KR100373511B1 - Auto control apparatus of ozone process and AOP(Advanced Oxidation Process) using I.D(Instantaneous Ozone Demand) and method thereof - Google Patents

Abstract

The present invention relates to an automatic control apparatus and method of an ozone process and an advanced oxidation process (AOP) using an instantaneous ozone demand (ID), and a general ozone injection control method in water treatment technology is an ozone process and an advanced oxidation process. Although the proper injection concentration of ozone and hydrogen peroxide, which are key operating factors of AOP, was determined through a long-term pilot test, the present invention requires ozone amount according to the result of real-time analysis of the instantaneous consumption of ozone according to the quality of influent water. It is to calculate the ozone and hydrogen peroxide to meet the changing water quality conditions in real time, and to control the injection concentration. Therefore, since the experiment to be performed to determine the proper injection concentration of ozone and hydrogen peroxide according to the water quality of the inflow water is unnecessary, the management efficiency is improved, and the water quality can be managed constantly, thereby enabling safe water treatment.

Description

Automatic control apparatus and method of ozone process and advanced oxidation process using instantaneous ozone demand {Auto control apparatus of ozone process and AOP (Advanced Oxidation Process) using I.D (Instantaneous Ozone Demand) and method

The present invention relates to an automatic control apparatus and method of an ozone process and an advanced oxidation process (AOP) using instantaneous ozone demand (ID), and more particularly, to an ozone process and an advanced process in water treatment technology. Ozone process using instantaneous ozone demand (ID) that analyzes inflow water flowing into oxidation process (AOP) in real time through ID measuring device and automatically injects appropriate amount of ozone and hydrogen peroxide according to the changing water quality conditions in real time according to the result. An automatic control apparatus and method for an advanced oxidation process (AOP).

Ozone treatment, a technology that purifies raw water with ozone (O ₃ ), is a water purification method that removes impurities from water with strong oxidizing ozone. It is responsible for the reactivity with ozone, which is a characteristic of ozone, due to oxidative power. It is used, and the water power is much superior to the conventional chlorine treatment method.

In addition, ozone has various advantages over other oxidants such as chlorine in process installation and operation, and oxidative power, and also removes some heavy metals such as iron and manganese, and removes contaminants such as phenol and hardly decomposable substances. It is known to have excellent effects, and it is also known for its excellent removal of organic substances from water. Above all, it does not produce trihalomethane (THM), a carcinogen that can occur when using chlorine. It tastes good.

Therefore, a lot of water purification technologies using oxidizing power of ozone have been studied. Generally, water purification technology using oxidizing power of ozone is used to generate more OH radicals that affect oxidative power during ozone treatment and ozone process using ozone alone. The advanced oxidation process (AOP), which improves the oxidative power by injecting hydrogen peroxide (H ₂ O ₂ ) at the same time as ozone, is widely used, and pH as a control factor for generating more OH radicals in the advanced oxidation process (AOP) Adjustment and ultraviolet (UV) irradiation may be used.

Among these, ozone process is divided into pre-ozone process and post-ozone process according to the installed position among the whole water treatment system. Advanced oxidation process (AOP) is a water purification technology that is being put into practical use in the world. .

All ozone processes aim to improve the coagulation and sedimentation efficiency, to remove iron and manganese, to remove algae, to remove taste and odor-causing substances, and to remove color. The after ozone process removes trace organic pollutants. It is introduced to increase biodegradability of hardly degradable organic substances, to remove trihalomethane precursors (THMFP), and to disinfect pathogenic microorganisms.

As a general control method of ozone process, based on the results obtained from pilot experiments, the proportional control method of injecting ozone at a constant concentration proportional to the inflow flow rate and the residual ozone control method of maintaining the residual ozone concentration of the effluent are constant. The amount of ozone injected is controlled by the ozone generation concentration of the ozone generator and the air volume of the ozonated air.

In particular, in the conventional ozone process, the real-time control of ozone injection concentration is not performed according to the change of inflow water quality, and it is difficult to verify the treatment efficiency because it is difficult to evaluate the efficiency and operability during ozone treatment. As the impact on the process is unclear, field workers complain a lot of difficulty in setting an appropriate injection concentration, and there is no established control method for the oxidative by-products caused by the excessive injection of ozone. In addition, the inflow flow rate of the ozone process and the advanced oxidation process (AOP) is continuously changing even during the day, but since the change in the flow rate during the day is not reflected, sometimes ozone is injected because ozone is not injected to the inflow flow rate, Occasionally, very little ozone is injected and the ratio of the inflow flow rate to the ozone injection ratio is excessively changed, and thus the possibility of overinjection of ozone, adverse effects on subsequent processes, and overproduction of oxidative by-products is highly investigated.

On the other hand, the selection of control factors is very important for the construction of the automatic control system in the ozone process and the advanced oxidation process (AOP), and a lot of time and effort is required for the field application. The proportional control method is a control method that is generally spread due to the simplicity of operation, and has the advantage of being easy to control in the field. However, since the long-term pilot experiment is required for optimal control, the time and economic losses are large. In addition, since a certain amount of ozone is injected in proportion to the inflow flow rate, it has always been very difficult to cope with water quality fluctuations.

In order to solve this problem, the inflow flow rate and the water quality fluctuation should be reflected in the control system.In order to construct the automatic control system, the introduction of a real-time water quality analysis device that automatically analyzes the water quality and the data derived from these results It was required to introduce expert systems that could be controlled.

However, even when the inflow flow rate is reflected and the automatic water quality analysis device and expert system are introduced to optimize the proportional control method, there is a limit in reflecting the water quality characteristics of the raw water analyzed by the automatic water quality analysis device to the control system. Therefore, it was essential to collect data through pilot experiments, and therefore, it was difficult to expect an ideal optimum driving effect.

Therefore, in most cases, the ozone injection amount was determined according to the results of the coagulation and sedimentation efficiency by performing a Jar-test to determine the appropriate injection concentration of the flocculant and the flocculent aid.

However, as described above, in order to proceed with the experiment to determine the total ozone injection concentration, pilot-scale facilities are required to perform experiments similar to the actual conditions, and it takes a lot of time and effort. Based on this, it operates with a proportional control method (constant concentration control method) that continuously injects ozone at a certain concentration.

As such, the effect of pre-ozone treatment is unclear due to the inability to control the injection concentration of all ozone at the appropriate concentration according to the inflow water quality, and in some cases, the adverse effect is caused by excessive ozone injection. As the flow rate changes due to insufficient response to the flow rate flowing into the ozone process, the amount of inflow of ozone cannot be changed appropriately. The problem arises that it is difficult to expect the optimum operating effect of the treatment. In other words, the flow rate and water quality are changing from time to time. Especially, the problems of safety and reliability of treated water quality have always been pointed out because they do not adequately respond to changes in flow rate and water quality such as floods and droughts.

Therefore, it is urgent to develop an automatic control device for the ozone process and the advanced oxidation process (AOP) capable of responding to changes in water quality and quantity in real time, ensuring stability of treated water quality, and linking to an automatic control system.

The present invention has been invented to solve the above problems, and an object of the present invention is to calculate the optimum amount of inflow and ozone and hydrogen peroxide injected into the inflow and inflow so as to respond in real time to changes in the quantity and quality of the incoming influent An object of the present invention is to provide an automatic control apparatus and method for an ozone process and an advanced oxidation process (AOP), which allow the injection process to be performed in real time.

1 is a schematic diagram showing an automatic control apparatus for an ozone process and an advanced oxidation process (AOP) using I.D according to an embodiment of the present invention;

2 is a control flowchart of an ozone process and an advanced oxidation process (AOP) using I.D according to the present invention,

3 is a table showing an example of the constant water I.D measurement results using the I.D measurement apparatus of the present invention,

Figure 4 is a diagram showing an example of the increase in I.D according to the increase in the concentration of ozone,

FIG. 5 is a diagram showing an example of an appropriate coagulant injection condition and an I.D correspondence relationship by an aggregation test (Jar-test). FIG.

* Explanation of symbols for the main parts of the drawings

1: Raw water inlet 2: Ozone / AOP contact facility

3: Inflow flow measuring device 4: I.D measuring device

5: hydrogen peroxide storage tank 6: hydrogen peroxide injection pump

7: ozone generating device 8: ozone generating monitor

9: I.D control unit 10: treated water outlet

In order to achieve the above object,

The present invention provides an inflow flow rate measuring device formed on one side of a raw water inflow unit for inducing raw water to an ozone / AOP contact facility in a water treatment system; An I.D measuring device configured to be connected to one side of the raw water inlet to measure the instantaneous ozone demand (I.D) of the raw water; A hydrogen peroxide injection pump for supplying hydrogen peroxide stored in the hydrogen peroxide storage tank to the ozone / AOP contact facility; An ozone generator for generating ozone for supplying to the ozone / AOP contact facility; A generation ozone monitor for measuring the concentration of ozone generated in the ozone generator; ID control unit that checks the measured flow rate, instantaneous ozone demand (ID) and generated ozone concentration, calculates the ozone and hydrogen peroxide injection concentrations, determines the injection volume, and controls the ozone generator and hydrogen peroxide injection pump to supply the determined injection volume. It provides an automatic control device of ozone process and advanced oxidation process (AOP) using the instantaneous ozone demand (ID) made, including.

In addition, the present invention comprises the steps of measuring the flow rate of raw water to achieve the above object; Measuring the instantaneous ozone demand (I.D) of the raw water; Comparing the measured instantaneous ozone demand (I.D) with a previous instantaneous ozone demand (I.D) to determine whether the deviation is less than a predetermined ratio; Determining the injection amount of ozone and hydrogen peroxide by maintaining the current injection amount if the deviation of the instantaneous ozone demand (I.D) is less than a predetermined ratio; Adjusting the ozone generator and the hydrogen peroxide injection pump according to the determined injection amount of ozone and hydrogen peroxide; Measuring the ozone concentration generated in the ozone generator; Comparing the generated ozone generation amount with the determined ozone injection amount to determine whether the deviation is less than a predetermined ratio; If the deviation between the generated ozone generation amount and the determined ozone injection amount is less than a predetermined ratio, the present invention provides an automatic control method of the ozone process and the advanced oxidation process (AOP) using the instantaneous ozone demand (I.D) comprising the steps of injecting ozone and hydrogen peroxide.

In addition, if the deviation between the measured instantaneous ozone demand (I.D) and the previous instantaneous ozone demand (I.D) is more than a predetermined ratio, requesting the database for ozone and hydrogen peroxide injection amount suitable for the measured instantaneous ozone demand (I.D); Determining the injection amount of ozone and hydrogen peroxide as a new injection amount; preferably, the predetermined ratio for the deviation between the measured instantaneous ozone demand (ID) and the previous instantaneous ozone demand (ID) is preferably 10% Do.

In addition, if the deviation between the generated ozone generation amount and the determined ozone injection amount is more than a predetermined ratio, it is preferable to return to the step of adjusting the ozone generator and the hydrogen peroxide injection pump by recalculating the ozone and hydrogen peroxide injection amount. It is preferable that the predetermined ratio with respect to the deviation of the determined ozone injection amount is 10%.

The present invention made as described above calculates the proper injection concentration of ozone and hydrogen peroxide by measuring the flow rate and instantaneous ozone demand (ID) of the inflow water flowing into the ozone process and advanced oxidation process (AOP) of the water treatment system in real time, ozone generation Since the proper amount is automatically injected by controlling the device and the hydrogen peroxide supply pump, the water quality to be treated is constantly controlled, so that it is possible to respond to changes in quantity and water quality in real time, thereby improving water safety and reliability.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of the present invention that can specifically realize the above objects will be described with reference to FIGS. 1 to 5 so that those skilled in the art may easily implement the present invention.

Preferred embodiments of the invention will be described in detail by way of example only. However, the apparatus and method of the present invention can be similarly applied to other embodiments without departing from the spirit of the present invention.

1 is a schematic diagram illustrating an automatic control apparatus for an ozone process and an advanced oxidation process (AOP) using an instantaneous ozone demand (I.D). Hereinafter, a detailed configuration and operation thereof will be described with reference to the same.

The configuration of the present invention is an inflow flow rate measuring device (3) formed on one side of the raw water inlet (1) for inducing raw water to the ozone / AOP contact facility (2) in the water treatment system;

An I.D measuring device 4 formed to be connected to one side of the raw water inlet 1 to measure the instantaneous ozone demand (I.D) of the raw water;

A hydrogen peroxide injection pump (6) for supplying hydrogen peroxide stored in the hydrogen peroxide storage tank (5) to the ozone / AOP contact facility;

An ozone generator 7 for generating ozone for supplying to the ozone / AOP contact facility 2;

A generation ozone monitor 8 for measuring the concentration of ozone generated in the ozone generator 7;

Check the measured flow rate, instantaneous ozone demand (ID) and generated ozone concentration, calculate the proper injection concentration of ozone and hydrogen peroxide, determine the injection amount, and control the ozone generator and the hydrogen peroxide injection pump to supply the determined injection amount. Provided are an automatic control apparatus for an ozone process and an advanced oxidation process (AOP) using an instantaneous ozone demand (ID) including a control unit (9).

Therefore, in the water treatment system, raw water is guided through the raw water inlet 1 and supplied to the ozone / AOP contact facility 2. An inflow flow rate measuring device 3 is formed in the raw water inflow unit 1 to measure the flow rate of the incoming raw water and the measured flow rate value is transmitted to the I.D control unit 9. In addition, some of the raw water flowing through the raw water inlet 1 is supplied to the I.D measuring device 4 to measure the instantaneous ozone demand (I.D), the measurement value is also transmitted to the I.D control unit (9).

The I.D control unit 9 calculates the amount of ozone and hydrogen peroxide injected based on the instantaneous ozone demand I.D using the data transmitted from the inflow flow rate measuring device 3 and the I.D measuring device 4.

The absorbance detected by the I. D measuring device 4 is calculated according to the following equation (1).

Blank (abs./cm): absorbance of distilled water measured at 600nm

Sample (abs./cm): Absorbance of sample water measured at 600nm

Indigo Vol. (ML): Volume of Indigo reagent injected into the reaction

Sample Vol. (ML): Volume of sample injected into the reaction

f: factor value (typically 0.42)

That is, the measurement result of the ID measuring device 4 is transmitted to the ID control unit 9 and stored in the form of a data file of a computer according to time, and the ID control unit 9 is measured by the ID measuring device 4. Instantaneous ozone demand (ID) is calculated using the following equations (2) and (3) with the residual ozone concentration by absorbance being the value of the Y axis and the time (min) being the value of the X axis. Therefore, the instantaneous ozone demand (I.D) is presented to the water treatment system administrator and stored in the I.D control unit (9).

a: Initial residual ozone concentration (mg / L)

k: kc (ozone consumption rate constant)

b: ozone injection concentration (mg / L)

a: Initial residual ozone concentration (mg / L)

In addition, the ID control unit 9 sets the ozone injection concentration based on the calculated ID value. The ozone injection amount is determined according to Equation 4 below, and the ozone generator is controlled by the ID control unit 9. Ozone is generated in (7) and supplied to the ozone / AOP contact facility (2).

Inflow flow rate (L / min): Real-time measured value of inflow flow measurement device

Ozone injection concentration (mg / L): Set based on the calculated I.D value

The generation ozone monitor 8 measures the concentration of ozone generated by the ozone generator 7 and transmits the result to the ID control unit 9 to control the concentration of ozone generated. The control is performed according to Equation 5.

Accordingly, ozone / AOP contacting equipment is provided with ozone generated in the ozone generator 7 under the control of the ID control unit 9 and hydrogen peroxide stored in the hydrogen peroxide storage tank 5 supplied through the hydrogen peroxide injection pump 6. It will supply appropriately to (2). At this time, the injection amount of hydrogen peroxide is preferably injected at a predetermined ratio proportional to the ozone injection amount.

In addition, the present invention configured as described above will be described with reference to the flowchart shown in order to explain the automatic control method of the ozone process and the advanced oxidation process (AOP) using the ID according to the present invention shown in FIG. same.

First, the inflow flow rate of the inflow water introduced into the water treatment system and introduced into the ozone / AOP contact facility 2 according to the induction of the raw water inflow unit 1 is measured through the inflow flow rate measurement device (S10).

Instantaneous ozone demand (I.D) of the influent is also measured by the I.D measurement device (4) (S20).

It is determined whether the deviation is less than 10% by comparing the measured instantaneous ozone demand (I.D) with the previous instantaneous ozone demand (I.D) (S30).

At this time, if the measured difference between the instantaneous ozone demand (ID) and the previous instantaneous ozone demand (ID) is less than 10%, the amount of the previous ozone and hydrogen peroxide is injected according to the inflow of the raw water and the previous instantaneous ozone demand (ID). The injection amount of the previous ozone and hydrogen peroxide is determined (S40).

In other words, if the change is small compared to the previous measured values, it is used to determine the previously used doses without adjusting the new value again.

However, if the deviation between the measured instantaneous ozone demand ID and the previous instantaneous ozone demand ID is 10% or more, ozone suitable for the instantaneous ozone demand ID measured in the database of the ID control unit 9 and The injection amount of hydrogen peroxide is called (S50), and the flow returns to the step (S40) of determining the injection amount of ozone and hydrogen peroxide suitable for the flow rate of raw water and the new instantaneous ozone demand ID.

When the injection amount of ozone and hydrogen peroxide is determined in this step, the ozone generator 7 and the hydrogen peroxide injection pump 6 are adjusted according to the determined injection amount of ozone and hydrogen peroxide (S60), and ozone generated from the ozone generator 7 The concentration of is measured (S70).

It is determined whether the deviation between the ozone generation amount generated by the ozone generator 7 and the determined ozone injection amount is less than 10% (S80). If the deviation between the generated ozone generation amount and the determined ozone injection amount is less than 10%, ozone / hydrogen peroxide is ozone / AOP. Supply to the contact facility (2) (S90).

However, when the deviation between the generated amount and the determined ozone injection amount is 10% or more, the flow returns to the step of recalculating the ozone and hydrogen peroxide injection amount (S100), and the ozone generator and the hydrogen peroxide injection pump are adjusted again.

FIG. 3 shows ozone consumption characteristics when ozone is injected at 1.2 mg / L for the source water of the Han River. In raw water, an instant ozone demand (I.D) of about 0.61 mg / L was observed. When ozone is injected into the ID measuring device at 1.2mg / L, the daily instantaneous ozone demand (ID) is about 0.6mg / L, and it increases to about 0.95mg / L when the high turbidity water is introduced due to flooding. Appeared to be. Continuous measurement of instantaneous ozone demand (I.D) confirms that it changes depending on the quality of raw water during the day. In addition, instantaneous ozone demand (I.D) was found to increase with the concentration of ozone. This result is shown in FIG.

5 is an instantaneous ozone demand (ID) that varies according to the ozone injection concentration showing the optimum coagulation effect when the Jar-test is performed on various raw water quality and the ozone injection concentration injected into the ID measuring device. ) Is the result of comparison. From these results, it was confirmed that the instantaneous ozone demand (I.D) measured after injecting ozone into the I.D measuring device at a concentration of 1.2 mg / L regardless of the quality of raw water coincided with the appropriate ozone dose of Jar-test. From the above results, in all ozone process, when ozone is injected based on the instantaneous ozone demand (ID) value measured by the ID measuring device after the operator sets the injection concentration of ozone, It is expected to maximize processing efficiency.

Therefore, considering the flow rate of the incoming raw water, measure the instantaneous ozone demand (ID) of the incoming water by using the ID measuring device, and inject ozone based on the measured instantaneous ozone demand (ID) value or At the same time, if a predetermined amount of hydrogen peroxide is injected, it can cope with changes in quantity and water quality in real time so that the treated water quality can be managed constantly, and the water treatment can be performed safely.

Referring to the effects of the present invention described above are as follows.

As described above, according to the automatic control apparatus and method of the ozone process and the advanced oxidation process (AOP) using the instantaneous ozone demand (ID) of the present invention, the inflow of inflow water into the ozone process and the advanced oxidation process (AOP) of the water treatment system By measuring the flow rate and instantaneous ozone demand (ID) in real time, it calculates the proper injection concentration of ozone and hydrogen peroxide, and controls the ozone generator and the hydrogen peroxide supply pump to automatically inject the appropriate amount to respond to changes in quantity and water quality in real time. It is possible to manage the water quality to be treated in a constant, so that the water treatment is improved to be safe and reliable.

In addition, the manager of the water treatment system increases the management efficiency because ozone and advanced oxidation process (AOP) is treated safely without the need to periodically check the coagulation experiment, and those who receive the treated water are treated with ozone. There is an advantage that hydrogen peroxide can always be provided with a properly treated safe treatment water.

In other words, the optimum amount of ozone and hydrogen peroxide can be calculated and controlled in real time according to the quantity and quality of the incoming water, which are varied by various factors such as season, weather, torrential rain, flood, etc. The optimized altitude water purification process can be safely automated.

Claims (7)

A raw water inlet 1 for guiding the raw water to the ozone / AOP contact facility 2; An ozone / AOP contact facility (2) for supplying ozone or ozone and hydrogen peroxide to the raw water introduced by the induction of the raw water inlet (1) and reacting it; An inflow flow rate measuring device (3) formed on one side of the raw water inflow unit (1) to measure the flow rate of the incoming raw water; An I.D measuring device 4 formed on one side of the raw water inlet 1 for measuring the instantaneous ozone demand (I.D) of the incoming raw water; An ID control unit 9 for receiving the inflow flow rate and the instantaneous ozone demand ID of raw water measured by the inflow flow rate measurement device 3 and the ID measurement device 4 and calculating the concentration of ozone or ozone and hydrogen peroxide; ; Ozone process using instantaneous ozone demand (ID), characterized by comprising an ozone generator (7) for generating ozone under the control of the ID control unit (9) and supplying it to the ozone / AOP contact facility (2). And automatic control of advanced oxidation process (AOP). The method of claim 1, To supply hydrogen peroxide to the ozone / AOP contact facility (2) Install a hydrogen peroxide injection pump (6) for supplying hydrogen peroxide stored in the hydrogen peroxide storage tank (5) to the ozone / AOP contact facility (2), The hydrogen peroxide injection pump 6 controls the injection amount of hydrogen peroxide at a predetermined rate according to the supply amount of ozone supplied to the ozone / AOP contact facility 2 under the control of the ID control unit 9 ( Control device of ozone process and advanced oxidation process (AOP) using ID). The method of claim 1, Instantaneous ozone demand (ID) characterized in that it comprises a generation ozone monitor (8) for measuring the concentration of ozone generated in the ozone generator (7) and provide the result to the ID control unit (9) Automatic control device for ozone process and advanced oxidation process (AOP). Measuring the flow rate of raw water (S10); Measuring the instantaneous ozone demand (I.D) of the raw water (S20); Comparing the measured instantaneous ozone demand (I.D) with the previous instantaneous ozone demand (I.D) and determining whether the deviation is less than a predetermined ratio (S30); Determining the injection amount of ozone or ozone and hydrogen peroxide by maintaining the current injection amount when the deviation of the instantaneous ozone demand (I.D) is less than a predetermined ratio (S40); Adjusting the ozone generator or the hydrogen peroxide injection pump according to the determined ozone or the injection amount of ozone and hydrogen peroxide (S60); Measuring the generated ozone concentration generated in the ozone generator (S70); Comparing the generated ozone generation amount with the determined ozone injection amount and determining whether the deviation is less than a predetermined ratio (S80); Ozone process and advanced oxidation process (AOP) using the instantaneous ozone demand (ID), characterized in that the step of injecting ozone or ozone and hydrogen peroxide if the deviation of the ozone generated and the determined ozone injection amount is less than a predetermined ratio (S90) Automatic control method. The method of claim 4, wherein If the deviation between the measured instantaneous ozone demand ID and the previous instantaneous ozone demand ID is greater than or equal to a predetermined ratio, requesting the database for ozone or ozone and hydrogen peroxide infusions suitable for the measured instantaneous ozone demand ID (S50). Automatic control method of ozone process and advanced oxidation process (AOP) using the instantaneous ozone demand (ID) comprising a. The method according to claim 4 or 5, wherein the predetermined ratio of the deviation between the previous instantaneous ozone demand ID and the measured instantaneous ozone demand ID is 10%. Automatic control of ozone process and advanced oxidation process (AOP). The method according to claim 4, wherein if the deviation between the generated ozone generation amount and the determined ozone injection amount is equal to or more than a predetermined ratio, the ozone generation unit and the hydrogen peroxide injection pump are adjusted by recalculating the injection amount of ozone or ozone and hydrogen peroxide. Automatic control of ozone process and advanced oxidation process (AOP) using instantaneous ozone demand (ID).