JPH06114377A - Automatic injection device of chloride agent in proportion to ultraviolet rays - Google Patents

Abstract

PURPOSE:To achieve the accurate injection amt. of a chlorine agent by correcting the operated injection amt. of the chlorine agent on the basis of the ultraviolet dose detected by an ultraviolet detection means in a chlorine pretreatment process by an injection amt. correction means. CONSTITUTION:The ultraviolet dose output X3 from an ultraviolet detector 13 is converted to an ultraviolet correction factor F(X3) in an ultraviolet dose correction factor operation means 100. The ultraviolet correction factor F(X3) is further multiplied by a correction factor P6 at a point 110 to calculate ultraviolet correction quantity X3' which is, in turn, inputted to a chlorine pre-injection ratio SV1' operation means 120. A chlorine preinjection ratio SV1' is determined by a sudden stirred water residual salt set value SV, sudden stirred water residual chlorine control output MVI and the ultraviolet correction quantity X3'. Since the chlorine pre-injection ratio SV1' determining a chlorine pre-injection quantity Q1 is determined, the chlorine pre-injection amt. Q1 is corrected on the basis of the ultraviolet correction quantity X3' being one of the correction items of the chlorine pre-injection ratio SV1'. By this constitution, the injection amt. of the chlorine agent can be corrected in chlorine pretreatment.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an ultraviolet-proportional chlorine agent automatic injection device in a pre-chlorination step in a pre-chlorination step in which a chlorine agent is injected into raw water.

[0002]

2. Description of the Related Art Disinfection of tap water is carried out for the purpose of removing pathogenic organisms in the water and protecting tap water from accidental contamination in the water distribution system in order to ensure the safety of drinking water. Since it is difficult to completely remove bacteria in water by ordinary water purification methods (eg precipitation, filtration, etc.), a chlorine agent is generally injected into the filtered water at the final stage of the water treatment process (post-chlorination). And then sterilized.

The use of chlorine agents is determined by "Enforcement Regulations of Water Supply Act (Ministry of Health and Welfare Ordinance No. 45 of 1957)" and related "Notification of Director General of Environment and Health Bureau of Ministry of Health and Welfare". It has an advantage that water can be easily disinfected and the disinfection effect remains.

However, since tap water sources have become more polluted in recent years and it is difficult to ensure the safety of drinking water only by disinfection at the final stage, a chlorine agent is injected (pre-chlorination) into raw water before treatment,
Although water purification is performed, the generation of trihalomethane (generic name) is a problem in this water purification method by pre-chlorination.

Trihalomethane in tap water is a chlorination process which is an essential process for water purification. Organic substances in the raw water such as humic substances (humic substances) such as humic acid or fulvic acid derived from nature and free residual chlorine. Is an organochlorine compound that is generated by a chemical reaction, and it has a carcinogenic effect on health, so it is important to reduce the amount of trihalomethane generated in water maintenance management. Has become an important issue.

On the other hand, in the sedimentation basin and the filtration basin installed outdoors, since the ultraviolet rays emitted from the sun are directly received, the halogen element of the chlorine agent is easily affected by the ultraviolet rays, so that the decomposition in water is remarkable. There is a problem that the sterilization effect is affected and it is difficult to add the chlorine agent that follows the subtle changes in the weather. Therefore, set the chlorine agent amount to be large considering the amount of decomposition by ultraviolet rays. There was a tendency.

[0007]

For this reason, the present invention is directed to an automatic UV-proportional chlorinating agent which can correct the chlorinating agent injection amount by detecting the UV-ray amount and achieve proper injection of the chlorinating agent. It is to provide an injection device.

[0008]

Therefore, the present invention is
In a water purification process that has a pre-chlorination process that injects a chlorine agent into the raw water taken into the water treatment plant, a chlorine agent injection amount calculation means that calculates the chlorine agent injection amount from the water intake amount, and an ultraviolet ray that detects the amount of ultraviolet rays that are irradiated Amount detecting means, injection amount correcting means for correcting the chlorine agent injection amount calculated by the chlorine agent injection amount calculating means based on the ultraviolet ray amount detected by the ultraviolet ray detecting means, and the injection amount correcting means for correcting the injection amount. And a chlorine agent injection control means for injecting the chlorine agent injection amount.

[0009]

Therefore, according to the present invention, in the pre-chlorination step, the chlorine agent injection amount calculated by the chlorine agent injection amount calculating means is corrected by the injection amount correcting means based on the ultraviolet ray amount detected by the ultraviolet ray detecting means. However, in order to inject the chlorine agent by the chlorine agent injection amount control means according to the corrected chlorine injection amount, the chlorine agent injection amount can be adjusted in accordance with the chlorine amount decomposed by ultraviolet rays,
The appropriate amount of chlorine injection can always be achieved, and the above problems can be achieved.

[0010]

Embodiments of the present invention will be described below with reference to the drawings. As shown in FIG. 1, the water treatment plant has at least a treatment well, a landing well 1, a mixing basin 2, a floc formation basin 3,
It has a settling basin 4, a rapid filtration basin (filtration basin) 5, and a water purification basin 6, and is constituted by a facility (not shown) attached thereto.

The landing well 1 arrives at a place where surface water (raw water) taken from a water intake tower (not shown) as a water intake facility arranged in a river or the like arrives via a water conduit as a water intake facility. This is to stabilize the fluctuation of the water level of the water, measure the flow rate of raw water, and enable a series of clean water treatment such as chemical injection, precipitation, and filtration to be performed accurately and easily. It also has the function of injecting alkaline agents and coagulant aids in case of high turbidity, receiving return water such as washing and draining of filter media, etc.

The mixing basin 2 has a stirrer 7 for giving rapid stirring immediately after the coagulant or the like is introduced into the landing well 1 to uniformly and sufficiently diffuse the raw water. This is because the flocculant is hydrolyzed in water to undergo a polymerization reaction and reacts with a suspension colloid in water at a high speed, and therefore needs to be rapidly stirred.

The flock formation pond 3 is a mixing pond 2 and a settling pond 4.
It is located between the two and is formed integrally with the settling basin 4, and is subjected to appropriate agitation in order to grow the agglomerated fine flocs largely. This agitation uses the energy of the water flow itself, and the vertical / horizontal combined bypass system that uses the water head with water for agitation gives strong agitation in the early stage when the particle size of the floc is small, and the floc grows large. The agitation intensity is gradually reduced as the water flow increases. Specifically, as the flow goes to the latter stage of the floc formation pond 3, the water channel width is widened to slow the average flow velocity and reduce the energy of the water flow itself. It is something that is done.

The sedimentation basin 4 removes most of suspended solids and flocs by gravity settling action, and is intended to reduce the load on the subsequent filtration basin 5. The settling tank 4 has three functions of settling, buffering and sludge.

The filter basin (rapid filter basin) 5 allows the suspended water in the raw water to be agglomerated, mixed, stirred, and precipitated to pass through the granular layer at a relatively high flow rate, and is mainly trapped by the adhesion on the filter medium 8. , The decontamination on the surface of the filter medium, the sieving action in the filtration, the blocking action and the gravity settling action are performed to remove the suspended matter. In the present embodiment, the filter medium 8 is formed by layering pebbles (sandwich type arrangement) and silica sand.

The water purification basin 6 regulates and alleviates the imbalance between the amount of filtered water and the amount of water to be sent which are generated in the operation management of the water purification process, and also responds to accidents, breakdowns, water sources and water quality fluctuations during abnormal water quality. It is for the purpose of storing purified water in preparation for facility inspection and maintenance work, and is the final stage of the water purification facility.

In order to disinfect and sterilize the raw water passing through the water purification plant having the above-mentioned structure, a sodium hypochlorite injection control device (chlorine agent injection control device) 10 using sodium hypochlorite as a chlorine agent is provided. ing. This chlorine agent injection control device 1
For example, as shown in FIG. 2, 0 is air provided on the control unit 20, the drive circuits 21 and 22, the chlorine agent storage tank 25, and the piping that connects the chlorine agent storage tank 25 and the chlorine inlets 26 and 27. The control unit 20 includes a flow meter 11 mounted on at least a pipe extending from the landing well 1 to the admixture pond 2 and a downstream of the admixture pond 2 in the control unit 20. Residual chlorine detector 12, ultraviolet detector 13, and filter basin 5
The signals from the residual chlorine detector 14 provided downstream of the filter medium 8 and the residual chlorine detector 15 provided downstream of the water purification tank 6 are input. The control unit 20 includes a pre-chlorination computer 20a and a post-chlorination computer 20b. Each of the computers 20a and 20b includes at least a central processing unit (CPU) and a random access memory (RA) not shown.
M), read-only memory (ROM), input / output port (I /
It has a microcomputer known per se composed of O) and the like.

The pre-chlorination process executed by the pre-chlorination computer 20a of the control unit 20 will be described below with reference to the functional block diagram shown in FIG.

The pre-chlorination is for introducing a chlorinating agent (sodium hypochlorite) into the raw water. First, the UV amount output X3 from the UV detector 13 and the residual chlorine detection provided in the mixing pond 2 are detected. The sudden water residual salt signal X4 from the vessel 12 and the intake water flow rate signal X2 from the flow meter 11 are input.

The ultraviolet ray quantity output X3 is converted into an ultraviolet ray correction coefficient F (X3) by the ultraviolet ray quantity correction coefficient calculating means 100. Specifically, as shown in FIG. 5, a continuous characteristic line is formed by numerical values obtained as optimum values by experiments, and calculation is performed according to this characteristic line. This characteristic diagram shows the amount of ultraviolet rays and the amount of decomposition of the chlorine agent (sodium hypochlorite in this case) due to the irradiation of ultraviolet rays in the flock formation pond 3, the sedimentation pond 4, and the filtration pond 5 without roof. On the other hand, it is obtained by the relationship with the injection amount of the chlorine agent which makes the residual chlorine amount constant in the subsequent process.

This ultraviolet ray correction coefficient F (X3) is further multiplied by a correction coefficient P6 at point 110 to obtain an ultraviolet ray correction amount X3 ', which is input to the pre-chlorine injection rate SV1' calculating means 120. The correction coefficient P6 is obtained by an experiment as a weighting of the chlorine agent injection rate SV1 ′ of the ultraviolet correction coefficient F (X3).

The sudden water residual salt signal X4 is obtained by detecting the residual chlorine amount in the mixing basin 2 of the chlorine agent injected in the landing well 1. The following injection rate correction makes this residual chlorine amount constant. It is done like this. In this injection rate correction, the rapid stirring water residual salt signal X4 is determined by the chlorine controller (ClC) 130 as the rapid stirring water residual salt set value SV1.
Based on (0 to 5 ppm), it is arithmetically converted into a sudden stirring water residual salt control output MV1 at regular intervals. On the other hand, the rapid residual water residual salt set value S
V1 is a route different from the suddenly stirred water residual salt control output MV1,
Proceed to point 140, where the injection ratio calculation coefficient P10
Is multiplied by to obtain the injection rate set value SV. Further, the intake water flow rate bias setting P1 used in the pre-chlorine injection amount Q ₁ calculating means 130, which will be described below, is calculated and set from the rapid water-mixture residual salt setting value SV1.

Pre-chlorine injection rate SV1 '(usually 0 to 5 pp
m) is calculated by the following mathematical formula 1, and is determined by the rapid stirring water residual salt set value SV, the rapid stirring water residual chlorine control output MV1, and the ultraviolet ray correction amount X3 ′. As a result, the pre-chlorine injection rate SV that determines the pre-chlorine injection amount Q ₁
Since 1 ′ is calculated, the pre-chlorine injection amount Q ₁ is corrected by the ultraviolet ray correction amount X3 ′ which is one of the correction terms of the pre-chlorine injection rate SV1 ′.

[0024]

## EQU1 ## SV1 '= SV + (MV1-0.5) + X3'

The intake flow rate signal X2 is supplied to the filter (LAG
1) it is converted in the calculation intake flow X2 '(X2' = X2 · P3 + P5) by passing through 150 and point 160, before the chlorine injection amount Q ₁ before the Equation 2 below the arithmetic unit 130 chlorine injection rate Q ₁ (Usually 0-4
0 liter / h) is calculated.

[0026]

[Formula 2] Q ₁ = K ₁ (X2 ′ + P1) · SV1 ′ / P7 + P2

K ₁ is a calculation constant, P 1 is a water intake amount bias setting, P 7 is a sodium hypochlorite concentration setting, P 2 is
Is an injection amount bias at the time of pre-chlorination.

The result of this calculation is output to the cascade terminal (C) of the switch 170 and sent to the chlorine injection amount controller 180 according to the setting of the switch 170. In the chlorine injection controller 180, for example, a signal corresponding to the previous chlorine injection amount X1 which is output by detecting the actual chlorine injection amount, or which is called from the memory that stores the previous previous chlorine injection amount is stored. , The pre-chlorine injection amount Q ₁ performs damper control or PID control, and the control signal Q
_C1 is output to the switch 180.

When the cascade / auto (C / A) is selected by the switch 180, the control signal Q _C1
Is output from the control unit 20 to the drive circuit 21 as a V1 operation output for controlling the pneumatic flow control valve 23. The drive circuit 21 controls the flow control valve 23 to store the chlorine agent stored in the chlorine agent storage tank 25. (Sodium hypochlorite) is injected into the raw water of the landing well 1 from the chlorine agent inlet 26.

In the case of the above cascade control, the switch 170 is connected to the C terminal side and the switch 190 is connected to the C terminal side.
/ A terminal side, in the case of automatic control,
The switch 170 is connected to the A / M terminal side, and the switch 190 is connected to the C / A terminal side. In this case, the V1 operation output is controlled by the pre-chlorine injection amount X1, and the constant chlorine injection amount is obtained by the pre-chlorine injection amount X1.

In the case of manual control, the switch 170 is connected to the A / M terminal side and the switch 190 is connected to the M side, so that the pre-chlorine control is effectively stopped. Manual control can be executed.

As described above, according to the pre-chlorination according to the present invention, the amount of sodium hypochlorite decomposed by ultraviolet rays in the roofless floc formation basin 3, settling basin 4 and filtration basin 5 is supplemented. Therefore, the amount of residual chlorine in the purified water for post-chlorination can be kept constant, and the post-chlorination described below can be performed normally.

Post-chlorination computer 20b shown in FIG.
The post-chlorination process, which is carried out in, is for adding a chlorine agent (sodium hypochlorite) to the final stage purified water.
The filter basin residual salt signal X6 from the residual chlorine detector 14 provided in the filter basin 5 and the purified water residual salt signal X7 from the residual chlorine detector 15 provided in the water purification basin 6 are input.

The filter pond residual salt signal X6 is the filter (LA
G2) Converted to a correction coefficient X6 ′ by passing through 300 and point 310 (X6 ′ = P4 · X6 + P1
1) and is input to the post-chlorine injection rate calculation SV2 ′ calculation means 320.

In the chlorine controller (ClC) 330, the purified water residual salt signal X7 is converted into a purified water residual salt control output MV2 at regular intervals based on the rapid stirring residual water residual salt set value SV2 (0 to 1 ppm). The post chlorine injection rate calculation SV
It is input to the 2'computing means 320. In addition, the rapidly stirred water residual salt set value SV2 is also input to the post-chlorine injection rate calculation SV2 ′ calculation means 320.

As a result, the post-chlorine injection rate calculation SV2 '
The calculation means 320 calculates the post-chlorine injection rate calculation SV2 ′ by the following mathematical formula 3.

[0037]

## EQU00003 ## SV2 '= (SV2-X6') + (MV2-0.5)

The calculation result is sent to the post-chlorine injection amount Q ₂ calculation means 330, and the calculation intake water flow rate X2 ′ input from the pre-chlorination is input to the post-chlorine injection amount Q ₂ calculation means 330. Then, the post-chlorine injection amount Q ₂ (0 to 15 liters / h) is calculated by the following formula 4.

[0039]

[Number 4] _{Q 2 = K 2 (X2 '} + P1) SV2' / P7 + P12

K ₂ is an arithmetic constant, and P 12 is an injection amount bias at the time of post-chlorination.

The post-chlorine injection amount Q ₂ calculated by this
Is input to the cascade (C) terminal of the switch 340, and is input to the chlorine injection amount controller (FC) 350 by the selection of the switch 340. The FC350, is input chlorine injection quantity X5 rear as before chlorination process described above, the control signal Q _C2 by performing the same control as FC180 is set, the control unit as V2 operation output via the switches 360 20 to the drive circuit 22, and the drive circuit 22 controls the pneumatic flow control valve 24 so that the chlorinating agent (sodium hypochlorite) stored in the chlorinating agent storage tank 25 is transferred to the chlorinating agent inlet 27. Is injected into the purified water of the filtration pond 5.

The switches 340 and 360 are switched in the same manner as the switches 170 and 190 described above.

Further, the pre-chlorine injection amount X1 and the post-chlorine injection amount X5 are added at a point 380, and the totalizer 3 is added.
At 90, the total injection volume is measured.

In the above-mentioned pre-chlorination and post-chlorination, the amount of the chlorine agent injected into the landing well 1 can be corrected by detecting the amount of ultraviolet light, so that the floc formation pond 3, sedimentation pond 4 and filtration pond 5 The sterilizing and disinfecting action by the chlorine agent can be stably performed, and the water quality reaching the filter basin 4 can be stabilized. Further, the stability of the water quality in the filter basin 4 can stabilize the chlorine injection amount in the post-chlorination, so that purified water containing an appropriate chlorine agent can be obtained, and delicious water without chlorine odor can be obtained. It is a thing.

[0045]

As described above, by correcting the chlorine injection amount in the pre-chlorination with the ultraviolet ray amount,
Since the amount of chlorine agent injected during pre-chlorination can be adjusted appropriately and the amount of residual chlorine in the water supplied at the final stage of clean water treatment can be stabilized, the amount of chlorine agent injected during post-chlorination can be suppressed. In addition, it is possible to reduce the total amount of chlorine agent to be injected, improve economic efficiency, and obtain safe and high-quality delicious water without chlorine odor. In addition, the production of trihalomethane (generic term), which is a carcinogen, can be suppressed by achieving proper injection of the chlorine agent.

[Brief description of drawings]

FIG. 1 is an explanatory diagram showing a configuration of a water purification plant according to an embodiment of the present invention.

FIG. 2 is a schematic configuration diagram of a chlorine agent injection control device.

FIG. 3 is a functional block diagram showing a pre-chlorination process.

FIG. 4 is a functional block diagram showing post-chlorination.

FIG. 5 is a characteristic diagram showing an ultraviolet correction coefficient value calculation.

[Explanation of symbols]

 1 Landing well 2 Mixing basin 3 Flock formation basin 4 Settling basin 5 Filtration basin 6 Purification basin 10 Chlorine injection control device 11 Flow meter 12,14,15 Residual chlorine detector 13 Ultraviolet detector 20 Control unit 21,22 Driving circuit 23 , 24 Pneumatic flow control valve 25 Chlorine agent storage tank

Claims (1)

[Claims] 1. In a water purification treatment having a pre-chlorination step of injecting a chlorine agent into raw water taken into a water purification plant, a chlorine agent injection amount calculation means for calculating the chlorine agent injection amount from the water intake amount, and an ultraviolet ray to be irradiated. An ultraviolet ray amount detecting means for detecting the amount, an injection amount correcting means for correcting the chlorine agent injection amount calculated by the chlorine agent injection amount calculating means based on the ultraviolet ray amount detected by the ultraviolet ray detecting means, and the injection amount And a chlorine agent injection control means for injecting the chlorine agent injection amount corrected by the correction means.