KR20210147178A - A Distribution Channel for parallely comnected Reaction Chambers - Google Patents

Abstract

The present invention relates to a distribution water channel for reaction chambers connected in parallel, and more particularly, to a distribution water channel for reaction chambers connected in parallel to have an improved structure arranged upstream of the reactor chambers connected in parallel for the flow of water to supply water to each reactor chamber so as to distribute and supply the most uniform flow rate to the reactor chamber. The present invention provides a distribution water channel for distributing the reaction target water to several reaction chambers connected in parallel, which includes: a first water channel having one side with an open inlet and a closed opposite side, and elongated in the same direction as the arrangement direction of the reactor chambers connected in parallel; a second water channel elongated in a direction parallel to the first water channel, having one side adjacent to the first water channel and an opposite side adjacent to several reactor chambers connected in parallel, and closed at both ends in the longitudinal direction; a connection plate installed between the first water channel and the second water channel and formed with a connection passage through which reaction target water passes; and a water passage port formed between the second water channel and each of the reactor chambers connected in parallel, wherein the reaction target water introduced into the first water channel through the inlet is introduced into the second water channel through the connecting water port, and flows into the reaction tank through the water passage port.

Description

{A Distribution Channel for parallely connected Reaction Chambers}

The present invention relates to a distribution channel for a reactor connected in parallel, and more particularly, it is disposed upstream of the reactor connected in parallel on the flow of water and has a structure so that when supplying water to each reactor, the flow rate can be distributed and supplied to the reactor as uniformly as possible. It relates to an improved distribution channel for parallel-connected reactors.

A reactor connected in parallel literally means a structure in which several reactors are connected in parallel. A typical example is a coagulation settling pond in a water purification plant. Most of the flocculation clarifiers in water purification plants have a very large capacity of the water to be purified, so they have a structure in which they are collectively collected after passing through several flocculation clarifiers installed in parallel.

Since it is a structure that disperses and flows from one inlet to several flocculation clarifiers installed in parallel, it is desirable that the amount of water to be purified is kept constant in each flocculation sedimentation basin. There is a problem that a relatively large amount of water flows in, and a relatively small amount of water flows into some coagulation sedimentation ponds.

1 is an example of a conventional distribution channel. There is an inlet 1 on the left side of the drawing, and the water flowing into the inlet flows into the coagulation and settling tanks 2 and 3 arranged in parallel; reference numeral 2 denotes a coagulation tank; When this structure is arranged, a relatively small flow rate flows into the coagulation settling tank located on the inlet side (left side of the drawing), and a relatively large flow rate flows into the coagulation settling tank located opposite the inlet side (right side on the drawing side).

2 is another example of a conventional distribution channel. Unlike the distribution channel shown in FIG. 1, it is a tapered distribution channel and has the advantage of distributing the flow rate relatively evenly compared to the distribution channel shown in FIG. 1, but efficiency is low when the flow rate flowing into the inlet 1 is irregular There is a problem with falling. Since the taper angle (θ) for evenly distributing the flow rate is a function of the flow rate, it is desirable to adjust the taper angle according to the changing flow rate when the flow rate changes. This is because it is a large structure with a large distribution channel as it is often more than 50 meters, although it is a reinforced concrete structure, so it is impossible to change the taper angle.

In the case of a flocculation clarifier with a relatively large flow rate, the sedimentation efficiency is low, resulting in a problem that suspended matter is not sufficiently removed. There is a problem with the material.

The present invention has been devised in order to solve the problems of the background art, and an object of the present invention is to provide a distribution channel for a parallel-connected reaction tank in which an equal flow rate distribution can be made to the reaction tanks installed in parallel.

The present invention as a means for solving the above problems,

In the distribution channel for distributing the reaction target water to several reaction tanks connected in parallel,

a first water channel having an open inlet on one side and closed on the other side and being elongated in the same direction as the arrangement direction of the plurality of reactors connected in parallel;

a second water channel which is long arranged in a direction parallel to the first water channel, one side is disposed adjacent to the first water channel, and the other side is disposed adjacent to a plurality of reactors connected in parallel and both ends in the longitudinal direction are closed;

a connecting plate formed with a connecting water hole through which the reaction target water can pass between the first water channel and the second water channel;

a water passage formed between the second water channel and each of the reactors connected in parallel; including

It provides a distribution channel for a reaction tank connected in parallel, characterized in that the reaction target water introduced into the first water channel through the inlet flows into the second water channel through the connection water port, and then flows into the reaction tank through the water passage port.

The connection water hole formed in the connection plate is a plurality of holes formed at regular intervals, and the connection plate may be configured in the form of a rectifying wall,

The connection water hole formed in the connection plate may be configured in the form of a weir formed on the top of the connection plate.

The water passage formed between the second water channel and the reaction tank is preferably in the form of a weir or an orifice.

According to the present invention, it is possible to provide a distribution channel for a parallel-connected reaction tank in which an equal flow rate distribution can be made to the reaction tanks installed in parallel.

1 and 2 are views for explaining a conventional distribution channel.
3 is a view for explaining the flow of the reaction target water in a distribution channel connected in parallel according to an embodiment of the present invention.
Figure 4 is a perspective view for explaining an embodiment of the distribution channel connected in parallel shown in Figure 3;
Figure 5 is a perspective view for explaining another embodiment of the distribution channel connected in parallel shown in Figure 3;
6 is a graph showing the results of computer analysis of an embodiment of the present invention and the prior art.

Hereinafter, specific contents for carrying out the present invention will be provided by describing preferred embodiments of the present invention with reference to the drawings.

3 is a view for explaining the flow of reaction target water in a distribution channel connected in parallel according to an embodiment of the present invention, FIG. 4 is a perspective view for explaining an embodiment of the distribution channel connected in parallel shown in FIG. 3 , FIG. 5 is a perspective view for explaining another embodiment of the distribution channel connected in parallel shown in FIG. 3, and FIG. 6 is a graph showing the results of computer analysis of an embodiment of the present invention and the prior art.

The distribution channel for parallel-connected reaction tanks according to the present embodiment relates to a distribution channel for distributing reaction target water to parallel-connected reaction tanks. The reaction tank may be a coagulation tank 2 and a settling tank 3 as shown in FIGS. 1 and 2 , and may be applied to filter paper. The reaction target water is the water that flows into the reaction tank. In the purification plant, the purified water becomes the reaction target water.

The distribution channel for a reaction tank connected in parallel according to this embodiment is configured to include a first water channel 10 , a second water channel 20 , a connecting plate 30 , and a water passage 40 .

As shown in FIG. 3 , the first water channel 10 is a long water channel and is disposed in the same direction as the arrangement direction of several reaction tanks. One side of the first water channel 10 has an open inlet 1 , and the other side is closed.

As shown in FIG. 3 , the second water channel 20 is long installed in a direction parallel to the first water channel 10 , and both ends in the longitudinal direction are closed. One side of the second water channel 20 is disposed adjacent to the first water channel 10 , and the other side is disposed adjacent to the plurality of reactors 2 connected in parallel.

The first water channel 10 and the second water channel 20 may be constructed of a reinforced concrete structure.

As shown in FIG. 3 , the connecting plate 30 is installed between the first water channel 10 and the second water channel 20 , and a connecting water hole through which the target water can pass is formed.

As shown in FIG. 4, the connecting water passage may be composed of a plurality of holes 31 formed at regular intervals, which is that the connecting plate 30 is configured in the form of a rectifying wall. The rectifying wall refers to a perforated wall for evenly flowing water, and since it is a configuration that can be fully understood by those of ordinary skill in the art to which the present invention pertains, further detailed description will be omitted.

On the other hand, as the connection water passage, as shown in FIG. 5, orifices 32 formed at regular intervals may be employed, or a weir (not shown) form may be employed, which is adopted according to the site conditions where they are installed.

The water passage is installed between the second water passage 20 and each of the reaction tanks connected in parallel, and the water to be treated flows into the second water passage 20 through the water passage into each of the plurality of reaction tanks. As shown in FIGS. 4 and 5 , the water passage may take the form of an orifice 40 or a weir form, which may also be employed according to the field situation.

Hereinafter, the effect of the present invention will be described by explaining the flow of water in the aforementioned distribution channel.

The reaction target water (target water for purification in the case of a water purification plant, sewage in the case of a sewage treatment plant) introduced through the inlet 1 flows into the first water channel 10 . The reaction target water moving along the first water channel 10 is introduced into the second water channel 20 through the connecting plate 30 . The reaction target water is introduced into the second water channel 20 at various locations through the connection water passage formed on the front surface of the connection plate 30 . The reaction target water introduced into the second conduit 20 flows into several reaction tanks (coagulation tank 2 in this embodiment). The flow of the reaction target water is indicated by an arrow in FIG. 3 . The inflow from the first waterway 10 to the second waterway 20 is made across the front surface of the connecting plate 30, and the fact that only a part of the arrows is shown is for convenience of illustration.

The table below shows the case in which the connecting plate 30 is in the form of a still wall (indicated as "the present invention" in the table) and the conventional invention shown in FIG. 1 (indicated as "comparative invention" in the table) among the embodiments of the present invention. This table shows the results of modeling and analysis by computer. There are seven reactors connected in parallel, and the first to seventh papers are indicated in the table, respectively. It is a modeling result of a coagulation sedimentation tank that is actually constructed and operated, and the inflow flow rate is set at 23,000m ³ per hour and is the result of modeling. The number indicated in the table is the inflow flow rate of each reactor and the unit is m ³ /s.

the present invention comparative invention paper 1 406.4 251.8 paper 2 324.9 283.2 paper 3 485.7 524.7 4th 492.5 539.4 paper 5 496.4 554.2 paper 6 529.5 569.2 Chapter 7 607.7 572.2

6 is a graphical representation of the above table.

The standard deviation of the present invention is 90.0, whereas the standard deviation of the comparative invention is 140.0, confirming that the flow rate is relatively evenly distributed in the present invention.

Even considering the deviation from the average, in the case of the present invention, the inflow of the second paper is 69% of the total average inflow, whereas in the comparative invention, the inflow of the first paper is 53% of the total average inflow, so that the even flow distribution of the present invention can be confirmed. is the result of doing In the case of the comparative invention, the first pond is the result that only about half of the average inflow into the reactor is introduced, and when the inflow is small, if the reactor is a coagulation sedimentation tank, anaerobic digestion is performed in the sedimentation tank, resulting in a possibility of worsening water quality.

1: inlet 10: first waterway
20: second channel 30: connecting plate
31: water hole 32: weir
40 : weir

Claims (4)

In the distribution channel for distributing the reaction target water to several reaction tanks connected in parallel,
a first water channel having an open inlet on one side and a closed side on the other side and extending in the same direction as the arrangement direction of the plurality of reactors connected in parallel;
a second water channel arranged long in a direction parallel to the first water channel, one side disposed adjacent to the first water channel, and the other side disposed adjacent to a plurality of reactors connected in parallel, both ends of which are closed in the longitudinal direction;
a connecting plate installed between the first water channel and the second water channel and having a connecting water hole through which the reaction target water can pass;
a water passage formed between the second water channel and each of the reactors connected in parallel; including
A distribution waterway for a parallel-connected reaction tank, characterized in that the reaction target water introduced into the first waterway through the inlet flows into the second waterway through the connecting waterway and then flows into the reaction tank through the waterway.
According to claim 1,
The connecting water passages formed in the connecting plate are a plurality of holes formed at regular intervals, and the connecting plate is in the form of a rectifying wall.
According to claim 1,
A distribution channel for a parallel-connected reaction tank, characterized in that the connecting water hole formed in the connecting plate is in the form of a weir formed on the upper part of the connecting plate.
According to claim 1,
A distribution channel for a parallel-connected reaction tank, characterized in that the water passage formed between the second water channel and the reaction tank is in the form of a weir or an orifice.

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