KR200317215Y1 - Cylindric water tank - Google Patents

Abstract

The present invention is to be joined to the bottom plate and the top plate to form a chamber in which a plurality of cylindrical receptors having different outer diameters are arranged concentrically inside the circular receiving body which secures a chamber of a predetermined size to accommodate the fluid. In particular, the present invention relates to a cylindrical reservoir tank, and in particular, a chamber formed by the receiving body and the cylindrical receptor is divided into a plurality of walls in the upper chamber of the cylindrical receptor to weld the overflow guide wall to guide the flow of the incoming fluid in a desired direction. By forming a flow hole so that the fluid contained in any one of the outer chamber flows to the adjacent inner chamber, the fluid can be evenly distributed in the reservoir, and also to ensure the longest residence time of the fluid in the reservoir Provide a cylindrical reservoir.

Description

Cylindrical Water Tank

According to the present invention, a plurality of cylindrical receptors having different outer diameters are concentrically arranged in a plurality of compartments inside a circular accommodating body having a predetermined size accommodating space secured to accommodate fluid by being bonded to a bottom plate and a top plate. The present invention relates to a cylindrical reservoir tank, and more particularly, to a cylindrical reservoir tank for allowing fluid to be evenly distributed in the reservoir tank, and to secure the maximum residence time of the fluid in the reservoir tank.

In general, the cylindrical reservoir (1) used in water purification, drainage, etc. is a facility that can disinfect chemicals and water at the same time to be mixed with each other to disinfect or temporarily store the water used as a constant.

The cylindrical reservoir 1 is formed with an inlet pipe 2 through which water is introduced, and a disinfecting chemical inlet (not shown) for injecting disinfecting chemicals according to the use of a purified water or a drainage basin is provided separately. A water discharge pipe 3 for discharging water is provided at the bottom.

In detail, as shown in FIG. 1, the base portion 4 is provided on the ground to support the balance and load of the reservoir 1, and the receiving body 5 of the cylindrical reservoir 1 is installed thereon. The upper and lower portions of the accommodating body 5 are each welded and sealed by a top plate 6 and a bottom plate (not shown) made of stainless material of the same material as the accommodating body 5, and the accommodating body 5 is A cylindrical outer wall 10 is provided at the outermost side, and a plurality of cylindrical receptors 11a, 11b, 11c whose inner diameter gradually decreases are welded to the bottom plate and the upper plate 6 as shown in FIG. .

Here, the cylindrical receptors 11a, 11b, and 11c that are erected and welded to the interior of the cylindrical outer wall 10 have the same structure and configuration, but have a difference in diameter and smallness of the outermost cylinder for ease of explanation. From the receptor 11a, the serial numbers (the first cylindrical receptor 11a, the second cylindrical receptor 11b, and the third cylindrical receptor 11c) are assigned.

Meanwhile, the water flowing into the water inlet pipe 2 flows into the first chamber 12a partitioned between the cylindrical outer wall body 10 and the first cylindrical container 11a, and then the upper portion of the first cylindrical container 11a. (B) flows into the second chamber 12b formed between the second cylindrical receptor 11b and the first cylindrical receptor 11a through a distribution hole (not shown) formed in the lower portion thereof, and the third chamber 12c in this manner. ) And the fourth chamber (12d), the water is eventually filled in the first, second, third, fourth chamber (12a, 12b, 12c, 12d) in the receiving body (5). will be.

As described above, when water is discharged after the water is accommodated in the housing body 5 or during the process of receiving water, the water in the fourth chamber 12d is discharged by opening a valve (not shown) coupled to the water outlet pipe 3. (3) to be discharged through the bar, when draining the water of the fourth chamber (12d) of the third chamber (12c) through the distribution holes formed in the upper and lower ends of the third cylindrical container (11c) Water flows into the fourth chamber 12d and water in the second chamber 12b flows into the third chamber 12c and water in the first chamber 12a flows into the second chamber 12b in this manner. It is discharged.

However, in the conventional cylindrical water tank, vortex generation is severe due to the flow of water in the partitioned chamber 12, and vibration and noise are generated by this, in particular, as a distribution hole formed at the top and bottom of the cylindrical container 11 without regularity. As the inflow / outflow of water shortens the chlorine administered for disinfection in the reservoir, the disinfection effect is lowered, and accordingly, sufficient disinfection cannot be achieved.

That is, since the cylindrical receptor 11 can receive water in each chamber 12 and flow in and out through the upper and lower distribution holes, there is no time for water to be evenly mixed, and in this state This drainage causes the problem of using uncontaminated contaminated water.

On the other hand, when the distribution hole is formed only at the upper end of the cylindrical receptor 11 and the reservoir is not formed at the lower end of the water tank, when the incoming water rises to the upper part and flows into the distribution hole of the cylindrical receptor 11, the water is horizontal. Because of the movement, the water in the bottom part cannot rise to the upper part and cannot move to other chambers, thereby becoming a catcher, and causing contamination of the inside of the reservoir, such as creating an environment where moss can grow inside the reservoir. Will have the problem of providing.

The present invention devised to solve the above problems, the water contained in the chamber to stay as long as possible, and at the same time to induce the water in the chamber to flow in a certain direction to the water near the bottom surface can rise to the top. In addition to providing an instrument, it also prevents the vortex phenomenon and stabilizes the flow of water like a normal flow, and also provides the purpose of minimizing vibration and noise by enabling structural stabilization even in the water pressure of the water contained in the chamber.

1 is an exploded perspective view showing the structure of a conventional cylindrical reservoir.

Figure 2a is a view showing the structure of a cylindrical reservoir according to the present invention.

Figure 2b is a view showing a fluid flow according to the present invention.

Figure 3 is a functional diagram showing the fluid flow of the present invention cylindrical reservoir.

<Description of Major Symbols in Drawing>

101: receiving body 102: chamber

103: cylindrical receptor 104: overflow current wall

105: overflow hole 110: the bottom plate

111: top plate 112: water supply pipe

The above object, according to the present invention, is bonded to the bottom plate 110 and the top plate 111 is different from each other inside the circular receiving body 101 to secure the chamber 102 of a predetermined size to accommodate the fluid In a cylindrical reservoir tank in which a plurality of cylindrical receptors 103 having an outer diameter are arranged concentrically to form a receiving space, the chamber 102 formed by the receiving body 101 and the cylindrical receptor 103 is divided. The overflow guide wall 104 is welded to guide the flow of the fluid flowing in the desired direction, and a plurality of overflow holes 105 are formed at a predetermined position on the upper portion of the cylindrical container 103 to form a chamber 102 on the outside. A fluid reservoir is achieved by a cylindrical reservoir characterized in that the fluid flows into the adjacent inner chamber (102).

And, the distance between the outer diameter surface of the cylindrical receptor 103 and the inner diameter surface of the other cylindrical receptor 103 adjacent to the outside is the outer diameter of the inner cylindrical surface of the cylindrical receptor 103 and another cylindrical receptor 103 inwardly adjacent. Cylindrical receptors 103 are arranged to be smaller than the distance between the surfaces.

Hereinafter, the configuration and operation of the present invention will be described with reference to the accompanying drawings, FIGS. 2 to 3.

Figure 2a is a view showing the overall configuration of the present invention, Figure 2b is a view showing the flow of water introduced into the chamber 102 of the cylindrical reservoir of the present invention.

First, the receiving body 101 is fixed to the upper portion of the base made of concrete and frame structure, the bottom plate 110 is welded to the lower end of the receiving body 101 and the upper plate 111 is welded to the top.

And, inside the receiving body 101, cylindrical receptors 103 of different diameters are arranged concentrically, as shown in the figure, the smaller the diameter is arranged in the center of the receiving body 101, a plurality of cylindrical receptors The chamber 102 in a predetermined space can be formed between the 103 and the cylindrical receptor 103.

Here, in order to explain the structure of the cylindrical receptor 103 of the receiving body 101, each cylindrical receptor 103 has the outermost cylindrical outer wall and the first, second, third, fourth in order toward the center side. The serial numbers are assigned to the cylindrical receptors 103a, 103b, 103c, and 103d, and the size of the fourth chamber 102d formed between the fourth cylindrical receptor 103d and the third cylindrical receptor 103c is the third cylinder. The size of the receiving space of the third chamber 102c formed between the receptor 103c and the second cylindrical receptor 103b is equal to or greater than that, and the size of the third chamber 102c is the second cylindrical receptor 103b and the first. The size of the receiving space is greater than or equal to that of the first cylindrical container 103a and the second chamber 102b, and the first chamber 102a between the first cylindrical container 103a and the receiving body 101 is a second chamber ( It is preferable to arrange and arrange each cylindrical container 103 so that the receiving space may be larger than or equal to 102b).

Therefore, while the water flowing from the water inlet pipe is filled in each chamber 102, the water pressure acting on the cylindrical receptor 103 is equally divided horizontally and vertically, and thus, the one cylindrical receptor 103 is applied. Since the hydraulic pressure is offset by the amount of water contained in the adjacent cylindrical receptor 103, it is possible to prevent the cylindrical receptor 103 from bending or deforming from the hydraulic pressure.

On the other hand, the overflow induction wall 104 is welded between the outer cylinder surface of the first cylindrical receptor (103a) at a predetermined position of the inner surface of the receiving body 101, the overflow induction wall 104 is introduced into the chamber 102 By preventing the water from being circulated with each other, as shown in Figure 2b or 3, the water flowing from the inlet pipe 113 can flow from the inflow side toward the other side of the overflow induction wall 104. Make sure

Here, when the water moving toward the other side of the overflow induction wall 104 rises to a predetermined water level, the water flows into the plurality of overflow holes 105 formed on the other side of the overflow induction wall 104 and the adjacent inner chamber ( 102, so that water flows steadily or rises from the bottom of the chamber 102, so that the water does not stay in any one chamber 102 for a long time and moves steadily. For example, as follows.

First, the water introduced into the first chamber 102 flows in the counterclockwise direction toward the other side of the overflow-flow inducing wall 104, and the water introduced into the water inlet pipe 112 gradually increases, thereby increasing the first chamber 102a. ) When the water reaches the water level up to the overflow hole 105 formed on the other side of the overflow flow guide wall 104 flows through the overflow hole 105 to the second chamber 102b.

In addition, the water introduced into the second chamber 102b does not flow in the clockwise direction by the overflow induction wall 104 but again flows in the counterclockwise direction to reach the other side of the overflow induction wall 104. When the water level of the water contained in the second chamber (102b) reaches the proper level, the water flows back into the third chamber (102c) through the overflow hole (105). Thus, the fourth chamber (102d) in the third chamber (102c). The furnace is moved from the fourth chamber 102d to the fifth chamber 102. As shown in FIG. 2B, the water flowing into the chamber 102 flows in one direction by the overflow flow guide wall 104. .

At this time, since the overflow hole 105 is formed in the upper portion of the cylindrical container 103, the water in the chamber 102 stayed at the lower portion of the chamber 102 while having a constant flow by the overflow flow guide wall 104. Induces a constant flow, and thus the water flowing is mixed with the rising to be able to move to the adjacent chamber 102 through the overflow hole 105.

As described above, the present invention allows the water to continuously flow even if water is received into the chamber formed between the cylindrical receptors so that there is no water staying at any one place, and at the same time, the residence time of the water from the inlet pipe to the outlet pipe is reduced. It is a very useful design that has the effect of increasing the disinfection effect of water by securing the chlorine residence time by extending as much as possible to use hygienic water.

Claims (2)

Cylindrical water tank, which is formed by concatenating a plurality of cylindrical receptors having different outer diameters into concentric circles inside the circular accommodating main body, which is secured to the bottom plate and the top plate to secure a chamber of a predetermined size to accommodate the fluid. To By separating the chamber formed by the receiving body and the cylindrical receptor to weld the overflow induction wall to guide the flow of the incoming fluid in the desired direction, and forming a plurality of overflow holes in the upper predetermined position of the cylindrical receptor any one chamber outside A cylindrical reservoir, characterized in that the fluid received in the overflow to the adjacent inner chamber. The method of claim 1, Arranging the cylindrical receptor so that the distance between the outer diameter surface of the cylindrical receptor and the inner diameter surface of the other cylindrical receptor adjacent to the outside is smaller than the distance between the inner diameter surface of the cylindrical receptor and the outer diameter surface of another cylindrical receptor adjacent inward Cylindrical reservoir, characterized in that.