KR101773968B1 - Method for water treatment using pressure of raw water - Google Patents

Abstract

The present invention provides a water treatment method. The method includes: a step (a) of measuring pressure (P) of raw water through a pressure sensor (Sp) located in an emission line of an intake tower (100); a step (b) of measuring a production flux (Q) of treatment water through a flux sensor (S_Q) located in an emission line of a membrane filter part (600); a step (c) of determining whether the pressure (P) of the raw water is included in a first pressure section; and a step (d1) of determining whether the production flux (Q) is included in a first flux section if the pressure (P) of the raw water is determined to be included in the first pressure section. During the step (d1), if the production flux (Q) is determined to be included in the first flux section, the intake tower (100) closes a first valve (V1) located in a divergent line to a raw water tank (200), and the intake tower (100) at least partially opens a second valve (V2) located in a divergent line to a disc filter part (400).

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a water treatment method using raw water inflow pressure,

The present invention relates to a water treatment method, and more particularly, to a water treatment method capable of efficiently operating a water treatment system to reduce power consumption.

The water treatment method is a method of treating raw water through various internal facilities so that raw water (untreated water) such as surface water, ground water, sewage water, heavy water, constant water, wastewater and sewage can be used.

In the water treatment method, a pump is used to supply raw water to the inside of the water treatment system or to transfer the water to the facilities of the water treatment system itself. The pump used in the water treatment system is a constant pump Capacity.

As a result, much power is consumed, the life is reduced, and the maintenance cost is increased.

Korean Patent Registration No. 1169027 discloses an apparatus and a method for highly concentrated membrane filtration and movement using circulation pressure and dual pump. The circulation pressure and the dual pump capable of producing membrane- The present invention provides a highly concentrated membrane filtration and purification apparatus and method.

However, since the membrane filtration water is produced by non-dynamic force using the water level of the raw water tank, additional power for lifting and lowering the raw water tank is consumed.

KR 1169027 B1 KR 2009-0128298 A JP 5398046 B2

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems.

The present invention provides an economical water treatment method capable of solving the problem of excessive maintenance cost due to the continuous operation of power facilities such as a pump.

According to an aspect of the present invention, there is provided a method of measuring a pressure P of raw water introduced from a pressure sensor Sp located on a discharge line of a water intake tower 100; (b) measuring the production flow rate Q of the treated water at the flow sensor S _Q located at the discharge line of the membrane filtration unit 600; (c) determining whether the pressure P of the introduced raw water is included in the predetermined first pressure section; And (d1) determining whether the production flow rate Q is included in the predetermined first flow rate interval when it is determined that the pressure P of the introduced raw water is included in the first pressure interval, the first valve V1 located on the line branching from the water intake tower 100 to the water tank 200 is operated when the production flow rate Q is determined to be included in the first flow rate section in step (d1) And the inflow pressure of the raw water in which at least a part of the second valve V2 located in the line branched from the water intake tower 100 to the disk filter unit 400 is opened is provided.

If it is determined that the production flow rate Q that is the measurement result of step (b) is not included in the first flow rate section after the step (c) Wherein the first valve (V1) is closed when the production flow rate (Q) is included in the second flow rate section in step (d2), and the second valve It is preferable that the predetermined backwash mode is performed when the flow rate Q of the introduced raw water is not included in the second flow rate section.

The method may further include, after the step (c): (e) determining whether the pressure P of the raw water is included in the first pressure interval, if the pressure P is included in the predetermined second pressure interval; And (f) determining whether the production flow rate (Q) is included in the first flow rate section when the pressure P of the introduced raw water is included in the second pressure section in the step (e) The first valve (V1) is closed and the second valve (V2) is opened when the production flow rate (Q) is included in the first flow rate section in the step (f) It is preferable that the backwash mode is performed when the second pump P2 located in the inflow line of the first flow rate control unit 600 is operated and the production flow rate Q is not included in the first flow rate zone.

If the pressure P of the introduced raw water is not included in the second pressure interval, the flow rate Q of the introduced raw water is included in the first flow rate section Wherein the first valve (V1) is opened when the flow rate (Q) of the raw water flowed in the first flow rate section is included in the step (g), and the second valve V2 are closed and the first pump P1 and the second pump P2 located in the line discharged from the source water tank 200 to the disk filter unit 400 are opened and the flow rate of the introduced raw water (Q) is not included in the first flow rate section, the backwash mode is preferably performed.

In the backwash mode, after the first valve (V1) and the second valve (V2) are closed, the disc filter unit (400) is backwashed or the filtration membrane of the membrane filtration unit (600) It is preferably a mode in which it is maintained and washed with sodium chlorate (NaOCl) or citric acid (C ₆ H ₈ O ₇ ).

In addition, a manganese column 500 is located at the rear end of the disk filter unit 400 and a pretreatment tank 300 is located at the rear end of the manganese column 500, (600).

In addition, the first pressure section is preferably in a range of 3.2 bar or more, and the first flow section may be 24 m ³ / hr or more, but the standard of the value may be changed according to design conditions.

Also, the second flow rate section is preferably a section having a flow rate of 14 m ³ / hr or more and less than 24 m ³ / hr, but the reference value of the value can be changed according to design conditions.

In addition, the second pressure interval is preferably a range of 2 bar to less than 3.2 bar, but the standard of the value can be changed according to design conditions.

By using the water treatment method according to the present invention, the power consumption can be reduced by 90% or more compared to the conventional water treatment system.

In addition, since the water treatment method according to the present invention is a method of operating in consideration of inflow pressure of raw water and production flow rate, the water treatment system can be operated stably regardless of all seasons.

In addition, the water treatment method according to the present invention reduces the power consumption, and thus the maintenance cost of the water treatment system is reduced, which is economical.

1 is a schematic diagram of a system for implementing a water treatment method according to the present invention.
2 is a flowchart of a water treatment method according to the present invention.
FIG. 3 is a table showing conditions together to illustrate the water treatment method according to the present invention.

In the present invention, the 'water intake tower (100)' is a facility for supplying raw water to a water treatment system, and may include any water supply source such as a dam.

In the present invention, 'raw water' is not limited as long as it is an object to be water-treated, but it may be any water which can be supplied from surface water, groundwater, sewage, heavy water, water, wastewater, sewage and water.

In the present invention, the 'pretreatment water' means that the introduced raw water is treated by the disk filter unit 400 or inter-mangled tower 500.

In the present invention, 'pretreatment water' means treated by the pretreatment tank 300.

In the present invention, 'treated water' means that the membrane filtration unit 600 has been finally treated, and is equal to the number of products produced.

Hereinafter, a water treatment method according to the present invention will be described in detail with reference to the drawings. Here, the constituent elements of the present invention can be used integrally or separately from each other as needed. In addition, some components may be omitted depending on the usage form. Various modifications can be made in the form and the number of elements of the present invention.

Water treatment  system

A system for implementing the water treatment method according to the present invention will be described with reference to FIG.

The water treatment system according to the present invention includes a pressure sensor S _P , a flow sensor S _Q , a water intake tower 100, a raw water tank 200, a pre-treatment tank 300, a disk filter unit 400, A membrane filtration unit 600 and a process water tank 700. The first valve V1 and the second valve V2 are connected to the first pump P1 and the second pump P2.

The pressure sensor ( _SP ) is installed in a discharge line of the water intake tower (100) for introducing the raw water, and measures a pressure (P) of the raw water to be introduced.

The flow sensor S _Q is installed on a discharge line of the membrane filtration unit 600 to be described later to measure the flow rate of the treated water processed in the membrane filtration unit 600, that is, the production flow rate Q.

The water treatment method differs depending on the pressure and the flow rate measured in the pressure sensor (S _P ) and the flow sensor (S _Q ).

The raw water tank 200 stores raw water supplied from the water intake tower 100.

The first valve (V1) is located on the raw water line which branches from the water intake tower (100) to the water tank (200).

The first valve V1 regulates the flow rate of the raw water supplied to the raw water tank 200 and is opened or closed according to an operation method determined according to the inflow pressure P of the raw water and the production flow rate Q.

The pretreatment tank 300 is a facility into which the pre-treated water treated in the disk filter unit 400 or inter-mangled tower 500 to be described later flows.

The pretreatment tank 300 stores pretreated water that has passed through the disk filter unit 400 or the inter-mangled tower 500 and supplies reverse osmosis water for cleaning the disk filter unit 400 or the inter-mangled tower 500 It is possible.

The raw water supplied from the water intake tower 100 or the raw water tank 200 flows into the disk filter unit 400.

The first pump P1 is a pump for supplying the raw water of the raw water tank 200 to the disk filter unit 400 and is located on a line connected from the raw water tank 200 to the disk filter unit 400. [

The operation of the first pump P1 is determined according to the operation method determined according to the inflow pressure and the flow rate of the raw water.

The second valve V2 controls the flow rate of the raw water supplied from the water intake tower 100. The second valve V2 is located in a line branched from the water intake tower 100 to the disk filter unit 400, The opening and closing is controlled according to the determined operating method.

In addition, a manganese column 500 is located at the rear end of the disk filter unit 400.

In the manganese tower 500, the raw water supplied from the water intake tower 100 or the raw water tank 200 flows in, and the pretreatment tank 300 is located in the downstream.

In the present invention, the disk filter unit 400 and the inter-mangled tower 500 are shown together, but the inter-mangled tower 500 may replace or be used together with the disk filter unit 400 according to the needs of the designer .

The membrane filtration unit 600 is connected to the pretreatment tank 300 to filter the residual substances, viruses and pathogenic microorganisms in the pretreatment water introduced from the pretreatment tank 300 to produce treated water.

The second pump P2 is located in the raw water line flowing into the membrane filtration unit 600.

The second pump P2 is a pump for supplying the pre-treatment water of the pretreatment tank 300 to the membrane filtration unit 600. The second pump P2 operates according to the operation method determined according to the inflow pressure P of the raw water and the production flow rate Q. Is determined.

The treatment water tank 700 is a facility where treated water produced by the water treatment system is stored, and the treated water that has passed through the membrane filtration unit 600 is stored.

Water treatment  Way

The water treatment method according to the present invention will be described with reference to FIG. 2 and FIG.

A preferred example of the predetermined pressure and flow interval used in the water treatment method according to the present invention is as follows, and the predetermined interval can be reset by the designer.

In the present invention, the 'first pressure interval' may be 3.2 bar or more.

In the present invention, the 'second pressure interval' may be at least 2 bar and less than 3.2 bar.

In the present invention, the 'first flow rate range' may be 24 m ³ / hr or more.

In the present invention, the second flow rate range, may be less than 14m ³ / hr at least 24m ³ / hr.

(A) the pressure P of the raw water introduced from the pressure sensor Sp of the line discharged from the water intake tower 100 is measured, (b) the flow sensor S of the line discharged from the membrane filtration unit 600 _Q ), the production flow rate Q of the treated water is measured.

Next, (c) it is determined whether the pressure P of the introduced raw water is included in the first pressure section, and if the pressure P of the introduced raw water is included in the first pressure section, the process proceeds to (d1) , The process proceeds to step (d2).

Next, in step (d1), it is determined whether the production flow rate Q is included in the first flow rate section when the pressure P of the introduced raw water is included in the first pressure section, The first valve V1 located on the line branching from the water intake tower 100 to the water tank 200 is closed and the water from the water intake tower 100 to the disk filter unit 400 At least a part of the second valve (V2) located in the branching line is opened.

In the embodiment, when the pressure P of raw water and the production flow Q are 3.2 bar or more and 24 m ³ / hr or more, respectively, the introduced raw water passes through the water intake tower 100, the disk filter unit 400, Processed through the column 500 and the membrane filtration unit 600, and then stored in the treatment water tank 700.

That is, as a method of performing water treatment only by the pressure of raw water to be introduced, no additional power is required.

Next, if it is determined that the production flow rate Q is not included in the first flow rate section, it is determined whether or not the production flow rate Q is included in the second flow rate section.

In the step (d2), when the production flow rate Q is included in the second flow rate section, the first valve V1 is closed and the second valve V2 is fully opened (100% open).

That is, when it is judged that the pressure P of the raw water is 3.2 bar or more and the production flow Q is 14-24 m ³ / hr, the second valve V 2 is fully opened.

The raw water introduced by the increased flow rate and pressure is processed through the water intake tower 100, the disk filter unit 400 and the membrane filtration unit 600, and then stored in the treatment water tank 700 do.

In the step (d2), when the production flow rate Q is not included in the second flow rate section, the backwash mode is performed.

That is, if the pressure P of the introduced raw water is 3.2 bar or more and the production flow rate Q is less than 14 m ³ / hr, the backwash mode is performed.

Described below are two cases in which the production flow rate Q does not reach a certain flow rate while maintaining a high pressure of the inflow source water. Or a case where the flow rate decreases due to membrane contamination of the membrane filtration unit 600. [

The solution in the case of the first cause is to backwash the disk filter unit 400 and the manganese column 500 using reverse water and the solution in the case of the second cause is to maintain the membrane filtration unit 600 Washing and restoration washing is carried out to recover membrane permeability.

Therefore, the backwash mode is a mode in which the disc filter portion 400 or inter-mangled bed 500 is backwashed after the first valve V1 and the second valve V2 are closed, It is a mode of holding and washing with sodium chlorate (NaOCl) or citric acid (C ₆ H ₈ O ₇ ).

Next, (e) if it is determined that the pressure P of the introduced raw water is not included in the first pressure section, it is determined whether it is included in the second pressure section.

That is, it is determined whether the pressure P of the raw water is less than 2 bar.

Next, (f) when the pressure P of the raw water is included in the second pressure section, it is determined whether the production flow rate Q is included in the first flow rate section.

In the step (f), when the production flow rate Q is included in the first flow rate section, the first valve V1 is closed, the second valve V2 is opened, and the inlet line of the membrane filtration section 600 The second pump P2 is activated.

The first valve V1 is closed and the second valve V2 is closed when the pressure P of the introduced raw water is not less than 2 bar and less than 3.2 bar and the production flow Q is not less than 24 m ³ / And the second pump P2 is operated.

In the step (f), when the production flow rate Q is not included in the first flow rate section, the backwash mode is performed.

That is, when it is judged that the pressure P of the introduced raw water is not less than 2 bar and less than 3.2 bar and the production flow rate Q is less than 24 m ³ / hr, the backwash mode is performed.

(g) If the pressure P of the introduced raw water is not included in the second pressure section, it is determined whether or not the production flow rate Q is included in the first flow rate section.

In the step (g), when the production flow rate Q is included in the first flow rate section, the first valve V1 is opened, the second valve V2 is closed, and the first pump P1 and the second pump V2 are closed. (P2) is opened.

That is, when it is judged that the raw water P has a pressure P of less than 2 bar and the production flow Q is more than 24 m ³ / hr, the first valve V 1 is opened and the second valve V 2 is closed The first pump P1 and the second pump P2 are operated.

Next, in step (g), if the production flow rate Q is not included in the first flow rate section, the backwash mode is performed.

That is, if it is determined that the pressure P of the introduced raw water is less than 2 bar and the production flow rate Q is less than 24 m ³ / hr, the backwash mode is performed.

3, an experiment in which the water treatment method according to the present invention is performed will be described.

As a result of water treatment using the inflow pressure of the raw water according to the present invention, the power consumption was 0.011 kWh / m ^{3 when} the inflow pressure P was 3.2 bar or more. This is because the pump did not operate at all.

As a result of water treatment using the inflow pressure of the raw water according to the present invention, the power consumption was 0.283 kWh / m ^{3 when} the inflow pressure of the raw water was 2 bar or more and less than 3.2 bar.

As a result of water treatment using the inflow pressure of the raw water according to the present invention, the power consumption was 0.357 kWh / m ³ when the pressure of the raw water was less than 2 bar.

That is, it is confirmed that the water treatment method using the inflow pressure of the raw water according to the present invention can save the power consumption of 0.272 to 0.346 kWh / m ^{3 in} the water treatment, compared with the conventional water treatment method .

While the present invention has been described with reference to exemplary embodiments thereof, it will be understood by those of ordinary skill in the art that various changes in form and details may be made therein without departing from the spirit and scope of the present invention as defined by the following claims. It will be appreciated that embodiments are possible. Accordingly, the scope of protection of the present invention should be determined by the claims.

100: water tower
200: Circulating water tank
300: Pretreatment tank
400: disk filter unit
500: manganese tower
600: membrane filtration section
700: Treatment tank
V1: first valve
V2: second valve
P1: first pump
P2: Second pump
S _P : Pressure sensor
S _Q : Flow sensor

Claims (6)

(a) measuring a pressure P of raw water introduced from a pressure sensor Sp located in a discharge line of the water intake tower 100;
(b) measuring the production flow rate Q of the treated water at the flow sensor S _Q located at the discharge line of the membrane filtration unit 600;
(c) determining whether the pressure P of the introduced raw water is included in the predetermined first pressure section;
(d1) determining whether the production flow rate (Q) is included in the predetermined first flow rate interval when it is determined that the pressure P of the introduced raw water is included in the first pressure interval; And
(d2) determining whether the production flow rate Q as a result of the measurement in the step (b) is included in the predetermined second flow rate interval when it is determined that the production flow rate Q is not included in the first flow rate interval (S320) and,
If it is determined in step (d1) that the production flow rate Q is included in the first flow rate section, the first valve (V1) located on the line that branches from the water intake tower (100) At least a part of the second valve V2 located in the line branching from the water intake tower 100 to the disk filter part 400 is opened,
If the production flow rate Q is included in the second flow rate period in the step d2, the first valve V1 is closed, the second valve V2 is fully opened, and the flow rate of the introduced raw water Q (Q) is not included in the second flow rate section, a predetermined backwash mode is performed,
(e) determining whether the pressure P of the introduced raw water is included in the predetermined second pressure interval when it is determined that the pressure P is not included in the first pressure interval;
(f) determining whether the production flow rate Q is included in the first flow rate section when the pressure P of the introduced raw water is included in the second pressure section in the step (e); And
(g) determining whether the flow rate Q of the introduced raw water is included in the first flow rate section when the pressure P of the introduced raw water is not included in the second pressure section,
In the step (f), when the production flow rate Q is included in the first flow rate section, the first valve V1 is closed, the second valve V2 is opened, the membrane filtration section 600 The second pump P2 is operated, and when the production flow rate Q is not included in the first flow rate section, the backwash mode is performed,
In the step (g), when the flow rate Q of the introduced raw water is included in the first flow rate section, the first valve V1 is opened, the second valve V2 is closed, The first pump P 1 and the second pump P 2 located in the line discharged from the main body 200 to the disk filter unit 400 are opened and the flow rate Q of the raw water flowing into the first flow rate section The backwash mode is performed,
Water treatment method.
delete delete delete The method according to claim 1,
In the backwash mode,
After the first valve (V1) and the second valve (V2) are closed,
If the disk filter unit 400 is backwashed,
Which is a mode in which the filtration membrane of the membrane filtration unit 600 is maintained with sodium hypochlorite (NaOCl) or citric acid (C ₆ H ₈ O ₇ )
Water treatment method.
The method according to claim 1,
The manganese column 500 is located at the rear end of the disk filter unit 400,
The pretreatment vessel 300 is disposed at the rear end of the manganese column 500,
The pretreatment tank 300 is connected to the membrane filtration unit 600,
Water treatment method.

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