KR102178914B1 - Non-point pollution source sampling tank - Google Patents

Abstract

A non-point pollution source sampling tank is disclosed. The non-point pollution source sampling tank provides sampling water collected and pumped from a river through a water collection pump while maintaining a state of the sample water to be same as the raw water so as to perform accurate measurement. According to the present invention, the non-point pollution source sampling tank comprises a water tank, a first inlet pipe, a second inlet pipe, a backwashing pipe, a first overflow pipe, a second overflow pipe, a first drain pipe, a second drain pipe, a drain connection pipe, and a water collector holder.

Description

Non-point pollution source sampling tank

The present invention relates to a non-point source sampling tank installed in a measuring station, and more particularly, by maintaining the sample water collected and pumped from a river through a water sampling pump in the same state as the raw water and providing it to the measuring equipment so that accurate measurement can be made. It relates to a non-point source sampling tank.

In general, water pollutants are classified into point and non-point sources according to the nature of the pollutant, and point sources are pollutants discharged in the form of sewers or ditches from the point that pollutant emissions can be clearly identified, and nonpoint sources are rainwater from a wide area. It is a pollutant source that is discharged from scattered pollutants where it is difficult to know exactly where the discharge source is as it is washed away by the back.

Examples of non-point pollutants include agricultural land, pastures, urban streets, forest lands, and suburbs, and potential pollutants near the soil surface or surface are washed by rainwater and included in the runoff and flow into rivers to pollute the water quality.

To check whether rainwater containing pollutants contaminates the water quality, sample water is collected from a river through a water collector and pumped to the non-point source sampling tank installed at the measurement station. Water quality data such as electrical conductivity, water temperature, dissolved oxygen, and hydrogen ion concentration are acquired.

As an example of a sampling tank used to measure the water quality of a river, Korean Patent Nos. 10-0817329 and 10-1147138 are disclosed.

However, conventional sampling tanks have a feature of supplying sample water that meets the conditions by reducing the flow rate by reducing the flow rate while moving in a manner in which the sample water flows along the tank and suppresses bubbling and turbulence. If the sample water in the tank is filled from the top in a way that overflows, the sample water in the tank is not completely mixed up and down, and the properties of the sample water are stored in a state that is different from the top and the bottom, which makes accurate measurement difficult.

In addition, the conventional sampling tank has a structure in which the supplied sample water is stored and discharged in the tank, but there is no backwash structure that returns the supplied sample water to the tank without guiding it to the tank. In other words, depending on the situation, such as when there is a problem inside the tank or when contaminated sample water is pumped, there are cases where the pumped sample water is not stored in the tank and must be returned directly.However, the conventional sampling tank does not have such a structure. There is discomfort.

1) Korean Patent Registration No. 10-0817329 (Registration Date: March 20, 2008), Title of Invention: "Water Tank for Water Quality Measurement" 2) Korean Patent Registration No. 10-1147138 (Registration Date: May 10, 2012), Title of Invention: "Sampling Device for Water Quality Meter" 3) Republic of Korea Patent Registration No. 10-1192064 (Registration date: October 10, 2012), Invention title: "Water quality measuring device" 4) Republic of Korea Patent Registration No. 10-1769398 (Registration date: August 11, 2017), title of invention: "Multi-item water quality measuring device with antifouling ability"

The present invention has been proposed in order to improve the above-described problem, and the purpose is that the water tank is divided into a first tank room in which sample water flows in and a second tank room in which sample water is stored, and the number of samples is from the first tank room to the second tank room. The purpose is to provide a non-point source sampling tank that allows accurate measurements to be implemented by maintaining the state of raw water by flowing into the lower portion of the second tank chamber when transported and the sample water in the second tank chamber is completely mixed up and down.

In addition, another object of the present invention is to install two inlet pipes for supplying sample water to the first water tank chamber, divided into a first inlet pipe and a second inlet pipe, and between the first inlet pipe and the second inlet pipe. A backwashing structure is provided by installing a backwashing pipe that connects to, so in some cases, it is to provide a nonpoint source sampling tank so that the pumped sample water can be returned directly through the backwashing tube without storing it in the tank room.

The above objectives are the first tank that is installed apart from the ground by a leg, is closed in all directions by a front plate, a rear plate, a side plate, and a bottom plate, and the upper surface is opened, and the inside is divided by a partition wall. A water tank having a structure provided with a chamber and a second tank room, and when sample water is supplied to the first tank room, the bulkhead overflows to guide and store the sample water to the bottom of the second tank room; A first inlet pipe installed at the front plate of the water tank to be in communication with the first water tank chamber, connected to a pressure delivery pipe through which sample water is pumped by a submersible pump, and selectively opened and closed by a check valve installed at a portion; It is arranged in parallel with the first inlet pipe on the front plate of the water tank to be installed in communication with the first water tank chamber, is connected to the pressure delivery pipe through which sample water is pumped by the water pump, and selectively opened and closed by a check valve installed in a part Installed second inlet pipe; A backwash pipe installed to connect the first inlet pipe and the second inlet pipe to each other and selectively opened and closed by a check valve installed at a portion; A first overflow pipe installed at an upper end of the side plate of the water tank in communication with the first water tank chamber and extending downwardly to discharge water overflowing from the first water tank chamber; A second overflow pipe installed at an upper end of the other side plate of the water tank to be in communication with the second tank chamber and extending downwardly to discharge excess water from the second tank chamber; A first drain pipe installed to communicate with the first tank chamber from the bottom plate of the water tank and extend downward to allow water from the first tank chamber to be discharged for cleaning, and to be selectively opened and closed by a check valve installed in a portion ; A second drain pipe installed to communicate with the second tank chamber from the bottom plate of the water tank and extend downward to allow water from the second tank chamber to be discharged for cleaning, and to be selectively opened and closed by a check valve installed in a portion ; The first overflow pipe, the second overflow pipe, the first drain pipe, and the second drain pipe are installed in communication with the lower end portions, and a discharge pipe discharged to the outside is formed in communication in a part of the first overflow pipe and the second overflow pipe. A drain connection pipe for discharging water discharged from the flow pipe, the first drain pipe, and the second drain pipe to the outside through the discharge pipe; And a water dispenser in which the lower end is fixed by welding on the side plate of the water tank, and the upper end extends upward and is bent to be installed to be located above the second water tank chamber, so that the water dispenser can be installed so that it can be placed in the second water tank chamber. Including a hook; when the sample water supplied through the pressure delivery pipe is supplied to the first tank room through the first inlet pipe or the second inlet pipe with the check valve open, the sample water overflows the bulkhead and is guided to the second tank room. It is stored and configured to collect sample water through a water collector in the second tank chamber, and when the check valves of the first inlet pipe and the second inlet pipe are closed and the check valve of the backwash pipe is opened, the number of samples pumped through the pressure delivery pipe is It is configured to be sent back through the reverse customs pipe without being supplied to the first tank room, and the partition wall consists of a partition plate and a blocking plate, and the partition plate seals the space between the first tank room and the second tank room to allow water to pass through. The upper end of the partition plate is lower than the upper end of the water tank, so that the sample water flowing into the first water tank chamber overflows the partition plate and is guided to the second water tank room, and the blocking plate is spaced apart from the partition plate. It is installed so that the sample receiving space is formed in between, and the upper part of the blocking plate is formed higher than the upper part of the partition plate, so that the sample water overflowing the partition plate is blocked on the upper part of the blocking plate and falls into the sample receiving space. The bottom of the blocking plate is separated from the bottom of the water tank, and an open space is formed between them, and the sample water flowing into the sample water inlet space is stored in the second tank room from the bottom of the second tank room through the open space. The partition plate is installed to be fixed by welding between the first tank chamber and the second tank chamber, and the blocking plate is bent at both ends so that the bent piece protrudes in the direction of the partition plate, and a hook is formed at the top of the bent piece. It is configured to be hung on the partition plate, and when the blocking plate is hung on the partition plate through a hook, a sample receiving space is formed between the partition plate and the blocking plate by a bent piece, and the interior of the first tank chamber When the sample water is supplied to the first tank chamber by putting a plurality of cleaning balls in the tank, the cleaning balls move under the force and collide with the inside of the first tank chamber, causing moss to get caught. It is configured to clean so as not to be cleaned, but the cleaning ball is formed of a molding composition to have durability, cold resistance, and heat resistance, and the molding composition includes 10% by weight of dihydroxybutanediic acid, and PEBAX (Polyether-block-amide) 8.5 Weight%, calcium hydroxide and silicic acid are mixed in a weight ratio of 1:2, 15% by weight of a mixture, 5% by weight of sulforaphane, 5% by weight of ethylene glycol diacetate, 5% by weight of phenyltrimethoxysilane and the rest It is achieved by a non-point source sampling water tank, characterized in that it is made of polycarbonate resin.

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The non-point source sampling tank according to the present invention is divided into a first tank room in which sample water flows in and a second tank room in which sample water is stored, and a partition plate and a blocking plate are spaced apart between the first tank room and the second tank room. Therefore, when the sample water is transferred from the first tank room to the second tank room, it flows into the space between the partition plate and the blocking plate, and is guided to the lower part of the second tank room, so that the sample water bubbles in the second tank room. It is completely mixed up and down without excessive turbulence to maintain the state of the raw water, which has the effect of realizing accurate measurement when the sample water is pumped up and measured with a measuring device.

In addition, in the non-point source sampling tank according to the present invention, the first inlet pipe and the second inlet pipe are installed in parallel to the first tank chamber, and a reverse customs pipe connecting each other between the first inlet pipe and the second inlet pipe is installed. By having a backwashing structure, depending on the situation, such as when there is a problem inside the tank or when contaminated sample water is pumped, the number of samples pumped through the first inlet pipe or the second inlet pipe is not stored in the tank chamber. There is an effect that it can be sent directly back to the second inflow pipe or the first inflow pipe through customs.

In addition, when the sample water is returned to the first inlet pipe or the second inlet pipe through the backwashing pipe, the sample water is discharged along the pressure delivery pipe and there is an effect of washing the submersible pump by passing through the submersible pump in the reverse direction.

1 is a perspective view showing a non-point source sampling tank according to the present invention,
Figure 2 is a perspective view showing Figure 1 from the rear opposite side,
3 is a cut-away perspective view showing the inside of the tank by removing the front plate from the non-point source sampling tank according to the present invention;
4 is a cut-away perspective view of FIG. 3 from another angle;
5 is a plan view illustrating the operation of the non-point source sampling tank according to the present invention;
6 is a plan view showing a state in which the backwashing function is operated in FIG. 5.

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

Referring to FIGS. 1 to 5, the non-point source sampling tank according to the present invention includes a water tank 100 in which the sample water pumped from the river through the pressure delivery pipe 10 is stored.

The water tank 100 is installed to be spaced apart from the ground by a leg 102, is closed in all directions by a front plate, a rear plate, a side plate, and a bottom plate, and the upper surface has an open structure, and the inside is a partition wall 200 A first tank room 110 and a second tank room 120 are provided. In addition, when the sample water is supplied to the first tank chamber 110, the bulkhead 200 is flooded to guide the sample water to the bottom of the second tank chamber 120 and store it.

Here, the partition wall 200 is composed of a partition plate 210 and a blocking plate 220. That is, the partition plate 210 seals the space between the first tank chamber 110 and the second tank chamber 120 so that water cannot pass, and the upper end of the partition plate 210 is Since the height is lower than the upper end, the sample water flowing into the first tank chamber 110 overflows the partition plate 210 and is configured to be guided to the second tank chamber 120. At this time, at the upper end of the partition plate 210, inlet grooves 212 are formed in a number of places, so that the sample water overflows through the inlet groove 212 rather than overflowing the partition plate 210 as a whole, and the second tank chamber 120 It is good to organize it to be guided. And the blocking plate 220 is installed to be spaced apart from the partition plate 210 so that a sample receiving space 230 is formed therebetween, and the upper end of the blocking plate 220 is higher than the upper end of the partition plate 210 Is formed high and the sample water overflowing the partition plate 210 is blocked at the upper end of the blocking plate 220 and is configured to fall into the sample water inlet space 230. In addition, the lower end of the blocking plate 220 is separated from the bottom of the water tank 100, and an opening space 240 is formed therebetween, so that the number of samples flowing into the sample receiving space 230 is second through the opening space 240. It is configured to be stored in the second tank room 120 from the bottom of the tank room 120.

In addition, the partition plate 210 is fixedly installed between the first tank chamber 110 and the second tank chamber 120 by welding, and the blocking plate 220 is bent at both ends so that the bent piece 222 is a partition plate It is formed to protrude in the direction of (210) and a hook 224 is formed at the upper end of the bent piece 222, and is configured to be hung on the partition plate 210. Therefore, when the blocking plate 220 is hooked on the partition plate 210 through the hook 224, the sample receiving space 230 between the partition plate 210 and the blocking plate 220 is formed by the bent piece 222. Is formed.

Of course, in the present embodiment, the partition wall 200 is composed of the partition plate 210 and the blocking plate 220 so that the sample water overflows into the first tank chamber 110 and the sample receiving space 230 and the opening space 240 Although it has a structure that is stored from the bottom of the second tank chamber 120 through the structure, the structure of the partition wall 200 is that the sample water of the first tank chamber 110 overflows the partition wall 200 and the second tank chamber 120 ), if it can be guided to the floor and stored in the second tank room 120 from the floor, any structure will be applicable.

Next, a first inlet pipe 300 and a second inlet pipe 310 connected to the pressure delivery pipe 10 are installed in the water tank 100.

That is, the first inlet pipe 300 and the second inlet pipe 310 are arranged side by side with each other, each installed in communication with the first water tank chamber 110 on the front plate of the water tank 100, and the submersible pump ( It is connected to the pressure delivery pipe 10 through which the sample water is pumped by 20), and is installed to be selectively opened and closed by a check valve V installed in a part.

In addition, the first inlet pipe 300 and the second inlet pipe 310 are installed to be connected to each other through a backwash pipe 320, and a check valve V is also installed in a part of the backwash pipe 320, so that the check valve V ) Is configured to be selectively opened and closed.

Next, a first overflow pipe 400 and a second overflow pipe 410 through which water overflowing from the water tank is discharged are installed on both side plates of the water tank 100.

That is, the first overflow pipe 400 is installed in communication with the first water tank chamber 110 from the top of one side plate of the water tank 100 and extends downward so that water overflowing from the first tank chamber 110 It is configured to be discharged. In addition, the second overflow pipe 410 is installed in communication with the second water tank chamber 120 from the top of the other side plate of the water tank 100 and extends downward to discharge overflowing water from the second water tank chamber 120 It is configured to be.

Next, a first drain pipe 500 and a second drain pipe 510 are installed on the bottom plate of the water tank 100 to clean the water tank chamber.

That is, the first drain pipe 500 is installed from the bottom plate of the water tank 100 to communicate with the first tank chamber 110 and extends downward to discharge water from the first tank chamber 110 for cleaning. It is configured to be selectively opened and closed by a check valve V installed in a part. And the second drain pipe 510 is installed in communication with the second tank chamber 120 from the bottom plate of the water tank 100 and extends downward so that the water in the second tank chamber 120 is discharged for cleaning. And it is configured to be selectively opened and closed by a check valve (V) installed in a part.

And the lower ends of the first overflow pipe 400, the second overflow pipe 410, the first drain pipe 500, and the second drain pipe 510 are installed to be in communication through the drain connector 600, A discharge pipe 610 discharged to the outside is formed in communication with a part of the drain connection pipe 600 so that the first overflow pipe 400, the second overflow pipe 410, the first drain pipe 500, and the second It is configured to discharge water discharged from the drain pipe 510 to the outside through the discharge pipe 610.

Next, a water collecting device rack 800 is provided on a part of the water tank 100 to install a water dispenser (not shown) for collecting sample water. Here, the water sink holder 800 is configured such that the lower end is fixed to the side plate of the water tank 100 by welding, and the upper end is extended upward and then bent to be positioned above the second water tank chamber 120. Therefore, when the water dispenser is hung on the water dispenser holder 800, the water dispenser is contained in the second water tank chamber 120 to collect sample water.

In addition, on the rear plate of the water tank 100, the first withdrawal pipe 700 and the first withdrawal pipe 700 and the first withdrawal pipe 700 and the first withdrawal pipe 700 and the second withdrawal may be provided at positions corresponding to the first water tank room 110 and the second water tank room 120. Two withdrawal pipes 710 are respectively installed.

That is, the first withdrawal pipe 700 is installed in communication with the first water tank chamber 110 in the middle part of the rear plate of the water tank 100, and is configured to be selectively opened and closed by a check valve V installed in a portion. . In addition, the second withdrawal pipe 710 is installed to be in communication with the second water tank chamber 120 in the middle portion of the rear plate of the water tank 100 and is configured to be selectively opened and closed by a check valve V installed at a portion.

On the other hand, in the present invention, a check valve (V) installed in the first inlet pipe 300, the second inlet pipe 310, the backwash pipe 320, the first drain pipe 500, and the second drain pipe 510 Is applicable either manually or automatically, but it would be better to implement it automatically.

On the other hand, the present invention puts a plurality of cleaning balls (not shown) inside the first tank chamber 110, and when the sample water is supplied to the first tank chamber 110, the cleaning balls move under the force and the first tank chamber 110 ) It is desirable to be configured to clean it so that it does not collide with the interior of the moss.

The cleaning ball applied to the present invention is preferably manufactured by rolling a conventional aluminum foil into a spherical shape.

In addition, since the cleaning ball must have high water pressure resistance, and it must have resistance to ultraviolet rays, heat resistance, and cold resistance to achieve long life, it may be configured to manufacture by forming a specially formulated molding composition and then molding it.

At this time, the molding composition for manufacturing the cleaning ball is a mixture of 10% by weight of dihydroxybutanediic acid, 8.5% by weight of PEBAX (polyether-block-amide), and 15% by weight of a mixture of calcium hydroxide and silicic acid in a weight ratio of 1:2. , Sulforaphane (Sulforaphane) 5% by weight, ethylene glycol diacetate 5% by weight, phenyl trimethoxysilane 5% by weight, and the remaining polycarbonate resin.

Here, the dihydroxybutanediic acid is added to maintain a strong bonding property by reducing voids due to adsorption between resin particles when mixing, and to increase heat resistance and cold resistance. In addition, PEBAX (Polyether-block-amide) has a small change in hardness even at low temperatures, has excellent fatigue resistance, and has excellent molding processability due to its low specific gravity, as well as low hygroscopicity, bending fatigue resistance, weather resistance, flexibility, and creep resistance. It is added to ensure good properties and excellent adhesion. In addition, in the case of a mixture in which calcium hydroxide and silicic acid are mixed in a weight ratio of 1:2, calcium hydroxide is dissolved in water to generate free calcium ions, and the free calcium ions and silicic acid react to generate CSH gel. It increases the function of filling pores and cracking due to film formation, blocking salt damage, and reinforcing waterproofing. In addition, the sulforaphane (C ₆ H ₁₁ NOS ₂ ) is added to suppress decay and increase resistance to ultraviolet rays to maintain discoloration resistance, durability, and crack resistance. In addition, the ethylenic glycol diacetate promotes the gelation of the silicic acid mixture and maintains a strong bond to secure tensile strength and reinforce rust prevention function. Furthermore, the phenyltrimethoxysilane has a high freezing inhibitory property and is very effective in suppressing freezing. This enhances durability by suppressing cracks due to shrinkage and expansion. In addition, the polycarbonate resin is a base resin having very strong heat resistance, durability, and cold resistance.

In addition, in the present invention, in order to further enhance the water pressure resistance, the molding composition includes 5 parts by weight of ATO (Antimony doped Tin Oxide), 5 parts by weight of allophene powder, and 10 parts by weight of hydrocolloid based on 100 parts by weight of the molding composition. Wow, 3.5 parts by weight of apatite powder, 2.5 parts by weight of dichlorodimethylsilane, 5 parts by weight of nonylphenol ethoxylate, and 10 parts by weight of 2-phenylimidazole may be further added.

At this time, ATO contributes to securing heat insulation and heat shielding performance, and allophene powder is made by pulverizing a porous allophene clay mineral to have a particle size of 0.01mm or less, and is made of porous fine particles, so it has excellent humidity control function. Therefore, it is added to exhibit this effect. In addition, hydrocolloid is added to strengthen adhesion by determining adhesion for a long time by forming a gel and maintaining a wet state. It is particularly flexible and strengthens waterproofing and water repellency so that wettability does not occur. It is added to strengthen. In addition, apatite is a mineral belonging to the hexagonal system, and has a complex structure to enhance the water pressure resistance. In addition, dichlorodimethylsilane is a material that exhibits very strong hydrophobicity because it has two chlorine atoms, which have the second largest electronegativity after fluorine (F), and has excellent waterproof and water repellency, contributing to the reinforcement of water pressure resistance. In addition, nonylphenol ethoxylate is added to provide a surface-active function while increasing the compatibility with the resin, and in particular, to obtain an antioxidant effect. In addition, 2-phenylimidazole reduces the rate of heat shrinkage during drying, thereby enhancing heat stability, discoloration resistance, and resin deterioration suppression.

Now, a method of using the non-point source sampling tank according to the present invention configured as described above will be described.

When the sample water is collected, when the sample water is pumped through the pressure delivery pipe 10, it is supplied to the first water tank chamber 110 through the first inlet pipe 300 or the second inlet pipe 310. At this time, the first inlet pipe 300 and the second inlet pipe 310 are selectively used, and are removed through the first inlet pipe 300 or the second inlet pipe 310 in which the check valve V is open. 1 Sample water is supplied to the tank chamber 110. Of course, if the sample water is usually supplied through the first inlet pipe 300 and a problem occurs in the first inlet pipe 300, the sample water is supplied through the second inlet pipe 310.

That is, as shown in Figure 5, the check valve (V) of the first inlet pipe (300) is opened and the second inlet pipe (310) and the check valve (V) of the back tubing (320) are closed, When the sample water is pumped through 10), the sample water is supplied to the first tank chamber 110 through the first inlet pipe 300.

Next, the sample water supplied to the first water tank chamber 110 is filled up to the upper end of the partition plate 210 forming the partition wall 200, and when it is greater than that, the sample water is inflow groove 212 of the partition plate 210 ) Through the sample water inlet space 230 and falls, and is filled in the second tank room 120 from the bottom of the second tank room 120 through the opening space 240.

Therefore, when the sample water supplied along the pressure pipe 10 by the pumping force of the submersible pump 20 is filled in the first tank chamber 110, bubbling and turbulence occur, but the second water overflows the bulkhead 200 When the tank chamber 120 is filled, there is no bubbling and turbulence, and since the sample water is filled from the bottom of the second tank room 120, the sample water stored in the second tank room 120 is completely mixed. Accurate measurement data can be obtained if the sample water is collected and measured through a water extractor while maintaining the state as it is.

In addition, the sample water that overflows in the first tank chamber 110 and the second tank chamber 120 is naturally discharged through the corresponding first overflow pipe 400 and the second overflow pipe 410, and thus the drain connection pipe. It is discharged to the outside through the discharge pipe 610 of 600. In addition, when cleaning the first water tank chamber 110 and the second water tank chamber 120, opening the check valve V of the first drain pipe 500 and the second drain pipe 510, the first water tank chamber 110 ) And the water filled in the second tank chamber 120 are discharged to the outside through the discharge pipe 610 of the drain connector 600 through the first drain pipe 500 and the second drain pipe 510 together with foreign substances. .

On the other hand, depending on the situation, such as when there is a problem inside the tank or when contaminated sample water is pumped, there may be a case where the pumped sample water must be returned directly without being stored in the tank. In this case, shown in FIG. As described above, the check valve V of the first inlet pipe 300 and the second inlet pipe 310 is closed, and the check valve V of the backwash pipe 320 is opened. Then, the sample water that is pumped through the pressure delivery pipe 10 is not supplied to the first tank chamber 110 and is sent back through the backwash pipe 320. That is, the check valve (V) of the first inlet pipe (300) and the second inlet pipe (310) is closed and the check valve (V) of the backwash pipe (320) is open, 1 When sample water is supplied to the inlet pipe 300, the pumped sample water does not enter the first tank chamber 110 and is discharged to the second inlet pipe 310 through the backwash pipe 320, and thus the other pressure pipe 10 Is discharged. Therefore, the pumped sample water does not enter the water tank 100 and is circulated to operate the backwashing function that is discharged again.

At this time, the discharged sample water is to wash the submersible pump 20 while passing through the submersible pump 20 installed in the pressure delivery pipe 10 in the reverse direction. This backwashing function is used when washing the submersible pump 20.

As described above, the present invention has been illustrated and described in connection with specific embodiments, but those skilled in the art have known that various modifications and changes are possible within the limit without departing from the spirit and scope of the invention indicated by the claims. Anyone who grows up will be easily aware of it.

10: pressure pipe 20: submersible pump
100: water tank 110: first water tank
120: first tank room 200: bulkhead
210: partition plate 220: blocking plate
230: sample receiving space 240: open space
300: 1st inflow pipe 310: 2nd inflow pipe
320: reverse customs pipe 400: first overflow pipe
410: second overflow pipe 500: first drain pipe
510: second drain pipe 600: drain connector
610: discharge pipe 700: first outlet pipe
710: 2nd drawer 800: water dispenser
V: check valve

Claims (5)

It is installed apart from the ground by a bridge, is blocked in all directions by a front plate, a rear plate, a side plate, and a bottom plate, and the upper surface has an open structure, and the inside is divided by a partition wall. A water tank having a structure in which the sample water is guided to the bottom of the second tank room by flooding the partition wall when the sample water is supplied to the first tank room; A first inlet pipe installed at the front plate of the water tank to be in communication with the first water tank chamber, connected to a pressure delivery pipe through which sample water is pumped by a submersible pump, and selectively opened and closed by a check valve installed at a portion; It is arranged in parallel with the first inlet pipe on the front plate of the water tank to be installed in communication with the first water tank chamber, is connected to the pressure delivery pipe through which sample water is pumped by the water pump, and selectively opened and closed by a check valve installed in a part Installed second inlet pipe; A backwash pipe installed to connect the first inlet pipe and the second inlet pipe to each other, and selectively opened and closed by a check valve installed at a portion; A first overflow pipe installed at an upper end of the side plate of the water tank to be in communication with the first tank chamber and extending downwardly to discharge water overflowing from the first tank chamber; A second overflow pipe installed at an upper end of the other side plate of the water tank to be in communication with the second tank chamber and extending downwardly to discharge excess water from the second tank chamber; A first drain pipe installed to communicate with the first tank chamber from the bottom plate of the water tank and extend downward to allow water from the first tank chamber to be discharged for cleaning, and to be selectively opened and closed by a check valve installed in a portion ; A second drain pipe installed to communicate with the second tank chamber from the bottom plate of the water tank and extend downward to allow water from the second tank chamber to be discharged for cleaning, and to be selectively opened and closed by a check valve installed in a portion ; The first overflow pipe, the second overflow pipe, the first drain pipe, and the second drain pipe are installed in communication with the lower end portions, and a discharge pipe discharged to the outside is formed in communication in a part of the first overflow pipe and the second overflow pipe. A drain connection pipe for discharging water discharged from the flow pipe, the first drain pipe, and the second drain pipe to the outside through the discharge pipe; And a water dispenser in which the lower end is fixed by welding on the side plate of the water tank, and the upper end extends upward and is bent to be installed to be located above the second water tank chamber, so that the water dispenser can be installed so that it can be placed in the second water tank chamber. Including a hook; when the sample water supplied through the pressure delivery pipe is supplied to the first tank room through the first inlet pipe or the second inlet pipe with the check valve open, the sample water overflows the bulkhead and is guided to the second tank room. It is stored and configured to collect sample water through a water collector in the second tank chamber, and when the check valves of the first inlet pipe and the second inlet pipe are closed and the check valve of the backwash pipe is opened, the number of samples pumped through the pressure delivery pipe is It is configured to be sent back through the station customs office without being supplied to the first tank room.
The partition wall is composed of a partition plate and a blocking plate,
The partition plate seals the space between the first tank chamber and the second tank chamber so that water cannot pass, and the upper end of the partition plate is lower than the upper end of the water tank, and the sample water flowing into the first tank chamber overflows the partition plate. It is configured to be guided to the second tank room,
The blocking plate is installed to be spaced apart from the partition plate to form a sample receiving space therebetween, and the upper end of the blocking plate is formed higher than the upper end of the partition plate, so that the number of samples overflowing the partition plate The bottom of the blocking plate is separated from the bottom of the water tank, and an opening space is formed therebetween, so that the sample water flowing into the sample water inflow space passes through the open space to the bottom of the second tank chamber. It is configured to be stored in the second tank room from
The partition plate is fixedly installed between the first tank chamber and the second tank chamber by welding,
The blocking plate is configured so that both ends are bent so that the bent piece protrudes in the direction of the partition plate, and a hook is formed at the top of the bent piece so that it can be hung on the partition plate. When the blocking plate is hooked to the partition plate, By this, a sample receiving space is formed between the partition plate and the blocking plate,
When the sample water is supplied to the first tank by putting a plurality of cleaning balls inside the first tank room, the cleaning ball moves under the force and is configured to collide with the inside of the first tank room to clean it from moss,
The cleaning ball is molded from a molding composition and is configured to have durability, cold resistance, and heat resistance,
The molding composition includes 10% by weight of dihydroxybutanediic acid, 8.5% by weight of PEBAX (Polyether-block-amide), 15% by weight of a mixture of calcium hydroxide and silicic acid in a weight ratio of 1:2, and sulforaphane (Sulforaphane) 5 A non-point source sampling tank, characterized in that consisting of a weight%, ethylene glycol diacetate 5% by weight, phenyltrimethoxysilane 5% by weight and the rest of the polycarbonate resin. delete delete delete delete

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