KR102453719B1 - How to operate a water treatment device - Google Patents

Abstract

In the method of operating a water treatment apparatus having a plurality of water treatment units of the same type and having the same treatment capacity installed in parallel, the method of operating a water treatment apparatus for collecting treated water by passing the same target water through each water treatment machine, When the water flow to A is made a higher load than other water treatment machines B, and the deterioration of the water quality of the treated water of the water treatment machine A occurs, the life of the water treatment machine B is predicted from the accumulated load to the water treatment machine A up to that point, and this prediction Based on the result, the operation method of the water treatment apparatus characterized by controlling the water passage amount and the water passage time for each subsequent water treatment machine.

Description

How to operate a water treatment device

The present invention relates to a method of operating a water treatment device in which a plurality of water treatment devices such as an ion exchange resin tower and an activated carbon tower are installed in parallel.

General industrial pure water such as boiler water, high-grade pure water used in power plants, and ultrapure water used as washing/rinsing water for wafers and substrates in semiconductor factories and liquid crystal factories, etc. It is manufactured by the water treatment system which uses combining two or more water treatment machines. As a water treatment machine, an ion exchange resin tower, an activated carbon tower, an RO membrane device, a UF membrane device, an ion exchange filter, etc. are widely used.

Methods of using these water treatment machines include, in addition to the method of repeatedly using the impurity removal process and the regeneration process, the daily use method of renewing a new product at the stage of use up to a certain level. In either case, it is preferable to maintain the impurity removal process (water-flowing process) for a long time while maintaining the desired quality of treatment water.

In many cases, it is difficult for a water treatment machine to rapidly shift to regeneration or renewal to a new product, even when a tendency for deterioration of treated water quality is confirmed. For this reason, in reality, playback/update is carried out on a regular basis for every fixed period or for every fixed amount of processing.

However, since the quality of the water to be treated cannot be limited to be constant throughout the year, when regeneration/renewal is carried out every certain period or at a certain amount of treatment, the water quality of the untreated water is severe (the impurity concentration to be removed is high). ) condition is set on the premise, and as a result, in many cases, playback/update occurs when there is a certain amount of leeway. In addition, there is a risk that the desired water quality may not be obtained if this is not done.

In Patent Document 1, a small ion exchange resin filled column is installed in parallel with the actual ion exchange resin device, and the same raw water (treated water) is passed through this small ion exchange resin filled column, and the quality of the treated water is monitored. , a method for estimating the remaining life of an ion exchange resin device is described.

Japanese Patent Laid-Open No. 2012-154634

In life prediction using a small ion-exchange resin-filled container, it is common to bring the SV, LV, etc. as close to the actual machine as possible, and to pass water under slightly strict conditions, but it is difficult to accurately reflect the load situation on the actual machine. , it was necessary to handle it considering a certain amount of surplus even here.

An object of the present invention is to provide a method of operating a water treatment device that operates to fully use the water treatment capacity of the water treatment machine.

The gist of the present invention is as follows.

[1] A method of operating a water treatment apparatus having a plurality of water treatment units of the same type and having the same treatment capacity installed in parallel, and a method of operating a water treatment apparatus in which the same water to be treated is passed through each water treatment unit to collect the treated water In this, when the water passing through some water treatment machines A is made a higher load than other water treatment machines B, and deterioration of the water quality of the treated water of the water treatment machine A occurs, from the accumulated load to the water treatment machine A up to that point, the The operation method of the water treatment apparatus characterized by predicting a lifespan, and controlling the water passage amount and water passage time for each subsequent water treatment machine based on this prediction result.

[2] The method of operating a water treatment device according to [1], wherein the water passing speed to the water treatment machine A is set to 1.05 to 1.3 times the water passing speed of the water treatment machine B until the deterioration of the water quality of the water treatment machine occurs. .

[3] In [1] or [2], the accumulated load on the water treatment machine A up to the time when the quality of the treated water of the water treatment machine A deteriorated to a predetermined value is set as the life load, and the water treatment machine up to the time point Find the difference between the integrated load on B and its lifetime load (hereinafter referred to as the load difference), and make the load applied to the water treatment machine B from that point until the end of water collection the load difference, so that the water treatment machine B after that point A method of operating a water treatment device, characterized in that setting the water passing speed and water passing time for

[4] The unit according to any one of [1] to [3], wherein the water flow to the water treatment machine A is stopped after the time point, and the required amount of treatment per unit time in the whole water treatment apparatus is divided by the number of water treatment machines B Let the water flow rate per hour be the water flow rate for each water treatment machine B,

A method of operating a water treatment apparatus, wherein the water passing time is set such that a load obtained from the product of the water passing speed and the water passing time from the time point to the end of water collection is the load difference.

[5] The water treatment according to any one of [1] to [4], wherein the water treatment machine has a container and an ion exchange resin, activated carbon, ion exchange filter, chelate resin or catalyst filled in the container. How to drive the device.

In the present invention, a part (one or a small number) of water treatment machines A is used as a pilot for detecting a decrease in treated water quality, and a slightly higher load than the other water treatment machines B (for example, high water speed) is passed, and this pilot The life of the water treatment machine is predicted from the sign of deterioration of the water quality of the treated water of the dragon water treatment machine. Then, the subsequent water passage conditions are set so that each water treatment device is exhausted until just before its lifespan.

Accordingly, each water treatment unit can be exhausted until just before its lifespan while maintaining desired water quality without additionally installing a special measuring device, control device, etc. for a conventional water treatment system. Even if a sign of deterioration of water quality is detected in some water treatment units with high load, the life of the entire water treatment unit is not reached immediately, so the response after preparing for regeneration and renewal of the water treatment unit can be carried out without unreasonableness.

1 is a block diagram of a water treatment device to which the method of the present invention is applied.

EMBODIMENT OF THE INVENTION Hereinafter, with reference to FIG. 1, embodiment is described. In the description of this embodiment, the water treatment unit is an ion exchange resin column, but an activated carbon column, a chelate resin column, a catalyst column, an ion exchange filter, an MF membrane device, a UF membrane device, an RO membrane device, or the like may be used. Preferably, an ion exchange resin tower, an ion exchange filter, a chelate resin tower, an activated carbon tower, a catalyst tower, etc. are mentioned with a clear lifetime. Moreover, for the production of ultrapure water, in addition to the water treatment for removing impurities in water, it can be applied to removal of impurities in the liquid other than the production of pure water.

As shown in Fig. 1, a plurality of ion exchange resin towers 3 are installed in parallel. Each ion exchange resin column 3 has a container of the same shape and the same volume, and the same type of ion exchange resin filled in the same amount in the container. In each of the ion exchange resin towers 3 , the to-be-treated water can pass through the pipe 1 and the valve 2 , and the treated water can flow out through the valve 4 and the pipe 5 . While the amount of water passing through each ion exchange resin column 3 is measured with a flow meter (not shown), the water quality of the treated water in each ion exchange resin column 3 is measured with a water quality meter 6 . Although a conductivity meter, a turbidity meter, a residual chlorine concentration meter, a pH meter, a resistivity meter etc. can be used as a water quality meter, it is not limited to these. A water quality meter suitable for the type of water treatment machine is appropriately selected.

A part of the plurality of ion exchange resin towers 3 (the leftmost tower in Fig. 1) A is used as the pilot tower A, and the other tower B is passed through slightly more harshly (in this case, a high flow rate condition). . And the water quality of the treated water of the ion exchange resin tower A is monitored continuously or intermittently, and the sign of deterioration is grasped|ascertained from a stable state. In addition, the water flow SV to the tower A during this period is preferably about 1.05 to 1.3 times the water flow SV to the tower B.

Since the water flow SV with respect to tower A is larger than tower B, tower A breaks through earlier than tower B (processed water quality deteriorates).

After grasping the signs of deterioration of the water quality of the treated water in the tower A prior to the deterioration of the water quality of the treated water in the tower B, in order to fully utilize the capabilities of the entire towers A and B (that is, just before their lifetime), the tower The residual life of B is predicted, and the flow rate is adjusted so that the treated water of good quality may be obtained as much as possible until the completion of water collection. That is, the flow rate of water passing through the tower A is reduced or the water flow is stopped, and the reduced amount (or stoppage amount) of the water flow through this tower A is added to the water flow rate for the other tower B. Although the water flow rate to each tower B may be equal, the additional amount of the flow rate of some towers (tower C) in tower B is slightly higher than that of others, and signs of deterioration of the treated water quality in tower C are monitored, and the remaining tower B may be predicted (symbol C is not shown).

According to the above method, it is possible to pass water through all ion exchange resin towers until just before their lifetime, while maintaining the desired quality of treated water without additionally installing a special measuring device or control device for a conventional water treatment system. Even when a sign of deterioration of water quality is detected in Tower A (or Tower C), the life of the entire water treatment apparatus is not reached immediately, so regeneration and renewal of the water treatment apparatus can be carried out without unreasonableness after preparation.

In Fig. 1, one ion exchange resin tower is used as the pilot tower A, but in a system in which a plurality of towers are installed in parallel, in order to increase the accuracy of the residual life prediction, the pilot water is passed under rather severe conditions. A plurality of towers A may be formed to make a difference in severity (degree of high flow rate) with respect to standard conditions.

Example

An example of the present invention will be described in more detail.

In general, the life of a functional material for water treatment such as an ion exchange resin is approximately determined by the product of the load amount, that is, the concentration of impurities in the to-be-treated water to be removed, and the integrated water flow rate, as long as water flow conditions such as flow rate (SV, etc.) are in an appropriate range.

As shown in FIG. 1 , in a water treatment device in which 10 ion exchange resin towers are installed in parallel, at the beginning of the water flow start, one tower A is passed through at a high flow rate 10% higher than that of the standard, and for the other tower B, the balance is Let the water flow at an evenly divided flow rate. That is, it is made to pass through the tower A at a water flow rate of 11% of the total water flow rate per unit time with respect to the water treatment apparatus. For the remaining nine towers B, respectively, let water pass through at a water flow rate (a water flow rate of 9.89% of the total water flow rate of the entire water treatment apparatus per unit time) divided equally by 89% of the total water flow per unit time (89/ 9 = 9.89).

If the water passing time until the time when the water quality of the effluent from tower A showed signs of deterioration was 100 days, the accumulated water flow for the tower A up to the 100th day is the standard condition (10% of the total water flow rate is equal to each tower) 10% more than the accumulated water flow of Accordingly, when water is passed through the tower 3 under the standard conditions, it can be estimated that the water passage time (lifetime) until the quality of the treated water starts to deteriorate is 110 days.

So, after the 100th day, reducing (or stopping) the water flow of tower A and increasing the water flow of tower B so as to secure the total water flow for 10 units from one tower A and the other 9 towers B Together, in both towers A and B, the number of days of water passing is set so that the accumulated load (integrated load during water flow start to end of water collection) corresponds to a load equivalent to 110 days in the case of standard condition water flow.

For example, when the water quality requirements of the treated water are strict, and even a slight impurity is not allowed, the water flow is terminated in this step (100th day) for the one tower A. For the other 9 towers B, the water flow rate obtained by dividing the water flow rate for 10 units in a unit time corresponding to the standard condition into 9 equal parts, specifically, the water flow rate increased by 11.1% of the water flow rate under the standard condition (100%/9 = 11.1%) ).

The accumulated load of tower B at the time of 100 days is 98.9 days' worth in terms of water flow under standard conditions, and there is a remaining capacity of 11.1 days in the case of water flow under standard conditions. Therefore, the number of days of water passing after the 100th day is set so that, at the water passing speed increased by 11.1%, the accumulated load for 11.1 days under this standard condition is obtained. In this case, by passing water through the next 10 days, it becomes this integrated load. Therefore, for the tower B, water is collected by the 110th day.

By performing life prediction and water flow control in the manner described above, the life of each tower A and B can be utilized to the maximum.

It is good also as an operation in which one tower A is increased by 20% to pass water at a high flow rate, the other tower A is increased by 10% to provide a high flow rate, and the remaining eight towers B are subjected to an equal water flow.

The tower A is not always the same tower, but may be alternated for every predetermined period. For example, in a water treatment device in which three towers a, b, and c are installed in parallel, when the standard water flow rate is K, in one example, the water flow rate of towers a, b is 1.0K, and tower c is 1.2 K, and when tower c shows a sign of deterioration of water quality, the water flow rate of towers a and b is 1.1K, and the water flow rate of tower c is 0.8K, and the lifespan of each tower a, b, and c is exhausted. In another example, the water flow rate of towers a and b is 1.0K, and the water flow rate of tower c is 1.2K, and when tower c shows signs of deterioration of water quality, the water flow rate of tower a is 1.0K and that of tower b You may make the water flow rate of 1.2K, the water flow rate of tower c be 0.8K, and make tower b a higher load than tower a, and you may make it monitor the water quality of the treated water of tower b.

Although this invention was demonstrated in detail using the specific aspect, it is clear to those skilled in the art that various changes are possible without departing from the intent and scope of this invention.

This application is based on Japanese Patent Application No. 2017-001990 for which it applied on January 10, 2017, The whole is used by reference.

2, 4: valve
3: Ion exchange resin tower

Claims (5)

A method of operating a water treatment apparatus having a plurality of types of water treatment units installed in parallel and having the same treatment capacity, the method comprising:
In the operating method of a water treatment device for collecting treated water by passing the same target water through each water treatment device,
Make the water flow to some water treatment machines A higher than other water treatment machines B,
When the deterioration of the water quality of the treated water of the water treatment machine A occurs, the life of the water treatment machine B is predicted from the accumulated load to the water treatment machine A up to that point, and based on this prediction result, the water flow amount for each subsequent water treatment machine and control the water passage time,
Let the accumulated load to the water treatment machine A up to the point in time when the water quality of the treated water of the water treatment machine A deteriorates to a predetermined value as a lifetime load;
The difference (hereinafter referred to as load difference) between the integrated load on the water treatment machine B up to the time point and the life load is calculated;
After the above time point, the water flow to the water treatment machine A is stopped, and the water flow rate per unit time obtained by dividing the required treatment amount per unit time in the entire water treatment apparatus by the number of water treatment machines B is the water flow rate for each water treatment machine B,
A method of operating a water treatment device, wherein the water passing time is set such that a load obtained from the product of the water passing speed and the water passing time from the time point to the end of water collection is the load difference. The method of claim 1,
Until the deterioration of the water quality of the water treatment device occurs, the water flow rate to the water treatment device A is set to 1.05 to 1.3 times the water flow rate of the water treatment device B. The method of operating a water treatment device. 3. The method according to claim 1 or 2,
The said water treatment machine has a container, and the ion exchange resin, activated carbon, an ion exchange filter, a chelate resin, or catalyst filled in the container, The operating method of the water treatment apparatus characterized by the above-mentioned. delete delete

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