JP2014151275A - Fluid treatment device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a fluid treatment device which can detect the amount of light of each of a plurality of ultraviolet lamps.SOLUTION: In a fluid treatment device 1 which includes a treatment tank 2 in which fluid to be treated flows, a plurality of ultraviolet lamps 8 which are stored around a central axis C of the treatment tank 2, and a cleaning mechanism 20 which has a driving shaft 23 of a cleaning plate 25, reciprocating along lamp sleeves 9 each inserted with the ultraviolet lamp 8 to clean the surfaces of the lamp sleeves 9, at the central axis C of the treatment tank 2, a sensor 33 is provided which detects the amount of light of the ultraviolet lamps 8, at least one light guide body 31 is provided which has a light guide part 35A at a tip thereof to guide the light of the ultraviolet lamps 8 to the sensor 33, and the light guide part 35A of the light guide body 31 is installed so as to be turnable to each of the ultraviolet lamps 8 or the light guide body 31 is installed for each ultraviolet lamp 8.

Description

  The present invention relates to a fluid treatment apparatus that performs sterilization treatment by irradiating a fluid such as purified water with ultraviolet rays.

2. Description of the Related Art Conventionally, an ultraviolet irradiation apparatus for running water treatment is known in which a tubular ultraviolet lamp extending along the flow of the water to be treated is installed in a cylindrical treatment tank in which the water to be treated is circulated to perform sterilization and the like. Such an ultraviolet irradiation device is installed in a water purification plant and is suitably used for purification of raw water and various types of industrial water (for example, see Patent Document 1).
By the way, in this kind of ultraviolet irradiation device, in order to maintain a predetermined sterilizing ability, it is necessary to replace the ultraviolet lamp whose light amount has decreased due to deterioration over time with a new one, and a light sensor detects a decrease in illuminance of the ultraviolet lamp. ing. For example, in the apparatus described in Patent Document 2, an illuminance measurement device is provided in a processing tank surrounded by an ultraviolet lamp, and the illuminance measurement device measures the illuminance of the ultraviolet lamp.

JP 2007-21434 A Japanese Patent No. 4186078

However, when the illuminance measuring device is provided in the processing tank surrounded by the ultraviolet lamp, the light from a plurality of ultraviolet lamps is incident on the illuminance measuring device at the same time, so the ultraviolet light emitted from all the lamps is added up. The illuminance of the ultraviolet lamp could be measured only by the value. Therefore, it has not been possible to detect that the illuminance of a specific lamp among the plurality of ultraviolet lamps has been extremely reduced, and the processing capacity may be reduced due to the collapse of the illuminance distribution in the treatment tank.
An object of the present invention is to provide a fluid processing apparatus that can solve the above-described problems of the prior art and can detect individual light amounts of a plurality of ultraviolet lamps.

  In order to achieve the above object, the present invention provides a treatment tank in which a fluid to be treated circulates, a plurality of ultraviolet lamps housed around the center of the treatment tank, and protective tubes into which the ultraviolet lamps are respectively inserted. And a cleaning mechanism having a cleaning plate drive shaft at the center of the processing tank for reciprocating along and cleaning the surface of the protective tube, and a sensor for detecting the light quantity of the ultraviolet lamp in a fluid processing apparatus, A light introduction part at a tip part, and at least one light guide for guiding the light of the ultraviolet lamp to the sensor, the light introduction part of the light guide for each of the ultraviolet lamps The light guide is provided so that it can be turned freely, or the light guide is provided for each ultraviolet lamp.

  In the fluid processing apparatus according to the present invention, the light guide is disposed at a position where the light introduction unit is not hidden behind at least the drive shaft.

  According to the present invention, in the fluid treatment apparatus, the sensor is provided for each light guide.

  According to the present invention, in the fluid processing apparatus, the light guide for guiding the light amount of the ultraviolet lamp can be switched to the sensor.

  According to the present invention, in the fluid treatment apparatus, the deterioration of each lamp is determined based on the degree of decrease in the light amount of the ultraviolet lamp detected by the sensor.

  According to the present invention, the light amounts of a plurality of ultraviolet lamps can be individually captured by at least one light guide disposed in the processing tank.

It is a figure which shows the structure of the fluid processing apparatus which concerns on embodiment of this invention. It is a figure which shows the AA cross section of FIG. It is a figure which shows typically the structure of an ultraviolet-ray detection mechanism. It is a figure which shows typically the structure of the light guide as a modification of this invention, (A) is a light guide which introduces incident light with a 45-degree mirror surface, (B) introduces incident light with a curved mirror. (C) is a figure which shows the light guide which introduces incident light by the curved-surface shape of the front-end | tip of a light guide. It is a figure which shows typically the structure of the ultraviolet-ray detection mechanism as a modification of this invention.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. In the following description, as one aspect of the fluid treatment apparatus 1 according to the present invention, a water purification plant is used to sterilize (disinfect) the water to be treated as the water to be sterilized to be treated. A running water sterilizer for inactivating microorganisms will be described.

FIG. 1 is a schematic diagram showing a configuration of a fluid processing apparatus 1 according to an embodiment to which the present invention is applied.
As shown in FIG. 1, the fluid processing apparatus 1 includes a cylindrical processing tank 2 constituting a casing, and a plurality of ultraviolet lamp bodies 3 provided in the processing tank 2.
The treatment tank 2 is made of, for example, stainless steel, and the openings at both ends thereof are closed by flanges 4 and 5. On the outer surface of the treatment tank 2, an introduction port 6 that is provided at one end and introduces water to be treated, and a lead-out port 7 that is provided at the other end and leads out the water to be sterilized, Is arranged.
From the introduction port 6, the water to be treated before sterilization is introduced into the treatment tank 2 while maintaining a predetermined flow rate (or flow pressure), and moves in the treatment tank 2 toward the outlet port 7 by the flow pressure. Then, the water to be treated is sterilized by being irradiated with ultraviolet rays from the ultraviolet lamp body 3 while moving in the treatment tank 2, and discharged from the outlet port 7 to the outside.

The ultraviolet lamp body 3 includes a straight tube type ultraviolet lamp 8 and a lamp sleeve (protective tube) 9 as a cylindrical tube made of quartz, for example, made of quartz, to which the ultraviolet lamp 8 is mounted. The lamp sleeve 9 extends along the central axis C of the processing tank 2 and is provided so as to pass through the flanges 4 and 5 at both ends. Both ends of the lamp sleeve 9 are opened, and air flow into the lamp sleeve 9 is achieved. Secured and prevents condensation. Each end of the lamp sleeve 9 is supported by the flanges 4 and 5, and is held at a strength that can withstand the fluid pressure in the treatment tank 2.
The ultraviolet lamp 8 is configured to have a length that extends from the inlet port 6 to the outlet port 7 when mounted on the lamp sleeve 9. Thereby, ultraviolet rays are irradiated over the entire range of the flow path from the introduction port 6 to the outlet port 7.

As shown in FIG. 2, for example, four ultraviolet lamp bodies 3 can be arranged in the processing tank 2. The four ultraviolet lamp bodies 3 may be configured to be equally spaced from each other along the circumference of a predetermined radius from the central axis C of the processing tank 2, or the distance from the central axis C, And the structure arrange | positioned in the position where the distance between the adjacent ultraviolet lamp bodies 3 differs may be sufficient.
By the way, the sterilizing ability of the fluid treatment apparatus 1 depends on the output of ultraviolet rays from each ultraviolet lamp body 3. In the fluid treatment apparatus 1, when a scale or the like adheres to the surface of the lamp sleeve 9 that accommodates the ultraviolet lamp 8, the transmittance of the lamp sleeve 9 is lowered, thereby reducing the ultraviolet output of the ultraviolet lamp body 3. The sterilizing ability is also reduced. Moreover, since the output of the ultraviolet rays of the ultraviolet lamp 8 decreases with time deterioration, the sterilizing power also decreases due to this.

In the fluid treatment apparatus 1, as shown in FIG. 1, a cleaning mechanism 20 and an ultraviolet ray are disposed inside the treatment tank 2 in order to prevent the sterilizing power from being lowered due to a decrease in the output of ultraviolet rays from the ultraviolet lamp body 3. And a detection mechanism 30.
The cleaning mechanism 20 is a mechanism for cleaning the surface of the lamp sleeve 9. The cleaning mechanism 20 regularly cleans the scale and the like attached to the surface of the lamp sleeve, thereby preventing the transmittance of the lamp sleeve 9 from decreasing.

  The cleaning mechanism 20 includes a drive shaft 23, a moving body 24 provided so as to be capable of reciprocating between both ends of the processing tank 2 along the drive shaft 23, a cleaning plate 25 connected to the moving body 24, An annular cleaning brush 22 that is supported by the cleaning plate 25 and into which the lamp sleeve 9 is fitted, and a guide shaft 28 that supports the cleaning plate 25 are provided. The drive shaft 23 is composed of, for example, a ball screw and is disposed on the central axis C of the processing tank 2. One end of the drive shaft 23 is supported by the flange 4 and the other end passes through the flange 5, and is connected to the drive motor 26 by a rotational force transmission mechanism 27. When the drive shaft 23 is rotationally driven by the drive motor 26, the moving body 24 moves along the drive shaft 23. As the moving body 24 moves, the cleaning plate 25 connected to the moving body 24 moves, whereby the cleaning brush 22 wipes the outer peripheral surface of the lamp sleeve 9 and the lamp sleeve 9 is cleaned.

  The cleaning plate 25 is configured to remain near the end of the processing tank 2 and closer to the flange 4 than the introduction port 6 so as not to cause an ultraviolet shadow of the ultraviolet lamp 8 during non-cleaning. ing. When the lamp sleeve 9 is cleaned, the cleaning plate 25 is reciprocated in the processing tank 2 with the flange 5 side of the outlet port 7 as a turning point as the drive motor 26 is driven. As the cleaning plate reciprocates, the cleaning brush 22 wipes the outer peripheral surface of the lamp sleeve 9 to clean the lamp sleeve 9 and prevent a decrease in the output of ultraviolet rays due to contamination of the lamp sleeve 9.

Next, the configuration of the ultraviolet detection mechanism 30 will be described.
The ultraviolet detection mechanism 30 is a spatial ultraviolet illuminance monitor, and is guided by a light guide 31, a sleeve (protection tube) 32 on which the light guide 31 is mounted, and the light guide 31, as shown in FIG. 3. The sensor 33 which detects the illumination intensity of an ultraviolet-ray, and the rotation mechanism 34 which rotationally drives the light guide 31 are provided.
The light guide 31 is formed of a light guide rod that is sufficiently transmissive to ultraviolet rays, such as quartz, and is attached to the sleeve 32 and provided in the processing tank 2 in parallel with the ultraviolet lamp 8. At least one light guide 31 is disposed inside the processing tank 2. The light guide 31 is disposed at a position where the drive shaft 23 is not shaded by the ultraviolet rays from the respective ultraviolet lamp bodies 3 (see FIG. 2). For example, in the case where the ultraviolet rays from at least one ultraviolet lamp body 3 among the plurality of ultraviolet lamp bodies 3 cannot be introduced into the light guide 31 due to the drive shaft 23 being shaded, the plurality of ultraviolet detection mechanisms 30 are disposed in the processing tank. 2 may be provided inside.

  The light guide 31 is provided so that one end side penetrates the flange 4 and protrudes outside the processing tank 2 while maintaining the sealing property of the processing tank 2. The light guide 31 can be configured to maintain an airtightness of the processing tank 2 by interposing an O-ring (not shown) fitted on the outer periphery of the light guide 31 between the light guide 31 and the flange 4, for example. . The distal end portion 35 which is the other end side of the light guide 31 is cut at an angle of 45 degrees with respect to the longitudinal axis, and the cut surface takes in the ultraviolet light of the ultraviolet lamp 8 (light introduction portion). It is formed as 35A. The light guide part 35A may be configured such that means for reflecting light such as aluminum vapor deposition is provided outside the cut surface of the light guide 31 to improve the reflection of the incident light L. As a result, the light guide body 31 is remarkable for the incident light L in a plane including both the axis line and the normal line of the light guide portion 35 </ b> A and from a direction substantially perpendicular to the axis line of the light guide body 31. The allowable incidence characteristics are shown.

  The light guide 31 is formed such that the tip 35 is positioned within the light emission length of the ultraviolet lamp 8. The light guide 31 may be configured to guide the ultraviolet light incident from the light guide 35A to the sensor 33. Alternatively, the light guide 31 converts the ultraviolet light incident from the light guide 35A into visible light by using a fluorescent material. The structure led to 33 may be used.

The sleeve 32 is formed in a cylindrical shape from quartz and has ultraviolet light transmissivity. One end of the sleeve 32 is supported by the flange 4.
The sensor 33 is attached to the opposite end of the distal end portion 35 of the light guide 31 provided with the light guide portion 35A. Light incident on the light guide 31 from the light guide 35 </ b> A is guided to the sensor 33 by the light guide 31. The sensor 33 outputs an electrical signal corresponding to the intensity of the light guided by the light guide 31 and detects the illuminance of the ultraviolet ray of the ultraviolet lamp 8.

  The light guide 31 is connected to a rotation mechanism 34 provided outside the processing tank 2. The rotation mechanism 34 includes a mechanism for rotating the light guide 31 around the longitudinal axis, for example, a motor. The rotation mechanism 34 also has a mechanism, for example, an encoder, for grasping the direction in which the light guide portion 35A of the distal end portion 35 of the rotating light guide 31 is directed. The ultraviolet detection mechanism 30 is configured to freely turn the light guide portion 35 </ b> A of the light guide 31 to each of the ultraviolet lamps 8 by the rotation mechanism 34.

  As described above, the light guide unit 35A has a configuration that has strong incidence tolerance characteristics with respect to light from a specific direction (see FIG. 2). And the ultraviolet detection mechanism 30 rotates the light guide 31 by the rotation mechanism 34, and synchronizes and monitors the direction in which the light guide part 35A faces and the strength of the electric signal output from the sensor 33, The illuminance of ultraviolet rays of each ultraviolet lamp 8 is individually monitored. The rotation mechanism 34 rotates the light guide 31 intermittently or continuously. Further, the rotation mechanism 34 can be configured to slowly rotate the light guide 31 over, for example, one minute or more.

The light guide 31 is not necessarily arranged at the geometric center position of the plurality of arranged ultraviolet lamps 8. Therefore, the arrangement direction of each ultraviolet lamp 8 viewed from the light guide 31 can be stored in advance in the ultraviolet detection mechanism 30. Thereby, the intensity or decrease in the output of each ultraviolet lamp 8 can be individually monitored from the detection result of the sensor 33 corresponding to the rotation angle of the light guide 31.
Further, the ultraviolet detection mechanism 30 determines the deterioration of each ultraviolet lamp 8 based on the degree of decrease in the amount of light of the ultraviolet lamp 8 detected by the sensor 33. Thereby, even if the distance between the light guide 31 and each ultraviolet lamp 8 is different for each ultraviolet lamp 8, the deterioration of each ultraviolet lamp 8 can be determined individually.
Moreover, when providing the several ultraviolet detection mechanism 30 in the inside of the processing tank 2, the intensity of the output of each ultraviolet lamp 8 is based on the illumination intensity of the ultraviolet-ray detected by the sensor 33 with which each light guide 31 was equipped. And monitor declines individually.

As described above, according to the present embodiment, the intensity or decrease in the output of the ultraviolet rays of each ultraviolet lamp 8 can be individually identified. As a result, when a specific lamp among the plurality of ultraviolet lamps 8 causes a significant decrease in illuminance or the like, the light quantity distribution of the ultraviolet rays in the treatment tank 2 is greatly collapsed, and the treatment capacity of running water is reduced. Can be detected.
In addition, when the lamp itself or the power supply for lighting the lamp supports dimming lighting, it is not limited to detecting a decrease in processing capacity due to a local decrease in illuminance, but linked to the dimming effect in a controlled manner. By increasing only the illuminance of the lamp that has caused the illuminance to decrease, it is possible to continue the operation while maintaining a predetermined processing capacity without unnecessarily increasing the illuminance of the normal lamp.

Next, a modified example of the light guide 31 will be described with reference to FIGS. 4 and 5.
As described above, in the light guide 31, the distal end portion 35 of the light guide 31 is cut at an angle of 45 degrees with respect to the longitudinal axis, and this cut surface is formed as the light guide 35A. It is not limited to. For example, as shown in FIG. 4A, the distal end portion 35 of the light guide 31 may be cut perpendicularly to the axis to form a light guide portion (light introduction portion) 35B. The light guide 31 is provided at a predetermined distance from the light guide 35B provided at the tip of the light guide 31 at an angle of 45 degrees with respect to the axis of the light guide 31, and the reflecting surface is directed to the light guide 35B. Alternatively, a configuration having a mirror 36 may be used. The mirror 36 reflects the incident light L toward the light guide 35 </ b> B, and causes the incident light L to enter the light guide 31.

  As described above, the light guide 31 having the mirror 36 has a strong incidence tolerance characteristic with respect to light from the direction in which the reflecting surface of the mirror 36 is directed. In order to individually monitor the illuminance of the ultraviolet rays of each ultraviolet lamp 8, the light guide 31 is rotated by the rotation mechanism 34 described above, and the mirror 36 attached to the distal end portion 35 of the light guide 31 is guided to the light guide. It can be set as the structure rotated with 31. FIG. In addition, the light guide 31 has a fixed configuration, and a configuration in which only the mirror 36 is rotated by a mirror rotation mechanism (not shown) so that the reflection surface of the mirror 36 can be freely directed to each of the ultraviolet lamps 8. Can do. According to this configuration, the light guide 31 and the mirror 36 are rotated together, or the mirror 36 is rotated about the axis of the light guide 31, so that the sensor 33 is passed through the light guide 31 by the mirror 36. It is possible to individually detect the illuminance of the ultraviolet rays of each ultraviolet lamp 8 led to.

  Further, as shown in FIG. 4B, the light guide 31 has a curved reflecting surface that allows light from a specific direction to enter the light guide 35B at a position away from the light guide 35B by a predetermined distance. A configuration having a curved mirror 37 may also be used. The curved mirror 37 may be configured to be rotated together with the light guide 31 in order to individually monitor the illuminance of the ultraviolet rays of each ultraviolet lamp 8, or may be curved mirrors by a mirror rotating mechanism (not shown). Only 37 may be rotated. As described above, by adopting a configuration in which the incident light L is guided to the light guide 31 by the curved mirror 37, a wide range of light in the longitudinal direction of the rod-shaped ultraviolet lamp 8 can be sent to the light guide 31. Therefore, it is possible to pick up ultraviolet rays in a wide range in the longitudinal direction of each ultraviolet lamp 8 to be monitored, or pick up ultraviolet rays of an arbitrary part of the ultraviolet lamp 8.

  Moreover, the light guide 31 may have a configuration in which the distal end portion 35 is cut into a curved shape into which light from a specific direction is incident, as shown in FIG. Further, on the outer side of the cut surface of the tip portion 35, means for reflecting light such as aluminum vapor deposition is provided, and the light guide portion 35C in which the reflection of the incident light L is improved is formed. good. As a result, the light guide 31 can guide the incident light L incident on the light guide 35C from a direction substantially perpendicular to the axis of the light guide 31 to the sensor 33 along the axis.

  Further, as shown in FIG. 5, the ultraviolet detection mechanism 30 may include a plurality of light guides 31 provided for each ultraviolet lamp 8 in a sleeve (protection tube) 32. In each light guide 31, the light guide 35A is arranged toward the corresponding ultraviolet lamp 8. The ultraviolet rays from the corresponding ultraviolet lamps 8 are incident on each light guide 31. The ultraviolet detection mechanism 30 is configured to be able to selectively switch the light guide 31 that guides light to the sensor 33.

  As described above, according to the embodiment to which the present invention is applied, the treatment tank 2 in which the fluid to be treated flows, and the plurality of ultraviolet lamps 8 housed around the central axis (center) C of the treatment tank 2 A cleaning mechanism 20 having a drive shaft 23 of a cleaning plate 25 for reciprocating along the lamp sleeve 9 into which the ultraviolet lamps 8 are inserted and cleaning the surface of the lamp sleeve 9 on the central axis C of the processing tank 2; In the fluid processing apparatus 1 having the above, at least one light guide 31 having a sensor 33 for detecting the light amount of the ultraviolet lamp 8 and a light guide 35A at the tip 35 and guiding the light from the ultraviolet lamp 8 to the sensor 33. The light guide part 35A of the light guide 31 is provided so as to be freely directed to each of the ultraviolet lamps 8 or the light guide 31 is provided for each ultraviolet lamp 8. According to this configuration, the light amounts of the plurality of ultraviolet lamps 8 can be individually taken in by at least one light guide 31 arranged in the processing tank 2.

  Further, according to the embodiment to which the present invention is applied, the light guide 31 is disposed at a position where the light guide 35 </ b> A is not hidden behind at least the drive shaft 23. According to this configuration, it is possible to individually detect the light amounts of the plurality of ultraviolet lamps 8 by guiding the ultraviolet rays from each of the plurality of ultraviolet lamps 8 to the light guide 31.

  Further, according to the embodiment to which the present invention is applied, since the sensor 33 is provided for each light guide 31, ultraviolet rays incident on each light guide 31 are transmitted to the sensor 33 provided for each light guide 31. Can be introduced. Thereby, the incident light L is not introduced into the single sensor 33 from the plurality of light guides 31 at the same time. Therefore, it is possible to individually detect the light amounts of the plurality of ultraviolet lamps 8 without using a complicated arithmetic system.

  Further, according to the embodiment to which the present invention is applied, the light guide 31 that guides the light amount of the ultraviolet lamp 8 to the sensor 33 can be switched. According to this configuration, the light guide unit 35 </ b> A guides the light amount of the ultraviolet lamp 8 to the sensor 33 in the configuration in which the plurality of light guides 31 facing the corresponding ultraviolet lamp 8 are provided for each ultraviolet lamp 8. The body 31 can be switched. Therefore, it is possible to individually detect the light amounts of the plurality of ultraviolet lamps 8 by the sensor 33 by guiding the ultraviolet rays from each of the plurality of ultraviolet lamps 8 to the corresponding light guides 31.

  Further, according to the embodiment to which the present invention is applied, the deterioration of each ultraviolet lamp 8 is determined based on the degree of decrease in the light quantity of the ultraviolet lamp 8 detected by the sensor 33. According to this configuration, even if the distance between the light guide 31 and each ultraviolet lamp 8 is different for each ultraviolet lamp 8, it is possible to individually determine the deterioration of the plurality of ultraviolet lamps 8.

In addition, the said embodiment is only an example of the specific aspect to which this invention is applied, This invention is not limited, It is also possible to apply this invention as an aspect different from the said embodiment. For example, in the said embodiment, although the processing tank 2 was formed in the cylindrical shape, the structure which is not restricted to this but a polygonal column shape may be sufficient.
Moreover, in the said embodiment, although the example which sets the process target of the fluid processing apparatus 1 as purified water was demonstrated, not only this but the ultraviolet ray lamp 8 was provided in the processing tank 2, and a to-be-processed fluid was contained in this processing tank 2. The present invention can be applied to any apparatus as long as the apparatus is moved and sterilized. Moreover, it can apply to the fluid in general as a to-be-processed fluid, and can apply to gases, such as air other than liquids, such as water.

DESCRIPTION OF SYMBOLS 1 Fluid processing apparatus 2 Processing tank 8 Ultraviolet lamp 9 Lamp sleeve (protection tube)
DESCRIPTION OF SYMBOLS 20 Cleaning mechanism 23 Drive shaft 25 Cleaning plate 30 Ultraviolet detection mechanism 31 Light guide 33 Sensor 34 Rotation mechanism 35A Light guide part (light introduction part)
35B Light guiding part (light introducing part)
35C Light guide part (light introduction part)
C Center axis (center)

Claims (5)

A treatment tank in which a fluid to be treated circulates, a plurality of ultraviolet lamps housed around the center of the treatment tank, and a cleaning tube in which the ultraviolet lamps are respectively inserted to reciprocate and clean the surface of the protection tube A fluid processing apparatus comprising: a cleaning mechanism having a cleaning plate drive shaft at the center of the processing tank;
A sensor for detecting the light quantity of the ultraviolet lamp;
A light introduction part at a tip part, and comprising at least one light guide for guiding the light of the ultraviolet lamp to the sensor,
The fluid processing apparatus, wherein the light introducing portion of the light guide is provided so as to be freely directed to each of the ultraviolet lamps, or the light guide is provided for each of the ultraviolet lamps.   The fluid processing apparatus according to claim 1, wherein the light guide is disposed at a position where the light introducing portion is not hidden behind at least the drive shaft.   The fluid processing apparatus according to claim 1, wherein the sensor is provided for each light guide.   The fluid processing apparatus according to claim 1, wherein the light guide that guides the light amount of the ultraviolet lamp can be switched to the sensor.   5. The fluid processing apparatus according to claim 1, wherein deterioration of each lamp is determined based on a degree of reduction in light quantity of the ultraviolet lamp detected by the sensor.

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