JP2007245081A - Water treatment system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To enhance the disinfection performance of a measure against algae, a microbe or the like, without producing a by-product, and also output a purified treated fluid even when an ultraviolet lamp and a protective tube are abnormal. <P>SOLUTION: A water treatment system comprises: an ultraviolet irradiation apparatus 1 which places a plurality of ultraviolet lamps 25 individually contained in the protective tube 26 in a container 20, into which water to be treated flows, and irradiates a fluid to be treated in the container with an ultraviolet ray from the ultraviolet lamp; a protective tube fracture detector 7 for detecting the fracture of the protective tube; a by-pass pipe 5 connecting the upstream side with the downstream side of the ultraviolet irradiation apparatus; disinfectant injection means 10 and 11 provided on the downstream side of the ultraviolet irradiation apparatus; and a water purifying treatment monitor controller having the disinfectant injection means which normally controls so that the fluid to be treated flows into the ultraviolet irradiation apparatus, and when the fracture of the protective tube is determined from the output of the protective tube fracture detector, switches to a by-pass pipe side, transmits a command to inject a disinfectant into the disinfectant injection means and purifies the fluid to be treated. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a water treatment system for performing water purification treatment by irradiating water to be treated with ultraviolet rays.

  Conventionally, water treatment systems represented by water supply have been operated on the basis of chlorination treatment from the viewpoint of hygienic safety. However, in recent years, water pollution accidents have occurred due to emerging or reviving pathogenic microorganisms such as Cryptosporidium and Giardia.

  In addition, large quantities of algae are generated in lakes, dams, and rivers, which are sources of tap water, due to eutrophication and the progress of organic pollution, and accompanied by off-flavors, coloring disturbances, aggregation, precipitation inhibition, and filtration. Obstacles such as clogging and leakage of filtered water have occurred.

  Further, there is a problem that a chlorine agent injected for sterilization reacts with organic substances in raw water to generate harmful by-products (such as trihalomethane).

  However, with respect to many problems as described above, a water treatment system having only a basic purification treatment process including conventional agglomeration, precipitation, filtration, and chlorination is in a situation where it cannot be sufficiently dealt with.

  In view of this situation, attention has been paid to a sterilization technique using ultraviolet irradiation (hereinafter sometimes referred to as ultraviolet disinfection) as an alternative sterilization technique for chlorination. Ultraviolet disinfection technology does not require complicated chemical injection management and has the advantage that no harmful by-products are generated.

  For this reason, in a water purification plant etc., an ultraviolet irradiation process may be employ | adopted for the purpose of the oxidation of bacteria and a residual organic substance. However, in consideration of the transmission efficiency of ultraviolet rays, the treatment of irradiating ultraviolet rays to the filtered water or the agglomeration / precipitation water is usually performed.

  On the other hand, in the case of aiming at improvement of aggregation or loss of infectivity of pathogenic protozoa such as Cryptosporidium, treatment of irradiating the raw water with ultraviolet rays is performed. This is a process of irradiating ultraviolet rays instead of chlorination.

  As described above, ultraviolet rays, unlike chlorine, do not produce by-products such as trihalomethane, and have a characteristic that they are highly effective in damaging the growth ability of cryptosporidium and eliminating infectivity. Therefore, the ultraviolet irradiation treatment can be utilized by making effective use of the merits of the ultraviolet rays.

  Furthermore, in the water purification treatment, it is important not to propagate the algae contained in the raw water, but in the case of the ultraviolet irradiation treatment, the effect of effectively preventing the growth of algae has been confirmed.

  Thus, in recent years, several techniques for performing water purification using ultraviolet irradiation have been proposed.

  Since the water purification technology by ultraviolet irradiation is aimed at disinfecting pathogenic microorganisms and protozoa, a lamp that emits ultraviolet rays in the 200 nm to 300 nm wavelength region called UV-C band, which is effective for disinfection, that is, a low pressure enclosing mercury vapor. A medium-pressure mercury lamp is used.

  In addition, as an ultraviolet irradiation device for irradiating the fluid to be treated with ultraviolet rays, a cylindrical container having a function of circulating the fluid to be treated and one or a plurality of ultraviolet lamps arranged in parallel to the container axis in the cylindrical container The thing of the structure which was made is known (for example, refer nonpatent literature 1).

  However, in order to inactivate pathogenic protozoa, pathogens, bacteria, viruses, etc. that are subject to disinfection, the amount of UV irradiation required for each microbial species differs, and the fluid to be treated enters the UV irradiation device. It is necessary to be irradiated with ultraviolet rays evenly within a short time before leaving. On the other hand, the irradiation efficiency of ultraviolet rays varies depending on the turbidity and chromaticity of the fluid to be treated. In the case of ultraviolet irradiation treatment, it is particularly difficult to control the quality of raw water, so that there is a problem that it is difficult to maintain appropriate ultraviolet irradiation efficiency. That is, the ultraviolet intensity (illuminance) decreases in inverse proportion to the square of the distance from the ultraviolet lamp. As a result, in order for ultraviolet irradiation to act effectively, it is necessary for the fluid to be processed to pass through the vicinity of the ultraviolet lamp.

  As a technical means for solving this point, there is a device in which the arrangement of the treated fluid inlet pipe and the outlet pipe of the container is devised so that the treated fluid swirls in the container and flows through the vicinity of the ultraviolet lamp. Yes (for example, see Patent Document 1 or Patent Document 2).

  As another ultraviolet irradiation technology, the raw water is appropriately irradiated with ultraviolet rays by detecting the turbidity of the raw water and controlling the flow rate of the raw water flowing into the water pipe containing the ultraviolet lamp according to the detected turbidity. There has been proposed a technique that can be received (see, for example, Patent Document 3). In this document, it is proposed to use ultraviolet irradiation at the time of disappearance treatment of underwater plankton, such as a reservoir.

  In addition, a technique has been proposed in which a particle meter is installed in place of the turbidimeter, and the amount of ultraviolet irradiation is controlled using the output of this particle meter (Non-patent Document 2). Furthermore, an ultraviolet irradiation system has been proposed in which a turbidimeter and a particle meter are used in combination, and an ultraviolet irradiation amount of an ultraviolet lamp is controlled using an output obtained from these instruments (see, for example, Patent Document 4).

  In some cases, a protective tube containing the ultraviolet lamp is provided for the purpose of protecting the ultraviolet lamp disposed in the container. As a material for the protective tube, crystal quartz or synthetic quartz glass is used because it is necessary to efficiently transmit ultraviolet rays. As a result, if an excessive force or sudden impact is applied to the protective tube or the ultraviolet lamp, there is a risk that it will be easily damaged. In particular, when the ultraviolet lamp is broken, there is a problem that mercury enclosed in the lamp enters the processing fluid and quartz glass fragments constituting a protective tube or the like are mixed into the processing fluid.

Conventionally, as means for solving such an inconvenient problem, a sensor for detecting breakage of the ultraviolet lamp and a bypass pipe for bypassing instead of the ultraviolet irradiation device are provided, and ultraviolet irradiation of the fluid to be treated is performed when the lamp is broken by the sensor. An ultraviolet irradiation system has been proposed in which the treatment water contaminated with mercury is prevented from flowing into other water purification processes by shutting off the inflow to the apparatus and the discharge of the treated water flow and flowing it to the bypass pipe by opening the valve ( For example, see Patent Document 5).
Japanese Patent Application No. 2005-31820 Japanese Patent Application No. 2005-347069 JP 05-169059 A JP 2004-188273 A JP 2004-188274 A “ULTRAVIOLET DISINFECTION GUIDANCE MANUAL”, United States Environmental Protection Agency, June 2003, Draft. Shigeo Kimura et al. “Survey on Basic Performance Evaluation of Fine Particle Measuring Instruments”, Journal of Water Supply Association, Vol. 71, No. 10, pp. 31-51, published in October 2002

  However, the following problems have been pointed out in the ultraviolet irradiation apparatus and the ultraviolet irradiation treatment method described in the above-mentioned patent documents.

  In general, the quality of raw water changes greatly due to fluctuations in the water source and weather. That is, the concentration of raw water, the number of fine particles, and the concentration of organic substances are greatly changed due to a large amount of algae, rainfall, and the like, and the increase in these numerical values decreases the ultraviolet transmittance. When the transmittance of ultraviolet rays decreases, the effect of ultraviolet irradiation decreases, and accordingly, the effect of sterilizing (disinfecting) pathogenic bacteria and the like decreases. Therefore, in order to prevent a decrease in sterilization treatment, it is conceivable to adjust the ultraviolet irradiation amount based on the measurement results such as the turbidity of raw water and the number of fine particles.

  However, it is difficult to adjust the amount of ultraviolet irradiation output from the ultraviolet lamp, and in some cases, there is a possibility that the ultraviolet rays to be sterilized or the irradiation efficiency may be lowered. In particular, an ultraviolet irradiation device for small scales has only a small initial cost for an output adjustment system for ultraviolet rays, and the effect of reducing power consumption is small. As a result, it is often operated with the maximum output capable of sufficiently disinfecting the pathogenic microorganism without providing an output adjustment function.

  In addition, if the UV transmittance is greatly reduced and sufficient disinfection performance cannot be obtained even when operating at the maximum output, or if the protective tube is broken, the water treatment system must be stopped and water supply cannot be performed. There is a problem that a state occurs and the abnormal state cannot be accurately grasped.

  Furthermore, when the light is turned off due to an abnormality of a part of the ultraviolet lamp, there is a problem that the fluid flowing in the vicinity of the turned off lamp is not sufficiently irradiated with the ultraviolet light and flows out to the downstream water purification process as it is.

  The present invention has been made in view of the above circumstances, and improves the disinfection performance of algae and pathogens by uniform ultraviolet irradiation, eliminates the generation of by-products, and purifies water even when an ultraviolet lamp or protective tube is abnormal. An object of the present invention is to provide a water treatment system that outputs the treated fluid.

In order to solve the above problems, a water treatment system according to the present invention includes one or more ultraviolet lamps individually housed in a protective tube in a container into which a fluid to be treated flows, An ultraviolet irradiation device for irradiating ultraviolet rays from the ultraviolet lamp with respect to the fluid to be processed flowing through
Protective tube crack detecting means for detecting cracks in the protective tube, a bypass pipe connected via a flow path switching valve disposed on the upstream side and the downstream side of the ultraviolet irradiation device, and the flow path switching valve A disinfectant injection device provided to inject a chlorine-based disinfectant into any one of the downstream side, the upstream side of the bypass pipe and the flow path switching valve;
The flow path switching valve is controlled so that the fluid to be treated flows into the ultraviolet irradiation device at all times, and when it is determined that the protective pipe is broken from the output of the protective pipe crack detection means, the flow path switching valve is set to the bypass pipe. And a clean water treatment monitoring control device having a disinfectant injection processing means for sending the chlorine disinfectant injection instruction to the disinfectant injection device and purifying the fluid to be treated. It is.

In the water treatment system according to the present invention, one or a plurality of ultraviolet lamps individually stored in a protective tube are arranged in a container into which the fluid to be treated flows, and the fluid to be treated flowing in the container On the other hand, an ultraviolet irradiation device that irradiates ultraviolet rays from the ultraviolet lamp, an illuminance measuring means that measures ultraviolet illuminance inside the container, and a disinfection provided for injecting a chlorine-based disinfectant downstream of the ultraviolet irradiation device An agent injection device;
Ultraviolet irradiation amount determining means for determining the ultraviolet irradiation amount based on a predetermined flow rate of the fluid to be treated flowing into the container and the illuminance measured by the illuminance measuring means, and the determined ultraviolet irradiation amount is the sterilization target microorganism. Lamp output reduction determining means for determining a decrease in the output dose of the ultraviolet lamp when the threshold value is sufficient for inactivation, and the UV irradiation dose is determined to be a decrease in the output dose when determined to be a decrease in the output dose. A lamp output adjusting means for adjusting the output dose of the ultraviolet lamp so as to reach the dose threshold, and the ultraviolet dose reaches the dose threshold regardless of the adjustment of the output dose of the ultraviolet lamp. A clean water treatment monitoring and control device having disinfectant injection processing means for sending a chlorine disinfectant injection instruction to the disinfectant injection device and purifying the fluid to be treated. And is a configuration.

Furthermore, in the water treatment system according to the present invention, one or a plurality of ultraviolet lamps individually stored in a protective tube are arranged in a container into which the fluid to be treated flows, and the fluid to be treated flowing in the container On the other hand, an ultraviolet irradiation device that irradiates ultraviolet rays from the ultraviolet lamp, an illuminance measuring means that measures ultraviolet illuminance inside the container, and a disinfection provided for injecting a chlorine-based disinfectant downstream of the ultraviolet irradiation device An agent injection device;
Ultraviolet irradiation amount determining means for determining the ultraviolet irradiation amount based on a predetermined flow rate of the fluid to be treated flowing into the container and the illuminance measured by the illuminance measuring means, and the determined ultraviolet irradiation amount is the sterilization target microorganism. Water purification monitoring having disinfectant injection processing means for sending an instruction to inject the chlorine-based disinfectant to the disinfectant injecting device when the threshold is sufficient for inactivation and purifying the fluid to be processed And a control device.

  Furthermore, the water treatment system according to the present invention includes a flow rate measuring means for measuring the flow rate of the fluid to be treated flowing into the ultraviolet irradiation device, and a flow rate measurement unit newly added to any one of the system configurations described above. And a water purification treatment monitoring and control device having an ultraviolet ray irradiation amount calculating means instead of the ultraviolet ray irradiation amount determining means for calculating the ultraviolet ray irradiation amount based on the flow rate measured by the means and the illuminance measured by the illuminance measuring means. It is a configuration.

  The disinfectant injection processing means sends out an injection instruction accompanied with an injection amount of a different chlorine-based disinfectant depending on an abnormal event to the disinfectant injection device.

  According to the present invention, it is possible to improve the disinfection performance of algae countermeasures and pathogenic bacteria by uniform ultraviolet irradiation, eliminate the generation of by-products, and perform the water purification treatment even when the ultraviolet lamp or the protective tube is abnormal A water treatment system capable of outputting a fluid can be provided.

Embodiments of the present invention will be described below with reference to the drawings.
FIG. 1 is a configuration diagram showing an embodiment of a water treatment system according to the present invention.

  The water treatment system includes an ultraviolet irradiation device 1 for irradiating the water to be treated with ultraviolet rays, a treated water flow meter 2 and an inlet three-way valve 3 installed in the treated water input line of the ultraviolet irradiation device 1, and an ultraviolet irradiation device. An outlet three-way valve 4 installed in the treated water output line 1, a bypass pipe 5 connected between the inlet three-way valve 3 and the outlet three-way valve 4, an ultraviolet illuminance meter 6, a protective tube crack detector 7, The water purification process monitoring control device 8 and the lamp output adjustment power supply unit 9 are configured.

  In addition, the water treatment system includes a chlorine-based disinfection water purification area 10 connected to the downstream side of the outlet three-way valve 4, and chlorine in the chlorine-based disinfection water purification area 10 based on an injection instruction signal from the water purification treatment monitoring control device 8. A chlorine-based disinfectant injection device 11 for injecting a system-based disinfectant and a disinfectant injection pipe 12 for connecting the chlorine-based disinfectant injection device 11 and the chlorine-based disinfecting water purification area 10 are provided. The chlorine-based disinfectant injection device 11 and the chlorine-based disinfectant injection tube 12 may be connected to the bypass tube 5 or connected to the upstream side of the inlet three-way valve 3. It is preferable to connect to the downstream side of the outlet three-way valve 4 from the viewpoint of effectively utilizing the output adjustment function.

  The ultraviolet irradiation apparatus 1 is an apparatus having a mechanism for generating treated water purified by irradiating ultraviolet rays to the water to be treated which flows from the treated water input line, and specifically, the ultraviolet rays are irradiated. A cylindrical irradiation part 20-1 corresponding to the trunk part and a bulge connected to the upper end part of the irradiation part 20-1 were formed, and the upper end opening part was closed with a metal material cover. The irradiation container 20 including a cylindrical inflow portion 20-2 and an inverted conical separation portion 20-3 connected to the lower end of the irradiation portion 20-1 is connected to the fluid outlet side of the treated water input line. A treated water inlet pipe 21, a treated water outlet pipe 22 that passes through the cover from the upper part of the inflow part 20-2 and is inserted into the central axis line inside the irradiation container 20, and a lower end part of the separation part 20-2 The attached contaminant trap container 23 and the truck And contaminant collection pipe 24 mounted is provided on the flop container 23.

  As shown in FIG. 2, the irradiation unit 20-1 includes a plurality of ultraviolet lamps 25 (25-1 to 25-6) arranged in parallel to the container axis and at equal intervals in the circumferential direction. A protective tube 26 is provided on the outer periphery of the ultraviolet lamp 25 to house and protect the lamp.

  The treated water inlet pipe 21 is attached to one side wall surface of the inflow portion 20-2, and more specifically, is attached toward the tangential direction with respect to the cylindrical container cross section of the inflow portion 20-2 constituting the irradiation container 20. The water to be treated that flows into the upper part of the irradiation container 20 creates a state in which an initial swirl is generated.

  The treated water outlet pipe 22 is inserted into the irradiation container 20 from the upper part of the irradiation container 20 along the central axis of the irradiation container as described above, but its lower end is equal to or slightly more than the lower end of the ultraviolet lamp 25. Set to the upper position.

  The ultraviolet illuminance meter 6 may be attached at any position where ultraviolet rays irradiated from the ultraviolet lamp 25 reach, but on the wall of the irradiation unit 20-1 corresponding to the vicinity of the center in the vertical direction of the ultraviolet lamp 25. It is preferable to attach. Further, although one ultraviolet illuminance meter 6 may be used, it is preferable to install a plurality of ultraviolet illuminance meters because it is necessary to monitor the amount of ultraviolet irradiation irradiated from all the ultraviolet lamps 25 (25-1 to 25-6).

  Incidentally, in the present embodiment, as shown in FIG. 2, when mainly monitoring the amount of ultraviolet irradiation irradiated from the two ultraviolet lamps 25, for example, for the six ultraviolet lamps 25-1 to 25-6. It is desirable to attach three ultraviolet illuminance meters 6-1 to 6-3 at equal intervals to the circumferential wall surface of the irradiation unit 20-1 corresponding to the substantially central position of the two adjacent ultraviolet lamps 25. . That is, the ultraviolet illuminance meter 6-1 monitors the ultraviolet irradiation amount irradiated from the paired ultraviolet lamps 25-1 and 25-2, and transmits it to the water purification treatment monitoring control device 8. Similarly, the ultraviolet illuminance meter 6-2 measures the amount of ultraviolet irradiation irradiated from the ultraviolet lamps 25-3 and 25-4 that make a pair, and the ultraviolet illuminance meter 6-3 emits the ultraviolet rays from the paired ultraviolet lamps 25-5 and 25-6. Each is monitored and transmitted to the water purification treatment monitoring control device 8. Each of the ultraviolet lamps 25-1 to 25-6 is individually housed in a protective tube 26 and protected.

  The protection tube crack detector 7 may be of any detection type as long as it can detect the breakage of each protection tube 26. When each protection tube 26 is damaged, the water to be treated enters into each protection tube 26. For example, a resistance electrode sensor that detects a potential change due to an electrode, a temperature detection sensor that detects a temperature change, and a pressure change. Detection is performed by either a pressure detection sensor for detection or a strain detection sensor for detecting a strain change.

  The protective tube crack detector 7 is individually attached to each protective tube 26 when the upper and lower ends of each protective tube 26 are closed in a liquid-tight state. For example, as shown in FIG. When the upper end of each protective tube 26 opened from the upper end of the skirt 27 having a concave cross section disposed at the lower part of the cover of the cover is supported in a protruding state, one protective tube crack detector at an appropriate location in the skirt 27 7 may be fixed, and the protection tube crack may be detected.

  The lamp output adjustment power supply unit 9 has a function to increase or decrease the output irradiation amount of the corresponding ultraviolet lamp 25 based on an output increase / decrease signal accompanied by an individual lamp instruction output from the water purification treatment monitoring control device 8. It has a function of detecting the energization current of the lamps 25-1 to 25-6 and sending it to the water purification treatment monitoring control device 8.

The water purification treatment monitoring control device 8 is configured as shown in FIG. 3, for example.
That is, the water purification process monitoring and control device 8 is a keyboard or mouse for inputting and setting the irradiation threshold value, the lamp output increase / decrease width, the illuminance-irradiation table data, the disinfectant injection amount data for each abnormal event, and other necessary data. Input means 81, a program memory 82 for storing program data for executing predetermined processing, a monitoring control processing unit 83 composed of a CPU for executing predetermined processing in accordance with this program, and each ultraviolet illuminance meter 6-1 An input interface 84 having a signal conversion function for capturing the detected illuminance of ˜6-3, a display unit 85, and a data storage device 86 are provided.

  The monitoring control processing unit 83 functionally includes a protective tube crack determining means 8A for determining a protective tube crack from the output of one or more protective tube crack detectors 7, and ultraviolet illuminance meters 6-1 to 6-3. The ultraviolet ray irradiation amount determining means 8B for determining the ultraviolet ray irradiation amount from the illuminance measured in the above, and the output reduction of the corresponding ultraviolet lamps, for example, 25-1 and 25-2, from the determined ultraviolet ray irradiation amount and the irradiation amount threshold value. The lamp output decrease judging means 8C for judging, and the other adjacent when the ultraviolet ray irradiation dose does not reach the dose threshold value even though the output dose of the corresponding ultraviolet lamps 25-1, 25-2 is increased. Are provided with lamp output adjusting means 8D for increasing the output irradiation amount of the ultraviolet lamps 25-3, 25-4,... And chlorine-based disinfectant injection processing means 8E.

  The data storage device 86 is a data setting storage unit 86a for storing dose threshold value, lamp output increase / decrease width, disinfectant injection amount data for each abnormal event, and other necessary setting data, and lamp output for storing each lamp output data. The storage unit 86b, specifically described later, as shown in FIG. 4, stores an illuminance-irradiation amount table 86c that defines the relationship between the ultraviolet illuminance and the ultraviolet irradiation amount for each predetermined flow rate, and other data. A data storage unit 86d is provided.

Next, the operation of the water treatment system configured as described above will be described.
As shown in FIG. 5, the water to be treated passes through the inlet three-way valve 3 installed in the input line and is attached in the tangential direction with respect to the cross section of the cylindrical container of the inflow portion 20-2 constituting the ultraviolet irradiation device 1. Enters the treated water inlet pipe 21, enters the inflow portion 20-2 of the irradiation container 20 from the treated water inlet pipe 21, and sequentially moves from the upper part of the container toward the lower part of the container while turning clockwise around the container axis. To go.

  More specifically, the water to be treated is spirally formed in a clockwise direction while passing through the vicinity of the outer periphery of each protective tube 26 individually storing, for example, six ultraviolet lamps 25-1 to 25-6 arranged in the circumferential direction. It flows while descending in the lower direction while rotating to the right.

  Here, while the water to be treated flows through the vicinity of the ultraviolet lamps 25 (25-1 to 25-6), the ultraviolet rays are irradiated from the ultraviolet lamps 25, and the water to be treated is shown in FIG. The chromaticity changes as shown. (A) shown in FIG. 6 represents a state in which the chromaticity changes with the amount of ultraviolet irradiation. That is, the water to be treated changes to blue-red-green-yellow as the amount of ultraviolet irradiation is received, and the sterilization target microorganisms contained in the water to be treated are inactivated and moved to the separation unit 20-3. In the separation unit 20-3, after being inactivated, the sludge substance and the treated water are separated, and the sludge substance falls into the sludge substance and the wrap container 23 while being settled, while the treated water is discharged from the treated water outlet. While entering and rising from the lower end of the pipe 22, it passes through the outlet three-way valve 4 of the output line and passes through the downstream chlorine-based disinfection water purification area 10 which is normally in an undisinfected state to another water purification process (not shown). leak.

By the way, in order to inactivate the microorganisms to be sterilized, it is necessary that the ultraviolet ray irradiation dose Dose represented by the following formula is equal to or larger than the irradiation amount unique to the microorganisms to be sterilized. For example, in order to inactivate Cryptosporidium, it must be irradiated with an ultraviolet irradiation dose of 10 mJ (J is Joule) / cm ² or more.

UV irradiation dose Dose = I × t (mJ / cm ² ) (1)
In the above formula, I: ultraviolet illuminance (mW / cm ² ), t: irradiation time (s), for example, t = 1 second to 3 seconds.

  In the present embodiment, as shown in FIG. 7, the water to be treated is irradiated with ultraviolet rays from all the ultraviolet lamps 25 in the process of flowing through the vicinity of all the ultraviolet lamps 25 while turning in the irradiation container 20. The microorganisms to be disinfected can be inactivated with high irradiation efficiency.

The water purification treatment monitoring and control device 8 takes in the measured flow rate of the treated water flow meter 2 and the measured illuminance of each ultraviolet illuminance meter 6 and calculates the ultraviolet irradiation dose Dose ^unit by calculating based on the following equation. Can do.
UV dose Dose ^unit = I x t x f (Flow) (mJ / cm ² ) (2)
In this equation, I: ultraviolet illuminance (mW / cm ² ), t: irradiation time (s), f (Flow): swirl flow efficiency.

The swirling flow efficiency f (Flow) varies depending on the flow rate flow (m ³ / min) of the water to be treated. Except for the flow rate of water to be treated, the function unique to the ultraviolet irradiation device 1 is analyzed and experimented. Can be determined.

Therefore, the ultraviolet irradiation amount Dose ^unit can be determined by the flow rate of the water to be treated and the measurement illuminance of the ultraviolet illuminance meter 6. Usually, the flow rate flowing through the input line depends on the flow rate, the input line tube diameter, the processing capability of the ultraviolet irradiation devices 2a and 2b, and so on, and can be set to a substantially constant flow rate in advance.

  Therefore, a relationship as shown in FIG. 8 is established between the ultraviolet illuminance and the ultraviolet irradiation amount for each predetermined flow rate, based on the accumulation of experiments. Therefore, based on the relationship as shown in FIG. 8, the illuminance-ultraviolet irradiation amount table 86 c is created and stored in the data storage device 86.

  Therefore, in the water purification process monitoring and control apparatus 8, a series of processes as shown in FIG. 9 are executed according to the program stored in the program memory 82 and using the illuminance-ultraviolet irradiation table 86c. There are several embodiments as examples.

(First embodiment)
First, the monitoring control processing part 83 which comprises the water purification process monitoring control apparatus 8 performs the protection pipe crack determination means 8A. The protective tube crack determining means 8A determines the presence or absence of a protective tube crack from the output of one or a plurality of protective tube crack detectors 7 at predetermined intervals (S1, S2). Note that the timing for determining whether or not the protective tube is broken is not particularly limited, and may be an appropriate timing in a series of processes, for example, between steps S10 and S11 described later, and between steps S10 and S14. Absent. Further, for example, when the output of the protective tube crack detector 7 reaches a predetermined level, an interruption may be automatically made to determine whether or not there is a protective tube crack (S2).

  By the way, the monitoring control processing unit 83 executes the chlorine-based disinfection and injection processing means 8E when it is determined in step S2 that there is a protective tube crack. The chlorine-based disinfection and injection processing means 8E sends a switching signal to the three-way valves 3 and 4 when it is determined that the protective tube is broken, and after switching the flow path from the ultraviolet irradiation device 1 side to the bypass tube 5 side (S3), A disinfectant injection instruction signal is sent to the chlorine-based disinfectant injection device 11, and a desired chlorine-based disinfectant injection amount is injected into the chlorine-based disinfecting water purification area 10 via the chlorine-based disinfectant injection pipe 12 every predetermined unit time. At the same time (S4), an alarm is issued to the monitoring room (S5).

  That is, the monitoring control processing unit 83 guides the water to be treated from the bypass pipe 5 to the chlorine-based disinfection water purification area 10 without stopping the water treatment system when the protection pipe breaks, and the chlorine-based disinfection water purification area 10 Inject a chlorine-based disinfectant and perform purification treatment equivalent to conventional water treatment to ensure continuity of water supply to each consumer.

  When it is determined in step S2 that there is no protective tube cracking, the monitoring control processing unit 83 executes the ultraviolet ray irradiation amount determining means 8B. The ultraviolet ray irradiation amount determining means 8B corresponds to Y = 1 (corresponding to the ultraviolet illuminance meter 6-1) and Z-1 (lamp 25-1 or paired lamps 25-1, 25-2) on a counter (not shown). (S6, S7), the illuminance measured by the ultraviolet illuminance meter 6-1 is taken in (S8), and the illuminance-ultraviolet irradiation amount table shown in FIG. 4 is based on a predetermined flow rate. The ultraviolet irradiation amount is determined from 86c (S9). The illuminance measured by all the ultraviolet illuminance meters 6-1 to 6-3 may be taken in at the same time.

  In addition, when the ultraviolet light transmittance of the water to be treated changes, the measured illuminance of each of the ultraviolet light illuminance meters 6-1 to 6-3 changes. Therefore, the ultraviolet light transmittance of the water to be treated can be easily changed. Can be reflected. Similarly, the UV output irradiation amount decreases due to a decrease in UV output irradiation amount due to lamp deterioration or lamp failure, and dirt or scratches on the surface of the protective tube 26. Therefore, since the measurement illuminance decreases as the output irradiation amount decreases, it can be similarly reflected in the ultraviolet irradiation amount.

  When the monitoring control processing unit 83 determines the ultraviolet ray irradiation amount in step S9, the monitoring control processing unit 83 executes the lamp output decrease determining means 8C. The lamp output lowering determination means 8C compares the determined ultraviolet irradiation amount with the irradiation threshold value set in the data setting storage unit 86a, and determines whether or not the ultraviolet irradiation amount is larger than the irradiation amount threshold value. Judgment is made (S10). Note that the irradiation threshold value corresponds to a value sufficient to make the microorganisms to be disinfected non-generated.

  Here, when the determined ultraviolet irradiation amount is larger than the irradiation threshold value, it has the ability to sufficiently eliminate the microorganisms to be sterilized. It is determined whether the measured illuminance of 6-3 is compared with the dose threshold value (S11). If not yet determined, Y = 1 is incremented by +1 (S12), and the process returns to step S7 and the same. Repeat the process. When the ultraviolet irradiation amount determined based on the measurement illuminances of all the ultraviolet illuminance meters 6-1 to 6-3 is larger than the irradiation amount threshold value (S13), the process proceeds to step S1, Continue processing.

  On the other hand, when the determined ultraviolet irradiation amount is smaller than the irradiation amount threshold value in step S10, the monitoring control processing unit 83 determines that the lamp output is reduced including dirt on the protective tube 26, but proceeds to step S14. Then, it is determined whether or not to increase the lamp output. If it is determined that the lamp output is to be increased, the lamp output adjusting means 8D is executed.

  The lamp output adjusting means 8D is set in the data setting storage unit 86a when it is determined from the illuminance measured by the ultraviolet illuminance meter 6-1 that the output doses of the ultraviolet lamps 25-1 and 25-2 are decreasing. Based on a predetermined output increase / decrease width, an output increase command signal of the corresponding lamp is sent to the lamp output adjustment power supply unit 9 (S15). A value based on the output increase / decrease width for each ultraviolet lamp is stored in advance in the lamp output value storage unit 86b. Here, when the lamp output adjustment power supply unit 9 receives the output increase command signal of the corresponding lamp, the lamp output adjustment power supply unit 9 performs adjustment to increase the output irradiation amount of the corresponding ultraviolet lamps 25-1 and 25-2 by the output amplification.

  After outputting the lamp output increase command signal, the lamp output adjusting means 8D determines whether the output irradiation amount of the corresponding ultraviolet lamps 25-1 and 25-2 has reached the output upper limit value (S16), and still determines the predetermined output upper limit. If the value has not been reached, the process returns to step S8, the illuminance after the increase in lamp output of the ultraviolet lamps 25-1, 25-2 is taken in, and the same processing is repeated.

  Further, when the lamp adjustment outputs of the ultraviolet lamps 25-1 and 25-2 reach the output upper limit value, output increases (S17) of other adjacent ultraviolet lamps 25-3 and 25-4 and all lamp adjustments are not completed. (S18), +1 is incremented to Z = 1 in the counter (S19), and based on a predetermined output amplification for the adjacent ultraviolet lamps 25-3, 25-4, for example, the corresponding lamps 25-3, 25-4 An output increase command signal is sent to the lamp output adjustment power supply unit 9 (S15), and the same processing is repeated.

As described above, the output irradiation amount of the adjacent lamp is increased. If the UV dose Dose ^unit still does not provide sufficient dose to inactivate the microorganisms to be sterilized, the lamp output dose of all the UV lamps 25-1 to 25-6 will be increased. If the irradiation dose is not reached, the chlorine-based disinfectant injection processing means 8E is executed.

  The chlorine-based disinfectant injection processing means 8E sends an injection instruction signal with a disinfectant injection amount to the chlorine-based disinfectant injection device 11 without switching the three-way valves 3 and 4, unlike the case where the protective tube is broken. Then, a desired amount of chlorine-based disinfectant is injected into the chlorine-based disinfecting water purification area 10 through the chlorine-based disinfectant injection pipe 12 every predetermined unit time (S20), and an alarm is issued to the monitoring room (S21). .

  Further, when the monitor control processing unit 83 does not perform the process of increasing the lamp output even if it is determined that the lamp output is reduced in step S14, or when the output of other lamps is not increased in step S22, as described above. The chlorine-based disinfectant injection processing means 8E in steps S20 and S21 is executed.

  In S22, when the chlorine-based disinfectant injection processing means 8E is not executed, the process proceeds to step S12, and the series of processes described above for the ultraviolet illuminance meter next to the process, for example, 6-2, is executed.

  Therefore, according to the embodiment as described above, the water to be treated is, for example, in the vicinity of the outer periphery of each of the protective tubes 26,... Individually housing six ultraviolet lamps 25-1 to 25-6 arranged in the circumferential direction. In the clockwise direction and from the upper part to the lower part of the container while being spirally distributed, while being irradiated with ultraviolet rays from the ultraviolet lamps 25-1 to 25-6, the ultraviolet rays are efficiently applied to the water to be treated. Can be irradiated.

  Moreover, when output irradiation amount falls by deterioration of some ultraviolet lamps, for example, 25-1, the measurement illumination intensity of a corresponding ultraviolet illuminance meter 6-1 falls, and ultraviolet irradiation amount falls. Therefore, when the output irradiation amount of the ultraviolet lamp 25-1 decreases, not only the output irradiation amount of the ultraviolet lamps 25-1 and 25-2 is gradually increased but also the predetermined irradiation threshold is reached even when the maximum irradiation output is output. When the value does not reach the value, the output irradiation amount of other adjacent ultraviolet lamps 25-3, 25-4, etc. is increased, so that a sufficient ultraviolet irradiation amount for inactivating the sterilization target microorganism can be secured.

  When some of the ultraviolet lamps, for example, 25-1 are damaged or failed, the lamp output adjustment power supply unit 9 detects from the energized current and transmits it to the water purification treatment monitoring control device 8 to execute the chlorine-based disinfectant injection processing means 8E. Similarly, an alarm is issued to the monitoring room.

  Furthermore, when a protective pipe crack occurs, the water to be treated is guided from the bypass pipe 5 to the chlorine-based disinfection water purification area 10 without stopping the water treatment system, and a chlorine-based disinfectant is added to the chlorine-based disinfection water purification area 10. Injecting and performing the purification process corresponding to the conventional water treatment, the water supply treatment can be continued.

  Further, when the lamp output is lowered, even if the output of each of the lamps 25-1 to 25-6 is increased, the ultraviolet irradiation amount does not exceed the threshold value, or the increase control of the lamp output is not executed, as described above. Since the chlorine-based disinfectant injection processing means 8E is executed, the microorganisms to be disinfected are inactivated even if the output of some ultraviolet lamps, for example, 25-1 or all the ultraviolet lamps 25-1 to 25-6 is increased. If sufficient UV irradiation dose is not reached, water can be reliably purified and discharged.

  Furthermore, the UV irradiation amount is determined from the measured illuminance of the UV illuminance meters 6-1 to 6-3, and when the irradiation amount is smaller than the irradiation amount threshold value, the output irradiation amount can be adjusted individually or in pairs for the corresponding ultraviolet lamps. It is possible to optimize the output irradiation amount of the ultraviolet lamps individually or in pairs.

  Furthermore, when one ultraviolet illuminance meter 6 is attached to the wall of the irradiation unit 20-1 of the irradiation container 20, an area that becomes a shadow of the treated water outlet pipe 22 is generated, and is opposite to the installation location of the ultraviolet illuminance meter 6. Even if the output dose of the UV lamp decreases for some reason, it cannot be detected. However, if the ultraviolet illuminance meter 6 is arranged in the center of two adjacent ultraviolet lamps for a plurality of ultraviolet lamps, abnormalities in all the ultraviolet lamps 25-1 to 25-6 can be detected and the output irradiation amount Can be controlled in an optimum state. Although it is possible to provide an ultraviolet illuminance meter 6 for each of the ultraviolet lamps 25-1 to 25-6, it is difficult to detect a decrease in ultraviolet transmittance due to high cost and water quality deterioration, and reliably inactivate microorganisms to be treated. Although there is a fear that it is impossible, such an inconvenient problem can be solved by providing the ultraviolet illuminance meter 6 for each pair of ultraviolet lamps as in the present embodiment.

(Embodiment 2)
As the water purification treatment monitoring control device 8, the illuminance-ultraviolet irradiation amount table 86c is used to determine the ultraviolet irradiation amount. For example, instead of the illuminance-ultraviolet irradiation amount table 86c, a data storage device 86 as shown in FIG. (2) is set in the data setting storage unit 86a, and the monitoring control processing unit 83 is provided with an ultraviolet ray irradiation amount calculating means 8F instead of the ultraviolet ray irradiation amount determining means 8B. There may be.

  The ultraviolet irradiation amount calculation means 8F of the water purification process monitoring controller 8 takes in the measured flow rate of the flow meter 2 and the measured illuminance of the ultraviolet illuminance meter 6 in step S8 shown in FIG. 9, and then sets the data setting storage unit 86a. Based on the calculated equation, the UV irradiation amount is calculated in step 4. Since other configurations and processing procedures are the same as those in FIGS. 3 and 9, the description thereof is omitted here.

  Also in this embodiment, the same effect as the above-described embodiment can be obtained.

(Embodiment 3)
(Lamp damage or malfunction)
The water purification process monitoring and control device 8 detects energization currents of the ultraviolet lamps 25-1 to 25-6 through the lamp output adjustment power supply unit 9. Therefore, since it can be determined that at least a part of the ultraviolet lamps is broken or malfunctioned when the energization current is interrupted, the output irradiation amount of the adjacent ultraviolet lamps is increased as described above, or the process of increasing the output irradiation amount is not performed. If a warning is given to replace the ultraviolet lamp while performing a process of injecting a chlorine-based disinfectant into the lamp, or if a message for replacing a damaged or malfunctioning ultraviolet lamp is displayed on the display unit 85, the corresponding ultraviolet light will be promptly displayed. The lamp can be replaced. When exchanging the ultraviolet lamp, if the upper lid of the irradiation container 20 is opened and the upper part of the ultraviolet lamp is grasped and pulled out from the skirt 27, it can be easily taken out and replaced with a new ultraviolet lamp.

  Therefore, according to such an embodiment, when each ultraviolet lamp 25 or the protective tube 26 is broken due to sudden impact, the quartz glass piece or each ultraviolet lamp 25 constituting each ultraviolet lamp 25 or each protective tube 26. Mercury contained inside leaks. In such a case, due to the centrifugal separation action and the gravity action by the spiral circulation of the water to be treated, the contaminants such as quartz glass pieces and mercury are surely lowered to the contaminant trap container 23, so that the contaminants are treated. There is no spillage in water.

(Other embodiments)
(1) Considering the swirling flow efficiency f (Flow) at the maximum flow rate in advance, the illuminance of the ultraviolet irradiation dose Dose that can sufficiently inactivate the microorganisms to be disinfected is determined, and the ultraviolet lamp is set so that the determined illuminance is obtained. Even if it is the structure which adjusts the output irradiation amount of (25-1, 25-2), (25-3, 25-4), (25-5, 25-6) and performs the purification process with respect to to-be-processed water. Good.

(2) Further, when the ultraviolet irradiation amount obtained from the measured illuminance of each ultraviolet illuminance meter 6 is equal to or smaller than the irradiation amount threshold, at least the output irradiation amount of the corresponding ultraviolet lamp 25 is increased. For example, the ultraviolet lamp 25 is turned on at a predetermined output dose without adjusting the output dose of the ultraviolet lamp 15.

Then, the water purification treatment monitoring and control device 8 uses the ultraviolet irradiation amount Dose ^unit obtained from the measured illuminance of the ultraviolet illuminance meter 6 and the measured flow rate of the flow meter 2 based on the formula (2) to sufficiently sterilize the microorganisms to be disinfected. If the ultraviolet ray irradiation amount that can be inactivated is not reached, the chlorine-based disinfectant injection processing means 8E may be executed to perform water purification treatment with the chlorine-based disinfectant and to issue an alarm.

(3) Similarly to (2) above, the UV lamp 25 is turned on at a predetermined output dose without adjusting the output dose of each UV lamp 25, and the flow meter 2 is not installed in the input line. To do.

In the state as described above, the water purification treatment monitoring and control device 8 is based on the arithmetic expression of the above formula (2) from the maximum flow rate determined from the designed ability of the ultraviolet irradiation device 1 and the detected illuminance of the ultraviolet illuminance meter 6. When the obtained ultraviolet irradiation dose ^unit does not reach the ultraviolet irradiation amount that can sufficiently inactivate the microorganisms to be sterilized, a configuration may be adopted in which an alarm is immediately issued.

(4) Further, when the determined ultraviolet irradiation amount is larger than the irradiation amount threshold value in step S10, the monitoring control processing unit 83 sets an excessive irradiation amount that is equal to or greater than the ability to sufficiently inactivate the microorganisms to be disinfected. You may judge that it is irradiating and reduce the output of the lamp concerned. If it is determined that the lamp output is to be reduced, the lamp output adjusting means 8D is executed to reduce the output of the corresponding lamp. In that case, when the chlorine-based disinfectant injection processing means 8E is injecting the chlorine-based disinfectant, the injection amount of the chlorine-based disinfectant is reduced or stopped. The other configuration is not different from the configuration in which the lamp output is increased when the ultraviolet ray irradiation amount is smaller than the irradiation amount threshold value, and does not increase the lamp output but lowers the lamp output.

  In addition, the present invention is not limited to the above-described embodiment, and various modifications can be made without departing from the scope of the invention. In addition, the embodiments can be implemented in combination as much as possible, and in that case, the effect of the combination can be obtained. Further, each of the above embodiments includes various higher-level and lower-level inventions, and various inventions can be extracted by appropriately combining a plurality of disclosed constituent elements. For example, when an invention is extracted because some constituent elements can be omitted from all the constituent elements described in the means for solving the problem, the omitted part is used when the extracted invention is implemented. Is appropriately supplemented by well-known conventional techniques.

The block diagram which shows one Embodiment of the water treatment system which concerns on this invention. The figure which shows the arrangement | positioning relationship between a ultraviolet lamp and a ultraviolet illuminance meter. The block diagram which shows one specific example of a water purification process monitoring control apparatus. The table figure which prescribed | regulated the relationship between the ultraviolet illumination intensity data and ultraviolet irradiation amount data in each flow volume. The figure explaining a mode that the to-be-processed water was swirled in the irradiation container. The figure showing the state from which chromaticity changes as to-be-processed water receives irradiation of an ultraviolet-ray. The figure explaining the irradiation efficiency of the ultraviolet irradiation amount with respect to the flow volume in the past and this invention. The relationship characteristic figure of the ultraviolet illumination intensity and ultraviolet irradiation amount with respect to each predetermined flow volume. The flowchart explaining a series of process examples in the water purification process monitoring control apparatus. The block diagram which shows the other specific example of a water-purification process monitoring control apparatus.

Explanation of symbols

  DESCRIPTION OF SYMBOLS 1 ... Ultraviolet irradiation apparatus, 2 ... Flow meter, 3 ... Inlet three-way valve, 4 ... Outlet three-way valve, 5 ... Bypass pipe, 6 (6-1 to 6-3) ... Ultraviolet illuminance meter, 7 ... Protection tube crack detector , 8 ... Water purification treatment monitoring and control device, 8A ... Protection tube crack judgment means, 8B ... UV irradiation amount determination means, 8C ... Lamp output decrease judgment means, 8D ... Lamp output adjustment means, 8E ... Chlorine disinfectant injection treatment means, 8F ... UV irradiation amount calculation means, 9 ... Lamp output adjustment power supply unit, 10 ... Chlorine-based disinfection water purification area, 11 ... Chlorine-based disinfectant injection device, 12 ... Chlorine-based disinfectant injection tube, 20 ... Irradiation container, 20-1 ... irradiation part, 20-2 ... inflow part, 20-3 ... separation part, 21 ... treated water inlet pipe, 22 ... treated water outlet pipe, 23 ... pollutant trap container, 24 ... pollutant recovery pipe, 25 (25 -1-25-6) ... UV lamp, 26 ... protection tube, 82 ... Program memory, 83 ... monitor control processing unit, 86 ... data storage device.

Claims (7)

In a water treatment system that irradiates the fluid to be treated with ultraviolet rays for water purification treatment,
One or a plurality of ultraviolet lamps individually housed in a protective tube are arranged in the container into which the fluid to be treated flows, and the ultraviolet rays are irradiated from the ultraviolet lamp to the fluid to be treated flowing in the container. An ultraviolet irradiation device;
Protective tube crack detecting means for detecting cracks in the protective tube;
A bypass pipe connected via a flow path switching valve disposed on the upstream side and the downstream side of the ultraviolet irradiation device;
A disinfectant injector provided for injecting a chlorine-based disinfectant into any one of the downstream side of the flow path switching valve, the bypass pipe and the upstream side of the flow path switching valve;
The flow path switching valve is controlled so that the fluid to be treated flows into the ultraviolet irradiation device at all times, and when it is determined that the protective pipe is broken from the output of the protective pipe crack detection means, the flow path switching valve is set to the bypass pipe. And a clean water treatment monitoring and control device having a disinfectant injection processing means for sending the chlorine-based disinfectant injection instruction to the disinfectant injection device and purifying the fluid to be treated. Water treatment system characterized by In a water treatment system that irradiates the fluid to be treated with ultraviolet rays for water purification treatment,
One or a plurality of ultraviolet lamps individually housed in a protective tube are arranged in the container into which the fluid to be treated flows, and the ultraviolet rays are irradiated from the ultraviolet lamp to the fluid to be treated flowing in the container. An ultraviolet irradiation device;
Illuminance measuring means for measuring ultraviolet illuminance inside the container;
A disinfectant injection device provided to inject a chlorine-based disinfectant downstream of the ultraviolet irradiation device;
Ultraviolet irradiation amount determining means for determining the ultraviolet irradiation amount based on a predetermined flow rate of the fluid to be treated flowing into the container and the illuminance measured by the illuminance measuring means, and the determined ultraviolet irradiation amount is the sterilization target microorganism. Lamp output reduction determining means for determining a decrease in the output dose of the ultraviolet lamp when the threshold value is sufficient for inactivation, and the UV irradiation dose is determined to be a decrease in the output dose when determined to be a decrease in the output dose. A lamp output adjusting means for adjusting the output dose of the ultraviolet lamp so as to reach the dose threshold, and the ultraviolet dose reaches the dose threshold regardless of the adjustment of the output dose of the ultraviolet lamp. A clean water treatment monitoring control device having a disinfectant injection processing means for sending the chlorine disinfectant injection instruction to the disinfectant injection device and purifying the fluid to be treated. Water treatment system, characterized in that. In a water treatment system that irradiates the fluid to be treated with ultraviolet rays for water purification treatment,
One or a plurality of ultraviolet lamps individually housed in a protective tube are arranged in the container into which the fluid to be treated flows, and the ultraviolet rays are irradiated from the ultraviolet lamp to the fluid to be treated flowing in the container. An ultraviolet irradiation device;
Illuminance measuring means for measuring ultraviolet illuminance inside the container;
A disinfectant injection device provided to inject a chlorine-based disinfectant downstream of the ultraviolet irradiation device;
Ultraviolet irradiation amount determining means for determining the ultraviolet irradiation amount based on a predetermined flow rate of the fluid to be treated flowing into the container and the illuminance measured by the illuminance measuring means, and the determined ultraviolet irradiation amount is the sterilization target microorganism. Water purification monitoring having disinfectant injection processing means for sending an instruction to inject the chlorine-based disinfectant to the disinfectant injecting device when the threshold is sufficient for inactivation and purifying the fluid to be processed A water treatment system comprising a control device. In the water treatment system according to any one of claims 1 to 3,
Flow rate measuring means for measuring the flow rate of the fluid to be processed flowing into the ultraviolet irradiation device;
A water purification treatment monitoring and control device having an ultraviolet ray irradiation amount calculating means instead of the ultraviolet ray irradiation amount determining means for calculating the ultraviolet ray irradiation amount based on the flow rate measured by the flow rate measuring means and the illuminance measured by the illuminance measuring means. And a water treatment system. In the water treatment system according to any one of claims 1 to 4,
The water purification treatment monitoring and control device is provided with means for detecting a breakage or failure of the lamp from the energization current of each ultraviolet lamp, and when the ultraviolet lamp is detected as broken or broken, the chlorine is supplied to the disinfectant injection device. A water treatment system comprising: a disinfectant injection processing unit that sends a disinfectant injection instruction and purifies the fluid to be treated. In the water treatment system according to any one of claims 1 to 4,
The water treatment system, wherein the disinfectant injection processing means sends an injection instruction accompanied with an injection amount of the chlorinated disinfectant which differs depending on an abnormal event to the disinfectant injection device. In the water treatment system according to any one of claims 1 to 4,
In the ultraviolet irradiation device, one or a plurality of ultraviolet lamps, which are parallel to the axis of the container and individually housed in a protective tube, are arranged inside a cylindrical container, and swivel from the top to the bottom in the container. A water treatment system characterized by irradiating ultraviolet rays from the ultraviolet lamp onto the fluid to be treated while descending.

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