the hopper.

Particulate contaminants settle by gravity in water and accumulate on the bottom surface. Contaminants that accumulate continuously form a sludge layer. When the bottom surface is inclined, the sludge moves downward.

In general, the degree of sludge movement on the slope varies depending on the degree of slope, and in the case of water pollutants, it flows well at a slope of 60 degrees or more.

However, the larger the slope in the hopper, the deeper the depth of the hopper with a 60 degree slope is about 86.5% of the length of the top surface of the hopper, so that the depth must be as deep as possible to form a single hopper in a larger tank, Cost and so on, it is impractical to make one hopper in a large tank.

Therefore, it is possible to reduce the bottom depth of the hopper by uniformly dividing the bottom of the tank into a lattice type and forming a plurality of small-sized unitary hoppers 42 in each grid.

The lattice type multi-hopper 40 has two or more small-sized quadrangular hoppers each having an inclination of about 60 degrees in one tank. Each hopper has four slopes 43 and a hopper bottom at the center, And has a sloped upper straight line 44. Both ends of the sloped upper straight line meet the adjacent hopper or wall surface to form a two-direction vertex at the edge, three-direction vertex at the wall, and four directions at the center Form a vertex.

The size of the small unit hopper 42 in the lattice type multiple hopper 40 is determined by the size of the rainwater storage tank 1a, the ratio of the width to the length of the rainwater storage tank 1a, the presence of obstacles such as columns, the water storage capacity and tank composition depth, It is necessary to divide the tank into four lattice types each having a similar size so that a plurality of small hoppers having an inclination of about 60 degrees can be formed.

The hopper forming method is a method of forming hoppers directly in a concrete in a tank when a concrete storage structure is formed, and a method of assembling the hoppers on the bottom of the tank by making them outside.

A method of directly forming a hopper with concrete is a method of concreting a tank bottom and a hopper concurrently in a state where a sludge passage pipe 50 is arranged together with a bottom reinforcing bar at the time of bottom construction of a storage structure, As a further operation, the sludge passage pipe 50 is arranged on the bottom of the tank, and in this state, the concrete has a method of forming the hopper,

In this case, when the hopper is made with concrete, the formwork is installed in the form of a hopper, and the concrete is poured into the formwork. However, since it is difficult to inject the concrete into the formwork with the upper straight line (44), the concrete is pierced, It is recommended to install the concrete at a slightly lower height with the exception of the upper straight line (44) of the inclined surface, and to add the remaining △ -type portion after curing to concrete, plastic, steel, wood or the like.

Meanwhile, in the method of manufacturing and assembling the hopper from the outside, the hopper is divided into a single piece or a plurality of pieces in a small form such as concrete, plastic or steel plate from the outside, and the sludge passage pipe The bottom of the hopper is divided into a plurality of hopper pieces. The hopper pieces are divided into a plurality of hopper pieces.

The sludge inhaling facility is a facility for draining water stored in the tank and then dredging sediments deposited on the bottom of the tank to clean the tank. A plurality of sludge passage pipes (50) buried in a straight line form under each hopper, And a sludge suction pipe (93) movably inserted into the hopper (50) and sucking the sludge in the hopper.

The sludge passage pipe 50 is a moving passage of the sludge suction pipe 93, and sets each line in a straight line from each leading hopper on one side of the lattice type multiple hopper 40 to the wall in the direction of the aft hopper, It is a line-by-line pipe beneath each hopper.

The sludge passage pipe 50 is provided with a vertical pipe 52 connecting the bottom of each hopper and the passage pipe at the upper side of the pipe to guide the sludge in the hopper to the passage pipe and extending the pipe to the insulated wall side However, it is turned to the vertical direction with a curve toward the upper part, and is extended to a level higher than the storage level of the rainwater in the tank to fix it to the wall.

The sludge passage pipe 50 is rigid and is not easily corroded and the inner surface is smooth so that the sludge suction pipe 93 can be easily moved. In particular, the curved portion has a larger diameter than the straight portion, 94) moves well.

The vertical pipe 52 may be shortened or omitted, and may be a pipe diameter for accommodating most of the bottom of the hopper, and a jaw is not formed at the connection portion so that the sludge does not remain on the bottom of the hopper when inhaled.

The sludge suction pipe 93 is a movable pipe having a front end pipe 94 attached to the front end thereof and coupled to the roll case 92 and the roll case 92 can be moved left and right by hanging from the rail 91.

7 is an enlarged sectional view of the sludge suction pipe 93 inserted into the sludge passage pipe 50 provided under the multiple hoppers. The sludge suction pipe 93 is normally wound around the roll bottle 92, Is inserted into each sludge passage pipe (50) from the end pipe (94), and a suction pump is connected to the end of the sludge suction pipe (93) to suck the sludge in the hopper and the passage pipe (50).

The front end pipe 94 is made of a rigid and less corrosive material such as stainless steel, plated steel, aluminum, plastic, and is a short length pipe having a diameter slightly smaller than that of the sludge passage pipe 50. The sludge suction pipe 93 And the sludge is sucked through the front opening.

The end pipe 94 can be manufactured in various forms such as closing the front opening and piercing the cylindrical surface to suck the sludge in the hopper in the vertical direction.

The sludge suction pipe 93 is a pipe having a diameter equal to or slightly smaller than the diameter of the end pipe 94 and capable of pushing the end pipe 94 into the passage pipe 50, And flexible pipes that are not folded like a fibrous pipe and can not be held in shape or can not be pushed through the end pipe 94, it is necessary to use a flexible pipe having a narrow and flat shape And a long auxiliary plate wound around the roll cylinder 92 is attached in the longitudinal direction.

The syringe suction pipe 93 is connected to the suction pump by an end pipe 96 attached to the syringe suction pipe 93. The syringe suction pipe 93 is connected to the drain pump 92, The end pipe 96 is connected to the pump and sucked.

Although not shown in the drawings, the suction pump is installed outside the tank or inside the tank, or uses a suction pump attached to the sludge transport vehicle.

The inhaled and dredged sludge is transported to a landfill or a sewage treatment plant through a tank transportation vehicle or an adjacent sewer pipe and is finally treated.

However, since the dewatered sludge has a water content of about 90% and most of it is water, it is necessary to dehydrate the water content to 75% or less at the time of final landfilling. Therefore, energy and cost are consumed in this process. In this method, the filter bag is made into a bag shape, and the water in the tank is drained. The filter bag hangs on the hopper depending on the wall or the ceiling of the tank. The sludge dredged in the bag is inserted immediately, The sludge can be dehydrated and reduced in weight with low cost and effort.

The washing facility is provided with a water spray nozzle 83 in a place where washing is required such as a wall screen 20, a sloping V-shaped water passage 31 and a multiple hopper 40 and a supply pipe 82 are installed.

The wall screen 20 installed in the form of a full inclined shape or the detail screen 24 for securing the self-cleaning water is provided with a sprinkling nozzle 83 on the back and front surfaces of the screen to perform backwashing and surface cleaning, A nozzle 83 is provided to perform surface cleaning.

The washing water supply pipe 82 is provided with a distribution pipe 85 (header) connected to the pressure pump and a branch 84 is provided for each customer in the distribution pipe 85 and a valve 84 ).

The piping method and the piping line can be various, so that each branch line is extended and piped by the line of the sludge passage pipe (50) of the hopper or piped to a separate screen. Where the cleaning range is wide and intensive washing is required, A plurality of second branch wires can be installed by installing the cylinder 85. [

The piping can be fixed directly to a ceiling or a wall by using anchor, long rod, etc., or can be fixed in a state of hanging in the air, and a spray nozzle (83) is attached to a position where cleaning is required at each branch line.

The washing operation can be effectively performed by supplying the washing water sequentially to each branch line through the operation of the valve (84), and it is also possible to install an extra branch branch in the distribution box (85) And can be utilized as cleaning water for other cleaning water and sludge passage pipe 50 while being supplied with washing water through the rubber sludge suction pipe 93 or the like.

A method of cleaning a rainwater storage tank using the above-described devices will be described as follows.

A rainwater storage tank for storing contaminated rainwater needs to be cleaned by discharging rainwater and then removing contaminants trapped on the screen of the wall or sediments deposited on the floor and periodically removing various contaminants.

The rainwater storage tanks according to the present invention are capable of capturing, dehydrating and collecting sediment sludge without any force. Areas requiring cleaning are captured on a screen to collect debris, remove sludge collected in small-sized hoppers, And water rinsing of residual residues.

In the present invention, a person does not enter the tank where odor and noxious gas are generated, and operates in a space separated from the tank or performs unattended cleaning during the removal of deposited sediments and the cleaning and removing of the contaminated residue.

As the contaminated rainwater enters the tank, the contaminants are trapped in the wall screen 20 and the particulate solids passing through the wall screen 20 stay in the tank and settle to the bottom and collect along the hopper slope 43 to the bottom of the central hopper .

When the stored rainwater is drained after a predetermined time elapses according to the drainage plan of the rainwater storage tank, as the water level in the tank is lowered, the impurities trapped on the wall screen 20 descend together and some of the impurities are exposed to the atmosphere while being attached to the screen .

In this process, the pressure water is injected from the central portion of the tank through the nozzle toward the screen to back wash the screen, so that the contaminants attached to the screen are torn off and fall into the bottom inclined V-shaped channel 31.

As the contaminated water flows into the inclined V-type water channel 31, the impurities trapped in the water channel 31 and the contaminants desorbed in the screen backwashing are piled up. Therefore, And transports it to the dirt-dehydrating box 30 on the downstream side of the water channel 31.

In this process, when the contaminants in the water channel 31 are not well conveyed, or when the contaminants are not desorbed even though they are cleaned with nozzles installed at the front and rear of the screen, the water can be discharged through the manhole 12 and the inspection port 18, It is transported or tared using a stick or the like.

The impurities conveyed to the dewatering box 30 are allowed to stand for a predetermined time to naturally dewater, and the dewatered dirt is picked up and collected through a manhole 12 on the upper structure dewatering box 30 by using a forklift or the like.

Next, as a sludge removing operation in the hopper, a suction pump is connected to the end pipe 96 of the roll cylinder 92 to which the sludge suction pipe 93 is connected, and the sludge suction pipe 93 of the sludge suction pipe 93 94) are sequentially inserted, and the sludge collected in each of the passages and the hopper is sucked and discharged to the outside while repeating advancing and retreating.

At this time, the washing water, the water in the water supply tank, or the tank separately stored in the tank is backwashed through the nozzles, the surface of each hopper is cleaned, and the contaminated washing water generated in this process is sucked and removed together with the sludge.

If the screen, hopper, passage pipe, etc. are contaminated with oil and it is difficult to clean, wash with hot water.

On the other hand, when a person enters the tank, such as the number of facilities, maintenance, etc., cleaning or ventilating work is carried out in a state in which the generation of bad odor or noxious gas is reduced to a safe level and the movable work foot is moved to the hopper inclined surface 43, Work on the straight line 44.

Washing water is supplied from the outside as clean water or it is used as tank water.

The washing water supplied from the outside is not necessary in the vehicle having the water storage tank or using the water supply. Since this method uses the own pump or there is already the pressure, a separate washing water supply pump is not necessary.

The method of using the tank water as the washing water is to use the water obtained by collecting the supernatant in which the particulate solid material has settled in the middle of the rainfall or in the middle of the rainfall, In this case, a separate water intake pump is required for taking in the upper water in the tank.

On the other hand, a washing water supply pump is not necessary when the water is directly connected to the washing water. However, when the washing water stored in the washing water storage room 1e is used, a separate washing water supply pump 81 is required.

The present invention can be applied to a partial application of a wall screen, a grid-type multi-hopper, a sludge suction facility, a washing facility, and an additional purification facility for the use of wash water in tank reservoirs for improvement of existing concrete storage facilities or new installation of storage facilities, It is applicable.

Another embodiment of the present invention will be described.

(Example 1)

As shown in Fig. 8, the three-sided application example of the wall surface screen 20 and the wall surface screen 20 extending on both wall surfaces is shown. The wall surface screen 20 and the V- And the dewatering box 30 formed of the perforated plate box 32 are extended to the side of the rainwater inflow port 13 and the adjacent sides of the rainwater inflow port 13 to capture a large amount of the contaminants introduced from the rainwater inflow port 13, Make dehydration quick.

(Example 2)

As shown in FIG. 9, the rainwater storage tank with the non-powered water quality management facility and the cleaning facility according to the second embodiment of the present invention includes a wall screen 20, a lattice type multi hopper 40, (101) and a microfiltration facility (100) are installed to secure clean water of high quality from the water stored in the tank.

The refinement screen 101, which is an additional refinement facility, is installed with a net smaller than the narrow net screen 21 of the wall screen 20 and has a depth enough to receive the supernatant in the space in front of the in- Install with a front sloping screen with an upward sloping front and a screen on the floor if necessary.

In the water intake of the upper water, the water having passed through the finishing screen 101 is supplied with a washing water intake pump 102 such as an underwater pump and is pumped to the washing water storage chamber 1e.

The cleaning of the detail screen 101 is carried out by installing a water spray nozzle 83 on the back surface of the screen, spraying backward the pressure water while the water in the tank is drained and exposed to the air, thereby causing the obstacles on the screen to fall down to the bottom of the tank.

The microfiltration facility 100 uses a horizontal filtration facility or a three-dimensional filtration apparatus using continuous filtration apparatus applied in Patent Application No. 10-2012-22947 in a space separated from the tank water by using a fibrous filter cloth such as particulate filter media or nonwoven fabric 9, a particulate filter medium such as sand and gravel and a horizontal filtration facility using a bottom collecting plate are installed on the upper wash water storage water of the wash water storage room 1e under the prefabricated foot 70 of the sludge suction space 1c It is.

The maintenance of the microfiltration facility shall be carried out in accordance with the general nonmagnetic particulate filtration facility and the maintenance method of the fibrous filter filtration facility.

The above-mentioned screen and fine filtration facilities are installed at a scale that allows the whole amount of influent water to be passed through, so that the treated water is treated and discharged all the way, and rainwater having high pollution level is transferred to the sewage treatment plant. Can be used as a way to protect the environment.

(Example 3)

Fig. 10 is a longitudinal sectional view of a third embodiment according to the present invention, Fig. 11 is an internal plan view of Fig. 10,

A box-like rainwater storage structure 10 having at least one manhole 12 in a predetermined region of a top plate 11, a rainwater inlet 13 at an upper portion of one side wall and a drainage port 4 at a lower portion of the other side wall;

A wall screen 20 installed in the form of a fence surrounding the rainwater inlet 13 at a predetermined distance from the rainwater inlet 13 of the rainwater storage structure 10 to filter various contaminants introduced through the rainwater inlet 13 )and;

A dewatering box 30 provided at a lower portion surrounded by the wall screen 20 and having a plurality of dewatering holes 33 for collecting dirt trapped in the wall surface screen 20 to naturally dewater;

A unit hopper 42 having a sludge outlet port 41 formed at a lower portion thereof so that the sludge having flowed through the rainwater inlet 13 together with the rainwater and passing through the wall screen 20 slides and is discharged downward, A plurality of hoppers 40 connected to the rainwater storage structure 10 at predetermined intervals upward from the bottom of the rainwater storage structure 10;

One end of the hopper 40 is located at the lower end of the hopper 40 and the other end of the hopper 40 is passed through the right end of the hopper 40 to pass through the wall formed with the drain 4. And a sludge inlet 51 is formed at a position corresponding to the sludge outlet 41 of the multiple hopper 40 so that the sludge introduced through the sludge inlet 51 is connected to another suction / A non-dynamic water quality management facility formed of a sludge passage pipe 50 arranged to be discharged to the outside, and a rainwater storage tank having a cleaning facility.

The rainwater storage structure 10 includes a ventilation pipe 14 provided on at least one top plate 11, a manhole cover 15 covering the manhole 12, A ladder 17 installed in a lower direction of the manhole 12 and an inspection port 18 provided in an area of the upper plate 11 and a grating lid 19 covering the inspection port 18 As shown in FIG.

It is possible to omit some facilities such as a sludge suction facility, a washing facility and a sludge suction space 1c separated into the first partition 2 from among the entire facilities of the present invention shown in FIG. 2, Or by using the portable equipment to inhale the sludge or perform the direct cleaning.

As described above, the present invention is as follows: (1) A non-motorized screen having no simple structure and having a simple structure is installed on the inner wall surface of the rainwater storage tank in a full inclined shape, and a V- And a debris dewatering box formed with a perforated plate at the downstream end of the water channel is installed,

② A large number of small hoppers are installed on the bottom of the storage tanks to collect the sediment sludge without power and bury the sludge passage pipes in a straight line from the first hopper to the rear hopper under the small multi hopper. The sedimentation sludge collected in each hopper is sucked and dredged in the space to be taken out to the outside,

③ After draining the tank water, the washing water is sprayed on the screen exposed to the atmosphere, and the impurities trapped on the screen are desorbed to fall down, the impurities accumulated in the inclined V-type water channel are sprayed with the pressure water, After dewatering for a certain period of time, dehydrated dirt is lifted from the outside of the tank by a forklift or the like,

(4) A rainwater storage tank with a non-motorized water quality management facility and a cleaning facility capable of cleaning and cleaning the residual sludge by spraying washing water into each hopper and sucking wash water and sludge together to manage and clean the water quality of the contaminated rainwater storage tank .

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the exemplary embodiments thereof, but is capable of numerous changes and modifications without departing from the spirit and scope of the invention as defined in the appended claims. will be.

1. 10: Rainwater storage structure 1a: Rainwater storage tank
1b: sludge suction tank 1c: sludge suction space
1d: drain pump room 1e: wash water storage room
2: first bank 3: second bank
4: drainage hole 11: top plate
12: Manhole 13: Rainwater inlet
14: Ventilation pipe 15: Manhole cover
16: Railing 17: Ladder
18: Checking hole 19: Grating lid
20: wall screen 21: narrow mesh screen
22: Wide mesh screen 23: Rod
30: Dewatering box 31: V-shaped channel
32: Perforated box 33: Dewatering hole
40: multiple hopper 41: sludge outlet
42: unit hopper 43: hopper slope surface
44: slope upper straight line 50: sludge passage pipe
51: sludge inlet 52:
53: leading pipe 60: discharging means
61: drain pump 62: pump inlet pipe
63: exhaust pipe 70: foot plate
80: Cleaning means 81: Feed pump
82: Supply piping 83: Water spray nozzle
84: valve 85:
90: suction and discharge auxiliary member 91: rail
92: Roller 93: Sludge suction pipe
94: end pipe
96: End pipe 100: Horizontal filtration facility
101: Split screen 102: Aspiration pump
103: particulate filter media 104:
105: Upper water intake space

Claims (20)

A rainwater storage tank 1a in which a partition wall 2 is formed at a predetermined position in a box-shaped water storage tank in which a top plate 11 is covered and a rainwater inflow port 13 is formed at one side of the side wall and a drainage tank 4 And a manhole 12 is provided in an area of the upper plate 11 of the sludge suction tank 1b and the rainwater storage tank 1a. The rainwater storage structure 1 is divided into a sludge suction tank 1b, and;
A wall screen 20 installed in the form of a fence surrounding the rainwater inflow port 13 at a predetermined distance from the rainwater inflow port 13 to capture various contaminants introduced through the rainwater inflow port 13;
The wall surface screen 20 is located between the wall surface screen 20 and the rainwater inflow port 13 of the rainwater storage tank 1a and is provided at a lower portion of the wall surface screen 20 so that a contaminant filtered by the wall surface screen 20 flows into the V- A dewatering box (30) having a plurality of dewatering holes (33) formed therein so as to be naturally dewatered;
The sidewall portion has a slope so that the sludge that has passed through the wall surface screen 20 slides and is discharged to the lower portion and the sludge discharge port 41 is provided at a lower portion of the sidewall portion A plurality of hoppers 40 connected in a lattice form to unit hoppers 42 of a funnel type;
A sludge inlet 51 is formed at a position corresponding to the sludge outlet 41 of the multiple hoppers 40 and is integrally formed with the sludge inlet 51 so that one end of the sludge inlet 51 is connected to the partition 2 A sludge passage pipe (50) penetrating the sludge suction pipe (1b) and positioned in the sludge suction tank (1b);
And a drainage means (60) installed in the sludge suction tank (1b) so as to discharge the rainwater introduced into the rainwater storage tank (1a) to the outside, and a rainwater storage tank The sludge suction apparatus according to claim 1, wherein the sludge suction tank is provided with a foot plate installed at a predetermined height of a middle portion of the sludge suction tank, And a second partition wall 3 is provided under the foot plate 70 so that one side is a wash water storage chamber 1e and the other side is a drain pump chamber 1d A rainwater storage tank with a non-motorized water quality management facility and a cleaning facility The rainwater storage structure according to claim 1 or 2, wherein the rainwater storage structure (1) comprises a rainwater storage tank (1a) and a ventilation pipe (14) provided at least one in each area of the upper plate (11) of the sludge suction tank A manhole lid 15 covering the manhole 12 and a fall prevention railing 16 erected on the upper side of the manhole 12 and a ladder 17 installed in a lower direction of the manhole 12, And a grating lid (19) covering the inspection port (18), and an inspection port (18) provided on the upper plate (11) of the rainwater storage tank (1a) Rainwater storage tank with built-in facility The sludge collecting system according to claim 3, further comprising a suction and discharge assisting member (90) installed at a predetermined position on the ceiling in the sludge suction tank (1b), and a rainwater storage tank 3. The rainwater storage system according to claim 2, wherein one end of the sludge passage pipe (50) is protruded above the foot plate (70). The rainwater storage tank [3] The apparatus according to claim 1 or 2, wherein the wall surface screen (20) is a linear screen or a lattice type screen and a perforated screen, Rainwater reservoir with non-motorized water quality management facility and cleaning facility        The water treatment system according to claim 1 or 2, wherein the wall surface screen (20) is installed as a front inclined screen inclined from the lower side to the upper side toward the rainwater inflow port (13) Stormwater storage tank The system of claim 1 or 2, wherein the wall screen (20) comprises a narrow mesh screen (21) at the bottom and a wide mesh screen (22) at the top. Rainwater storage tank with built-in facility 7. The apparatus of claim 6, wherein the rod (23) of the wall screen (20) is circular, rectangular, or triangular with a narrow front side and a wide back side, And a rainwater storage tank with a cleaning facility installed therein. The dewatering box (30) according to any one of claims 1 to 3, wherein the dewatering box (30) comprises a V-shaped water channel (31) having a sloped side and an open bottom and a perforated box (32) connected to a lower portion of the water channel A rainwater storage tank with a non-motorized water quality management facility and a cleaning facility  The dewatering device according to claim 1 or 2, wherein the dewatering box (30) is installed on the side of the rainwater inflow port (13) and on both sides adjacent thereto, and a rainwater storage tank The sewage treatment system according to claim 1 or 2, wherein the sludge passage pipe (50) is provided by connecting a vertical pipe (52) at a position corresponding to the sludge discharge port (41) Rainwater storage tank with water quality management facility and cleaning facility 2. The rainwater storage system according to claim 1, wherein the discharge means (60) is provided with a drain pump (61), a discharge pipe (63), and a pump inlet pipe (62) The washing machine according to claim 2, characterized in that the washing means (80) is provided by a wash water supply pump (81), a feed pipe (82), a spray nozzle (83), a valve (84) Rainwater storage tank with management facilities and cleaning facilities The sludge suction apparatus according to claim 4, wherein the suction and discharge assisting member (90) comprises: a rail (91) attached to a ceiling of a sludge suction tank (1b); a roll cylinder (92) 92) is provided with a sludge suction pipe (93) to be inserted into the sludge passage pipe (50), and a rainwater storage tank The sludge suction pipe (93) according to claim 15, wherein the sludge suction pipe (93) connects an end pipe (94) to the tip end, and the end pipe (94) is made of stainless steel, plated steel, aluminum or plastic having durability and corrosion resistance And a rainwater storage tank with a cleaning facility installed therein. The rainwater inflow port (13) according to claim 2, wherein the rainwater inflow port (13) is provided at a depth sufficient to receive the supernatant water in the rainwater storage tank (1a) in front of the wash water storage room (1e) provided in the sludge suction tank (1b) And a washing water intake pump (102) installed in the water intake space (105). The washing water intake pump (102) is installed in the upper water intake space (105) A microfiltration facility 100 formed of granular material 103 of sand and gravel and a collecting plate 104 between the lower part of the foot 70 of the sludge suction tank 1b and the upper part of the washing water storage room 1e A rainwater storage tank with a non-motorized water quality management facility and a cleaning facility The washing machine according to claim 17, wherein a supply pipe (82) equipped with a water spray nozzle (83) is installed in the water intake space (105) so that the water splash screen (101) Rainwater storage tank with non-motorized water quality management facility and cleaning facility A box-like rainwater storage structure 10 having at least one manhole 12 in a predetermined region of a top plate 11, a rainwater inlet 13 at an upper portion of one side wall and a drainage port 4 at a lower portion of the other side wall;
A wall screen 20 installed in the form of a fence surrounding the rainwater inlet 13 at a predetermined distance from the rainwater inlet 13 of the rainwater storage structure 10 to filter various contaminants introduced through the rainwater inlet 13 )and;
A dewatering box 30 provided at a lower portion surrounded by the wall surface screen 20 and having a plurality of dewatering holes 33 formed therein so that the dirt trapped on the wall surface screen 20 is gathered and naturally dewatered;
A unit hopper 42 having a sludge outlet port 41 formed at a lower portion thereof so that the sludge having flowed through the rainwater inlet 13 together with the rainwater and passing through the wall screen 20 slides and is discharged downward, A plurality of hoppers 40 connected to the rainwater storage structure 10 at predetermined intervals upward from the bottom of the rainwater storage structure 10;
One end of the hopper 40 is located at the lower end of the hopper 40 and the other end of the hopper 40 is passed through the right end of the hopper 40 to pass through the wall having the drain 4 formed therein. And a sludge inlet 51 is formed at a position corresponding to the sludge outlet 41 of the multiple hopper 40 so that the sludge introduced through the sludge inlet 51 is integrated by separate suction means And a sludge passage pipe (50) arranged to be discharged to the outside, and a rainwater storage tank The rainwater storage structure (10) according to claim 19, wherein the rainwater storage structure (10) comprises a ventilation pipe (14) provided at least on the upper plate (11), a manhole cover (15) covering the manhole (12) A ladder 17 installed in a lower direction of the manhole 12 and an inspection port 18 provided in an area of the upper plate 11 and an inspection port 18 provided in the inspection port 18, And a grating lid (19) covering the rainwater storage tank (19). The rainwater storage tank

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