KR101998320B1 - Water flow distribution device of water treatment facility - Google Patents

Abstract

The present invention relates to a flow distribution device of a water treatment facility for distributing even flow to each filter provided in the water treatment facility. The device comprises: a filter unit to which feed water is distributed to a plurality of filters and filtered; an inlet unit installed upstream of the filter unit to distribute the feed water to the filter unit; and an outlet unit installed downstream of the filter unit and through which the treated water filtered out of the filter unit is mixed and discharged. The outlet unit is formed in a shape equivalent to the inlet unit. Therefore, in the present invention, by forming the inlet unit and the outlet unit in the same multi-stage shape, flow can be evenly distributed to the filter without installing a separate valve and a pressure regulator, and water pressure can be maintained constant, thereby enhancing distribution performance, discharge performance, and water treatment performance.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a water-

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a flow rate distribution apparatus for a water treatment facility, and more particularly, to a flow rate distribution apparatus for a water treatment facility for distributing an equal flow rate to each filter provided in a water treatment facility.

2. Description of the Related Art Generally, an inorganic membrane filter (membrane) equipped with a thin film formed with a large amount of fine pores is installed in a water treatment facility for filtering a feed water containing contaminants such as various impurities by filtration and filtering the same with treated water.

When the feed water flows into the water treatment facility, the feed water passes through the filter, and various impurities or the like can not be clogged by the micropores of the filter, and only the clean water flows out through the micropores of the filter.

At this time, impurities such as various impurities which are not clogged by the micropores of the filter are concentrated in the filter. If the impurities of various impurities are concentrated above a predetermined concentration, the pores of the filter are blocked and water can not pass therethrough. .

1, a filter unit 10, which is generally applied to a large-capacity water treatment plant, has a plurality of filters arranged in parallel between an inlet 20 and an outlet 30 arranged in parallel to each other, A plurality of distribution channels 25 are formed on the upper side of the filter unit 10 and the filter unit 10 is provided on the upper part of each distribution channel 25 and flows out through the outflow unit 30 on the upper side of the filter unit 10. [ do.

At this time, a high water pressure is applied to the filter unit 10 disposed near the inlet of the inlet unit 20, and a low water pressure is applied to the filter unit 10 disposed far from the inlet of the inlet unit 20 .

The filter portion 10 disposed near the inlet of the inflow portion 20 has a larger amount of water to be treated than the filter portion that is relatively different. Therefore, a relatively large amount of impurities are concentrated in the filter portion 10 disposed near the inlet of the inlet portion 20. [

The filter unit 10 should be replaced when the concentration of the impurities is higher than a certain level. At this time, the entire filter unit 10 should be replaced at a time without replacing only the filter unit 10 with a high concentration of impurities.

Since the filter unit 10 is replaced with the filter unit 10 having the highest degree of contamination disposed near the inlet of the inlet unit 20 as a reference, There is a problem in that unnecessary expense is incurred because the unit 10 needs to be replaced even when its life is short.

Korean Patent No. 10-1092058 discloses a method for controlling the flow rate of an underground heat exchanger by arranging piping of an underground heat exchanger pipe in a parallel manner and using an intermediate flow rate distribution header provided with a pressure gauge and a valve, And the flow rate control method is constituted uniformly.

However, the above-described wander control method requires a pressure gauge and a valve in each of a plurality of piping, which complicates the structure and requires a large initial installation cost and maintenance cost.

A uniform distribution structure of the filter between the filters of the water purification apparatus of Korean Patent No. 10-1282133 is a flow distribution device which provides equal pressure and quantity of water to the filter by forming a two-stage hydraulic pressure distribution structure by an outer inflow passage and an inner inflow passage .

However, in the above-described flow rate distribution device, since the flow rate distribution structure is applied only to the inflow portion that flows into the filter, there is a problem in that the efficiency of the flow rate distribution device is low.

Disclosure of the Invention The present invention has been made in order to solve the above conventional problems, and it is an object of the present invention to improve the distribution performance, the discharge performance and the water treatment performance by distributing the flow rate uniformly to the filter and maintaining the water pressure constant without installing separate valves and pressure devices. The present invention has been made in view of the above problems,

Further, according to the present invention, the inflow portion and the outflow portion are formed so as to be equal to each other, but by changing the flow path size, the water pressure and the water amount of the feed water and the treatment water are maintained at the same level while simultaneously inflowing the feed water, Another object of the present invention is to provide a water distribution apparatus of a water treatment facility capable of improving the water treatment efficiency and backwash efficiency of the filter unit.

It is another object of the present invention to provide a flow rate distribution apparatus for a water treatment facility capable of improving the flow rate distribution efficiency of a water treatment facility by forming a multi-layered multi-stage structure of the inflow section and the outflow section.

The first connection pipe is arranged to be shifted from the longitudinal direction of the distribution pipe and the second inlet pipe and the second connection pipe is arranged to be shifted from the longitudinal direction of the coupling pipe and the first outlet pipe, Another object of the present invention is to provide a flow distribution apparatus for a water treatment facility capable of improving the flow distribution efficiency.

It is another object of the present invention to provide a flow rate distribution device for a water treatment facility capable of improving the flow rate distribution efficiency of a water treatment facility by forming different diameters of the first outlet pipe and the second outlet pipe.

According to an aspect of the present invention, there is provided a flow rate distribution apparatus for a water treatment facility for distributing supply water to a plurality of filters and treating the supply water, comprising: a filter unit in which supply water is divided into a plurality of filters and subjected to filtration; An inflow portion provided upstream of the filter portion and supplied with the supply water; And an outflow part which is provided downstream of the filter part and through which the filtered treatment water flows out from the filter part. The outflow part is formed in a shape equivalent to that of the inflow part.

An inflow section of the present invention comprises: a first inflow pipe into which supply water is introduced, the first inflow pipe having a first diameter; A second inflow pipe installed parallel to the first inflow pipe, the second inflow pipe having a second bore diameter into which the feed water is introduced from the first inflow pipe; And a first duct connecting the one end of the first inflow pipe and the one end of the second inflow pipe; And a control unit.

The first ray tube of the present invention comprises: a first inlet connection tube connected to one end of the first inlet tube and bent in an a-shape; A second inflow connection pipe connected to one end of the second inflow pipe and bent in an a-shape; And a first tapered pipe connected between the first inlet connection pipe and the second inlet connection pipe; And a control unit.

The inlet portion of the present invention comprises: a first connection pipe arranged at regular intervals along the longitudinal direction of the first inflow pipe so that the supply water flows from the first inflow pipe to the second inflow pipe; And a distribution channel disposed at equal intervals along the longitudinal direction of the second inflow pipe so that the supply water flows from the second inflow pipe to the filter unit; And further comprising:

The first connection pipe of the present invention is characterized in that it is arranged to be shifted from each other in the longitudinal direction of the distribution passage and the second inflow pipe.

The outflow portion of the present invention comprises: a first outflow pipe into which process water is introduced and which has a second bore; A second outlet pipe installed in parallel with the first outlet pipe, the second outlet pipe having a first bore into which process water flows from the first outlet pipe; And a second linear pipe connecting one end of the first outlet pipe and one end of the second outlet pipe; And a control unit.

The first bore size of the present invention is characterized by being formed larger than the second bore size.

The second whirling pipe of the present invention comprises: a first outflow connection pipe connected to one end of the first outflow pipe and bent in an a-shape; A second outflow connection pipe connected to one end of the second outflow pipe and bent in an a-shape; And a second taper pipe connected between the first outlet connection pipe and the second outlet connection pipe; And a control unit.

The outflow portion of the present invention includes: a coupling flow path disposed at equal intervals along the longitudinal direction of the first outflow pipe so that the treated water flows from the filter portion to the first outflow pipe; And a second connection pipe disposed at an equal interval along the longitudinal direction of the second outflow pipe so that the process water flows from the first outflow pipe to the second outflow pipe; Further comprising:

The second connection pipe of the present invention is characterized in that the coupling flow path and the first outflow pipe are arranged to be shifted from each other in the longitudinal direction.

As described above, according to the present invention, since the inflow portion and the outflow portion are formed in a multi-step shape equivalent to each other, even if a separate valve and a pressure device are not provided, an even flow rate is distributed to the filter, Performance, and water treatment performance.

In addition, by forming the inflow portion and the outflow portion so as to be equal to each other and changing the flow path size, the supply pressure and the water pressure of the process water are maintained equally, and the supply water is pressurized and inflow, Efficiency and backwash efficiency can be improved.

Further, by forming the inflow portion and the outflow portion in a multi-layered multi-step structure, it is possible to improve the flow rate distribution efficiency of the water treatment facility.

The first connection pipe is arranged to be shifted from each other in the longitudinal direction of the distribution passage and the second inlet pipe and the second connection pipe is arranged to be shifted from the coupling flow passage in the longitudinal direction of the first outlet pipe, Of the present invention.

Further, by forming the first outlet pipe and the second outlet pipe in different diameters, it is possible to improve the flow rate distribution efficiency of the water treatment facility.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a block diagram showing a flow distribution device of a conventional water treatment facility. FIG.
BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a flow rate distribution apparatus for a water treatment facility.
3 is a plan view showing a flow distribution device of a water treatment facility according to an embodiment of the present invention.
4 is a side view showing a flow distribution device of a water treatment facility according to an embodiment of the present invention.

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

3 is a plan view showing a flow rate distribution device of a water treatment facility according to an embodiment of the present invention, and FIG. 4 is a cross-sectional view of the flow rate distribution device of a water treatment facility according to an embodiment of the present invention. FIG. 2 is a side view showing a flow distribution device of a water treatment facility according to an embodiment of the present invention. FIG.

As shown in FIGS. 2 to 4, the flow rate distribution device of the water treatment facility according to the present embodiment includes a filter unit 100, an inlet unit 200, and an outlet unit 300, The flow distributing device of the water treatment facility for distributing an equal flow rate to each filter.

The filter unit 100 is a filtering unit composed of a general porous inorganic film to which feed water is divided and filtered by a plurality of filters. Feed water containing impurities or the like is distributed to a plurality of filters and subjected to filtration.

The inlet unit 200 is a multi-stage multi-stage pipe that supplies the feed water containing impurities and the like to the filter unit 100 at a uniform water pressure so that the feed water can be filtered. The inlet pipe 200 includes a first inlet pipe 210, 2 inlet pipe 220, a first pipe 230, a first connection pipe 240, and a distribution channel 250.

The first inlet pipe 210 is a pipe for supplying the feed water and has an inlet 211 formed at one side thereof and a hollow pipe shape having a first bore size d1.

The second inlet pipe 220 is formed as a hollow pipe shape having a second bore size d2 for supplying the feed water flowing from the first inlet pipe 210 to the filter unit 100, And is installed parallel to the first inflow pipe 210.

In this case, the second bore size d2 may be formed to be smaller than or larger than the first bore size d1, and may be formed in different sizes.

The first linear pipe 230 is connected to the other end of the first inlet pipe 210 and the one end of the second inlet pipe 220 so that the supply water flows from the first inlet pipe 210 to the second inlet pipe 220, And includes a first inlet connection pipe 231, a second inlet connection pipe 232, and a first taper pipe 233.

The first inlet pipe 231 is a connecting member for connecting the first inlet pipe 210 to the second inlet pipe 220. The first inlet pipe 231 is provided at the other end of the first inlet pipe 210, And the other end is bent so as to be pivoted toward the second inflow pipe 220 in an " a " shape.

The second inflow connection pipe 232 is a connecting member for connecting the second inflow pipe 220 to the first inflow pipe 210. The second inflow pipe 232 is provided at one end of the second inflow pipe 220, And the other end is bent so as to be pivoted toward the first inflow pipe 210 in an " a " shape.

The first taper pipe 233 is a connecting member for connecting the first inflow connection pipe 231 and the second inflow connection pipe 232 which are formed in different bore sizes and the first inflow connection pipe 231, The first inlet connection pipe 231 and the second inlet connection pipe 232 are formed in a tapered shape having a reduced diameter in a section from one end connected to the second inlet connection pipe 232 to the other end connected to the second inlet connection pipe 232, Is installed.

The first connection pipe 240 is a connection pipe connected with the first pipe 230 so that the supply water flows from the first inflow pipe 210 to the second inflow pipe 220. The first inflow pipe 210 And the second inflow pipe 220 along the longitudinal direction of the first inflow pipe 210 at equal intervals.

At this time, it is preferable that the diameter of the first connection pipe 240 is smaller than the diameter of the first pipe 230.

The distribution channel 250 is a connection channel through which the supply water flows from the second inlet pipe 220 to the filter unit 100 and between the second inlet pipe 220 and the filter unit 100, Are arranged at regular intervals along the longitudinal direction of the body 220.

The outflow portion 300 is a multi-layered multi-step pipe for discharging the treated water filtered in the filter portion 100. The outflow portion 300 includes a first outflow pipe 310, a second outflow pipe 320, a second outboard pipe 330, A second connection pipe 340, and a coupling passage 350.

The first outflow pipe 310 is formed as a hollow pipe shape having a second bore size d2 as a pipe for discharging treated water.

The second outflow pipe 320 is a pipe for discharging the treated water flowing in from the first outflow pipe 310. The outflow pipe 321 is formed at one side of the pipe and the hollow pipe having the first bore size d1 And is installed in parallel with the first outflow pipe 310. The first outflow pipe 310 is formed in a pipe shape.

The outflow port 321 may be connected to the outflow port 30 and the inflow port 20 in such a manner that the outflow port 321 of the filter unit 100 is supplied with backwash water to backwash the filter unit 100, Are formed correspondingly in multiple stages of the variable flow path, it is of course possible to improve the backwash efficiency by improving the backwash water pressure while maintaining the backwash flow rate constant.

In this case, the second bore size d2 may be formed to be smaller than or larger than the first bore size d1, and may be formed in different sizes.

The second line pipe 330 is connected to one end of the first outlet pipe 310 and the other end of the second outlet pipe 320 so that the process water flows from the first outlet pipe 310 to the second outlet pipe 320, A second outflow connection pipe 332, and a second taper pipe 333. The first outflow connection pipe 331, the second outflow connection pipe 332, and the second taper pipe 333 are connected to each other.

The first outflow connection pipe 331 is a connecting member for connecting the first outflow pipe 310 to the second outflow pipe 320. The first outflow connection pipe 331 is provided at one end of the first outflow pipe 310, And the other end is bent so as to pivot toward the second outflow pipe 320 in a " A " shape.

The second outflow connection pipe 332 is a connecting member for connecting the second outflow pipe 320 to the first outflow pipe 310 and has one end provided at the other end of the second outflow pipe 320, And the other end is bent and bent so as to be bent in the " a " shape toward the first outlet pipe 310.

The second taper pipe 333 is a connecting member for connecting the first outflow connection pipe 331 and the second outflow connection pipe 332 which are formed in different bore sizes and is connected to the first outflow connection pipe 331 The first outlet connection pipe 331 and the second outlet connection pipe 332 are formed in a tapered shape so as to extend the bore size from the first end connected to the second outlet connection pipe 332 to the other end, .

The second connection pipe 340 is a connection pipe connected with the second pipe 230 to allow the process water to flow from the first outlet pipe 310 to the second outlet pipe 320, And the second outflow pipe 320 along the longitudinal direction of the first outflow pipe 310 at regular intervals.

At this time, it is preferable that the diameter of the second connection pipe 340 is smaller than the diameter of the second linear pipe 330.

The coupling channel 350 is a connection channel connected to the process unit 100 so as to flow from the filter unit 100 to the first outlet pipe 310. The coupling pipe 350 is connected to the first outlet pipe 310 between the filter unit 100 and the first outlet pipe 310, Are arranged at regular intervals along the longitudinal direction of the base 310.

As described above, according to the present invention, since the inflow portion and the outflow portion are formed in a multi-step shape equal to each other, the flow rate is distributed evenly to the filter without providing a separate valve and pressure device, Performance, and water treatment performance.

In addition, by forming the inflow portion and the outflow portion so as to be equal to each other and changing the flow path size, the supply pressure and the water pressure of the process water are maintained equally, and the supply water is pressurized and inflow, Efficiency and backwash efficiency can be improved.

Further, by forming the inflow portion and the outflow portion in a multi-layered multi-step structure, it is possible to improve the flow rate distribution efficiency of the water treatment facility.

The first connection pipe is arranged to be shifted from each other in the longitudinal direction of the distribution passage and the second inlet pipe and the second connection pipe is arranged to be shifted from the coupling flow passage in the longitudinal direction of the first outlet pipe, Of the present invention.

Further, by forming the first outlet pipe and the second outlet pipe in different diameters, it is possible to improve the flow rate distribution efficiency of the water treatment facility.

The present invention may be embodied in other specific forms without departing from the spirit or essential characteristics thereof. Therefore, the above embodiments are merely illustrative in all respects and should not be construed as limiting.

100:
200: inlet
210: first inlet pipe
211: inlet
220: second inlet pipe
230: first ray tube
231: first inlet connector
232: second inlet connector
233: first taper pipe
240: first connector
250: Distribution Euro
300:
310: first outflow pipe
320: Second outflow pipe
321: Outlet
330: 2nd line hall
331: first outflow connector
332: second outlet connector
333: second taper pipe
340: second connector
350: Coupling flow

Claims (10)

A flow distributing device for a water treatment facility for distributing supply water to a plurality of filters and treating supply water,
A filter portion in which supply water is divided and filtered through a plurality of filters;
An inflow portion provided upstream of the filter portion and distributing the supply water to the filter portion; And
And an outlet disposed downstream of the filter unit, the outlet being connected to the filter unit through the filter unit,
Wherein the inflow portion and the outflow portion are formed in a multi-stage shape equivalent to each other,
Wherein the inflow portion includes a first inflow pipe into which supply water is introduced through an inflow port formed at one side and formed into a first bore size; A second inflow pipe installed parallel to the first inflow pipe, the second inflow pipe being supplied with water from the first inflow pipe and formed in a second bore size; And a first duct connecting the other end of the first inflow pipe and the first end of the second inflow pipe,
The first linear pipe includes a first inlet connection pipe connected to one end of the first inlet pipe and bent to pivot; A second inlet connection pipe connected to one end of the second inlet pipe and bent to pivot; And a first taper pipe connected between the first inlet connection pipe and the second inlet connection pipe, the first taper pipe being formed to reduce a caliber size,
Wherein the outlet comprises: a first outlet pipe through which treated water flows out and is formed in a second bore size; A second outflow pipe installed parallel to the first outflow pipe, the second outflow pipe being formed with a first bore size into which process water flows from the first outflow pipe; And a second linear pipe connecting one end of the first outlet pipe and one end of the second outlet pipe,
The second linear pipe includes a first outlet connection pipe connected to one end of the first outlet pipe and bent to pivot; A second outflow connection pipe connected to one end of the second outflow pipe and bent to pivot; And a second taper pipe connected between the first outflow connection pipe and the second outflow connection pipe and configured to expand the bore size. delete delete The method according to claim 1,
Wherein:
A first connection pipe arranged at regular intervals along the longitudinal direction of the first inflow pipe so that the supply water flows from the first inflow pipe to the second inflow pipe; And
A distribution channel disposed at equal intervals along the longitudinal direction of the second inflow pipe so that the supply water flows from the second inflow pipe to the filter unit; Further comprising: a flow rate control unit for controlling the flow rate of the water. 5. The method of claim 4,
Wherein the distribution channels are disposed to be shifted from each other in the longitudinal direction of the first connection pipe and the second inlet pipe. delete The method according to claim 1,
Wherein the second bore size is smaller than the first bore size. delete The method according to claim 1,
The outlet
A coupling flow path disposed at equal intervals along the longitudinal direction of the first outflow pipe so that the process water flows from the filter unit to the first outflow pipe; And
A second connection pipe arranged at regular intervals along the longitudinal direction of the second outflow pipe so that the process water flows from the first outflow pipe to the second outflow pipe; Further comprising: a flow rate control unit for controlling the flow rate of the water. 10. The method of claim 9,
And the second connection pipe is arranged to be shifted in the longitudinal direction of the coupling flow path and the first outflow pipe.

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