JP2009112943A - Ultraviolet sterilizing device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an ultraviolet sterilizing device that has a measurement sensor and an ultraviolet lamp which are stored in the same quartz tube, that can therefore correctly measure the irradiation amount of ultraviolet light by simple constitution, and further can prevent the failure of the measurement sensor. <P>SOLUTION: The ultraviolet lamp 16 is inserted into a quartz tube 12 and is arranged inside casing 1, and the axial length of the ultraviolet lamp 16 inserted into the quartz tube 12 is made shorter than the axial length of the quartz tube 12. In a state where the ultraviolet lamp 16 is inserted into the quartz tube 12, a sensor mounting part 38 mounted with the measurement sensor 37 measuring the intensity of ultraviolet light in the ultraviolet lamp 16 is formed in one end direction of the quartz tube 12. The quartz tubes 12 each provided with the sensor mounting part 38 are arranged at least by two pieces in such a manner that the sensor mounting parts 38 are disposed in directions opposite from each other in the axial direction. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to an ultraviolet sterilization device for sterilizing a final treatment solution obtained by purifying factory waste water, domestic waste water, river water, etc. by various purification devices by irradiating ultraviolet rays, and accurately measures ultraviolet rays emitted from an ultraviolet lamp. It is something to manage.

  Conventionally, as a means for sterilizing a liquid to be treated by irradiating it with ultraviolet rays, a quartz tube containing an ultraviolet lamp is disposed in the casing, and the ultraviolet rays emitted from the ultraviolet lamp are circulated through the casing to be treated. An ultraviolet sterilizer for sterilizing a liquid to be processed by irradiating the liquid to be processed is known.

  In such an ultraviolet sterilizer, the ultraviolet irradiation amount decreases due to the deterioration of the ultraviolet lamp over time, and the ultraviolet lamp must be replaced in accordance with the decrease in the irradiation amount. Therefore, as shown in Patent Documents 1 and 2, an ultraviolet sterilizer provided with a measurement sensor for measuring the intensity of ultraviolet rays emitted from an ultraviolet lamp is known.

  In the apparatus of Patent Document 1, two measurement sensors are arranged on the outer peripheral side surface of a casing into which a quartz tube is inserted via a quartz glass plate. Further, the device of Patent Document 2 has a quartz glass protective tube inserted and arranged in the center of the casing, and a measurement sensor is inserted and arranged in the protective tube, so that the ultraviolet rays of the ultraviolet lamp arranged in the casing can be reduced. Measuring.

JP-A-10-57954 JP 2007-155546 A

  However, in the devices of Patent Documents 1 and 2, when the quartz glass plate or the protective tube is cooled by the liquid to be treated in the casing, the surface condenses, and the measurement sensor measures ultraviolet rays through this condensation. For this reason, the transmittance of the quartz glass plate and the protective tube is lowered, and it is difficult to accurately measure the intensity of ultraviolet rays emitted from the ultraviolet lamp. Moreover, there is a possibility that the measurement sensor may break down due to the condensed water droplets adhering to the measurement sensor. In addition, a quartz glass plate and a protective tube for protecting the measurement sensor have to be formed separately from the quartz tube, and the manufacturing process of the device has become complicated.

  Accordingly, the present invention is intended to solve the above-described problems, and enables ultraviolet ray sterilization that enables accurate measurement of the amount of ultraviolet irradiation with a simple configuration and can prevent the measurement sensor from failing. I want to get a device.

  In order to solve the problems of the prior art as described above, the present invention inserts a quartz tube into a casing provided with an inlet and an outlet for a liquid to be processed, and ultraviolet rays for sterilizing the liquid to be processed in the quartz tube. A lamp is inserted, and the axial length of the ultraviolet lamp is shorter than the axial length of the quartz tube. Further, a sensor mounting portion is formed in which a measurement sensor for measuring the ultraviolet intensity of the ultraviolet lamp is mounted in one direction of the quartz tube with the ultraviolet lamp inserted into the quartz tube.

  The inner surface of the quartz tube is kept at a constant temperature by the heat generated by the ultraviolet lamp, and does not cloud due to condensation. Therefore, if the sensor mounting part is formed inside the quartz tube together with the ultraviolet lamp as described above, the ultraviolet rays emitted from the ultraviolet lamp housed in one quartz tube are reliably irradiated to the measurement sensor housed in the other quartz tube, With the other quartz tube measurement sensor, it is possible to always accurately measure the intensity of ultraviolet rays emitted from the ultraviolet lamp housed in the one quartz tube. At the same time, the ultraviolet rays of the ultraviolet lamps of the other quartz tubes are measured by the measuring sensor of one quartz tube. Further, since the measurement sensor is protected by the quartz tube, it is not necessary to separately prepare a member for protecting the measurement sensor, and the apparatus can be manufactured easily and inexpensively.

  Further, as described above, when the sensor mounting portion is provided in the one end direction of one quartz tube, the ultraviolet lamp and the sensor mounting portion are arranged on the same axis in the quartz tube, and the same quartz tube is used by the measurement sensor. It is difficult to measure the irradiation intensity of the ultraviolet lamp housed in the housing. Therefore, as described above, at least two quartz tubes each provided with a sensor mounting portion on one end side are disposed in parallel in the casing, and the sensor mounting portions are disposed in opposite directions in the axial direction. By forming in this way, a measurement sensor housed in one quartz tube cannot measure the irradiation intensity of an ultraviolet lamp housed in the same quartz tube, but a measurement sensor housed in another quartz tube The irradiation intensity of the ultraviolet lamp housed in the one quartz tube can be reliably measured. At the same time, the ultraviolet rays from the other ultraviolet lamps in the quartz tube are measured by a measuring sensor in one quartz tube. Therefore, it is possible to accurately measure the irradiation intensity.

  Further, the measurement sensor may be disposed in a resin guide holder and disposed in the sensor mounting portion of the quartz tube via the guide holder. If the measurement sensor is arranged in the quartz tube by the guide holder in this way, the measurement sensor can be easily installed, and the ultraviolet rays can be accurately measured by the measurement sensor. Further, if the guide holder is made of resin, there is no possibility that the inner surface of the quartz tube is damaged by the outer peripheral surface of the guide holder.

  Further, the guide holder is provided with a sensor fixing portion that fixes the measurement sensor at one end, passes through the insertion hole of the fiber cable that transmits the signal of the measurement sensor to the measurement portion, and projects the other end out of the casing. A holder main body provided with a fitting flange for fitting the fixing portion may be formed. Further, the abutting portion of the ultraviolet lamp may be supported and arranged by a support rod through the fixing portion of the holder main body and the arrangement interval of the measurement sensor. By forming in this way, it is possible to place the abutting portion against the tip of the ultraviolet lamp and place the ultraviolet lamp in the quartz tube in a fixed position without being slidable.

  Further, the guide holder may be made of a fluorine-based resin to reduce deterioration due to ultraviolet rays.

  In addition, the quartz tubes arranged in the casing have the same axial length, and in the case where no measurement sensor is arranged, an ultraviolet lamp may be arranged at the center of the axial length of the quartz tube. good. By forming in this way, it becomes possible to accurately measure the ultraviolet rays from the ultraviolet lamps arranged in the quartz tubes where no measurement sensor is arranged, by the measurement sensors arranged in other quartz tubes.

  In the present invention, as described above, the sensor mounting portion is formed in one end direction inside the quartz tube. The inner surface of the quartz tube is kept at a constant temperature by the heat generated by the ultraviolet lamp, and does not cloud due to condensation. For this reason, it is possible to always accurately measure the intensity of ultraviolet rays emitted from the ultraviolet lamp by the measurement sensor. At the same time, the ultraviolet rays of the ultraviolet lamps of the other quartz tubes are measured by the measuring sensor of one quartz tube. Further, the measurement sensor is protected by a quartz tube, and it is not necessary to separately prepare a member for protecting the measurement sensor, and the apparatus can be manufactured easily and inexpensively.

  Further, at least two quartz tubes provided with the sensor mounting portion are arranged in the casing in parallel, and the sensor mounting portions are arranged in the opposite directions in the axial direction. By arranging in this way, the measurement sensor housed in one quartz tube cannot measure the irradiation intensity of an ultraviolet lamp housed in the same quartz tube, but the measurement sensor housed in another quartz tube The irradiation intensity of the ultraviolet lamp housed in the one quartz tube can be reliably measured. At the same time, the ultraviolet rays from the other ultraviolet lamps in the quartz tube are measured by a measuring sensor in one quartz tube. Therefore, it is possible to accurately measure the irradiation intensity.

  In the following, Embodiment 1 of the present invention will be described with reference to FIGS. 1 to 14. Reference numeral (1) denotes a casing, which is formed by fixing and projecting flanges (3) at both ends of a cylindrical body (2). The lid (4) is fixed to the flange (3). In addition, on the side surface of the casing (1), there are an inlet (5) and an outlet (6) for a liquid to be treated, which is a final treatment liquid obtained by purifying factory wastewater, domestic wastewater, river water, and the like by various purification means. Each is formed into a pipe shape. In the present embodiment, as shown in FIGS. 3 and 4, the casing (1) is used horizontally. Further, the casing (1) is configured to store the liquid to be processed and to have sufficient strength for performing the sterilization treatment.

  In the casing (1), a drive shaft (7) that moves forward and backward by the cylinder mechanism (9) is inserted in the horizontal direction at the axis of the casing (1). 3 shows a state in which the drive shaft (7) has moved most toward the cylinder mechanism (9), and FIG. 4 shows a state in which the drive shaft (7) has been inserted and moved most into the casing (1).

  Further, on the outer periphery of the drive shaft (7), a central portion of a substantially circular wiper blade (8) obtained by punching a flat plate by pressing or the like is provided with bolts (through a fixed cylinder (10) as shown in FIG. 11). As shown in FIG. 8, eight wiper blades (8) are fixed perpendicularly to the axial direction of the drive shaft (7) at eight intervals in the axial direction of the drive shaft (7). The moving distance of the drive shaft (7) is longer than the installation interval of the wiper blade (8).

  Further, the wiper blade (8) has three insertion holes (13) for inserting the quartz tubes (12) at equal intervals in the radial direction as shown in FIG. Three through holes (15) for inserting a guide shaft (14) to be described later are opened at intervals. Then, the insertion ports (13) and the through-holes (15) of all wiper blades (8) fixed at regular intervals in the axial direction of the drive shaft (7) are arranged on the same axis.

  Further, the drive shaft (7) is formed in a square cross section, and passes through the insertion hole (17) at the center of the wiper blade (8) formed in the same square as shown in FIG. By thus forming the drive shaft (7) and the insertion hole (17) in a square shape, the insertion port (13) and the through-hole of the eight wiper blades (8) fixed in the axial direction of the drive shaft (7). Positioning to arrange (15) on the same axis becomes easy.

  Further, three quartz tubes (12) coated with ultraviolet lamps (16) are inserted into the insertion port (13) one by one, and both ends of the quartz tube (12) are shown in FIG. In this way, it is fixed to the lid (4) of the casing (1). Then, by irradiating the liquid to be processed flowing outside the quartz tube (12) with the ultraviolet rays emitted from the ultraviolet lamp (16), the liquid to be processed can be sterilized. Further, as shown in FIG. 5, the insertion openings (13) are formed at equal intervals in the outer circumferential direction of the wiper blade (8). Hereinafter, in the present specification, for convenience of explanation, two of the three quartz tubes (12) inserted through the lower insertion port (13) in FIG. 12a), the second quartz tube (12b), and the one inserted through the upper insertion port (13) is the third quartz tube (12c).

  Further, as shown in FIG. 1, the ultraviolet lamp (16) has an axial length shorter than the axial length of the quartz tube (12). The ultraviolet lamps (16) housed in the first quartz tube (12a), the second quartz tube (12b), and the third quartz tube (12c) all have the same axial length. As shown in FIG. 1, the first quartz tube (12a) and the second quartz tube (12b) are provided with a measurement sensor (for measuring the ultraviolet intensity of the ultraviolet lamp (16) in one end direction of the quartz tube (12)). 37) is attached to the sensor mounting portion (38). Hereinafter, in this specification, the measurement sensor (37) housed in the first quartz tube (12a) is taken as the first measurement sensor (37a) and the measurement sensor (37) housed in the second quartz tube (12b). The second measurement sensor (37b) is used. The third quartz tube (12c) is not provided with a sensor mounting portion (38).

  Since the inner surface of the quartz tube (12) is kept at a constant temperature by the heat generated by the ultraviolet lamp (16) and does not cloud due to condensation, the sensor mounting portion (38) is placed inside the quartz tube (12) as described above. The ultraviolet rays from the ultraviolet lamp (16) built in the second quartz tube (12b) and the third quartz tube (12c) are provided in the first quartz tube (12a) without being blocked. It reaches the first measurement sensor (37a). Similarly, the second measurement sensor provided in the second quartz tube (12b) without blocking the ultraviolet rays from the ultraviolet lamp (16) built in the first quartz tube (12a) and the third quartz tube (12c). (37b). Therefore, the intensity of the ultraviolet rays emitted from the ultraviolet lamp (16) can always be accurately measured by the measurement sensor (37). Further, the measurement sensor (37) is protected by the quartz tube (12), and it is not necessary to separately arrange a member for protecting the measurement sensor (37), and the apparatus can be manufactured easily and inexpensively.

  In this embodiment, as described above, an ultraviolet lamp (16) and a measurement sensor (37) are provided in one quartz tube (12), and the ultraviolet lamp (16) and the measurement sensor (37). Are arranged on the same axis. Therefore, it is difficult for the measurement sensor (37) to measure the irradiation intensity of the ultraviolet lamp (16) housed in the same quartz tube (12). That is, it is difficult to measure the irradiation intensity of the ultraviolet lamp (16) housed in the first quartz tube (12a) by the first measurement sensor (37a), and the second measurement sensor (37b) performs the second measurement. It is difficult to measure the irradiation intensity of the ultraviolet lamp (16) housed in the quartz tube (12b).

  Therefore, as shown in FIG. 1, the sensor mounting portion (38) of the first quartz tube (12a) provided with the first measurement sensor (37a) and the second quartz tube (12b) provided with the second measurement sensor (37b). ) Is mounted in the opposite direction in the axial direction in the casing (1). By arranging in this way, the irradiation intensity of the ultraviolet lamp (16) of the first quartz tube (12a) and the third quartz tube (12c) can be accurately measured by the second measurement sensor (37b). Moreover, the irradiation intensity of the ultraviolet lamp (16) of the second quartz tube (12b) and the third quartz tube (12c) can be accurately measured by the first measurement sensor (37a). Thus, since the measurement sensor (37) accommodated in one quartz tube (12) can reliably measure the irradiation intensity of the ultraviolet lamp (16) accommodated in the other quartz tube (12). The irradiation intensity of the ultraviolet lamps (16) other than the ultraviolet lamp (16) housed in the same quartz tube (12) is measured by the measurement sensor (37) housed in one quartz tube (12) as described above. It becomes possible to measure accurately.

  Further, in the third quartz tube (12c) in which the measurement sensor (37) is not disposed as described above, as shown in FIG. 1, an ultraviolet lamp ( 16) is arranged.

  Further, the measurement sensor (37) is arranged in a guide holder (42) formed of a fluororesin as shown in FIG. 2, and the sensor mounting portion (12) of the quartz tube (12) is inserted through the guide holder (42). 38). If the measurement sensor (37) is arranged in the quartz tube (12) by the guide holder (42) in this way, the measurement sensor (37) can be easily installed, and the measurement sensor (37) accurately measures the ultraviolet rays. be able to. Further, if the guide holder (42) is formed of resin as described above, there is no possibility of damaging the inner surface of the quartz tube (12) with the outer peripheral surface of the guide holder (42). Furthermore, if the guide holder (42) is made of a fluorine-based resin, deterioration of the guide holder (42) due to ultraviolet rays can be reduced.

  Further, as shown in FIG. 2, the guide holder (42) has a holder main body (44) provided with a sensor fixing portion (43), and an arrangement interval between the holder main body (44) and the measurement sensor (37). It is formed by the abutting portion (46) of the ultraviolet lamp (16) supported by the support rod (45). By forming in this way, the abutting portion (46) is abutted against the tip of the ultraviolet lamp (16), and the ultraviolet lamp (16) is fixed in a non-slidable position in the quartz tube (12). Is possible.

  The holder body (44) is provided with a sensor fixing portion (43) for fixing the measurement sensor (37) at one end and the other end protruding outside the lid (4) of the casing (1). Further, a fitting flange (47) for fitting the sensor fixing portion (43) to the casing (1) is provided. Moreover, the insertion hole (50) of the fiber cable (48) which transmits the signal of the said measurement sensor (37) to a measurement part (not shown) is penetrated from the one end side to the other end side.

  Further, a guide bush (18) is inserted and arranged inside the insertion opening (13) of the wiper blade (8) as shown in FIG. As shown in FIGS. 9 and 10, the guide bush (18) is formed in a cylindrical shape by providing a flange (19) on the outer periphery of the opening on one end side.

  Further, a ring-shaped wiper ring (20) is arranged on the flange (19) side of the guide bush (18) as shown in FIG. 7, and the wiper ring (20) is slid on the outer periphery of the quartz tube (12). The wiper ring (20) and the guide bush (18) are inserted and arranged by being movably sandwiched between the insertion opening (13) of the wiper blade (8) by the insertion guide (21). ing. The guide bush (18) and the wiper ring (20) are made of a fluorine-based resin so as to prevent deterioration due to ultraviolet rays and not damage the outer peripheral surface of the quartz tube (12).

  Further, as described above, the wiper ring (20) has an inner periphery that is in close contact with the outer periphery of the quartz tube (12), so that the wiper ring (20) is moved to the quartz tube (with the horizontal movement of the drive shaft (7)). It slides in close contact with the outer peripheral surface of 12), and the outer peripheral surface of the quartz tube (12) can be cleaned. As described above, since the moving distance of the drive shaft (7) is longer than the installation interval of the wiper blade (8), the wiper ring (20) cleans the outer peripheral surface of the quartz tube (12) without wiping away. It becomes possible to do.

  Further, as shown in FIGS. 11 and 12, the wiper ring (20) has a V-shaped inner peripheral surface, reduces frictional resistance with the outer peripheral surface of the quartz tube (12), and smoothly advances and retracts. It is supposed to be. Even if there is a step error that the outer diameter of the quartz tube (12) is slightly larger than the inner diameter of the wiper ring (20), the V-shaped portion is elastically deformed outward. The quartz tube (12) can be easily inserted into the wiper ring (20).

  The wiper ring (20) forms a movable interval (22) between the inner surface of the insertion guide (21) as shown in FIG. Therefore, various dimensional errors generated in the drive shaft (7) and the wiper blade (8) can be absorbed by the wiper ring (20) moving within the movable interval (22). Therefore, even if the horizontal axis of the drive shaft (7) is displaced or the outer diameter of the quartz tube (12) is slightly uneven, the quartz tube (12) may be distorted or damaged, or other members may be damaged. There is no fear that it will occur, and the quartz tube (12) can be cleaned smoothly and reliably by the wiper ring (20).

  Further, as shown in FIG. 7, the guide bush (18) made of fluorine resin has an inner diameter larger than the outer diameter of the quartz tube (12) and an inner diameter of the metal insertion guide (21). And smaller than the inner diameter of the insertion port (13). Therefore, even when the wiper ring (20) is worn due to the cleaning operation of the quartz tube (12), this resin is used before the quartz tube (12) comes into contact with the metal insertion guide (21) and the wiper blade (8). It comes into contact with the made guide bush (18), and it is possible to prevent the quartz tube (12) from coming into contact with the metal and being damaged.

  Further, a total of three guide shafts (14) are inserted through the through hole (15) of the wiper blade (8) one by one through a guide holder (23) as shown in FIG. Then, both ends of the guide shaft (14) are fixed to the lids (4) at both ends of the casing (1) as shown in FIGS. 3 and 4, thereby moving the wiper blade (8) according to the guide holder (23). It is possible. By fixing the guide shaft (14) inserted through the wiper blade (8) in this manner to the lids (4) at both ends of the casing (1), the drive shaft (7), wiper blade (8), insertion guide ( 21) and the like can be received by the casing (1) through the guide shaft (14). For this reason, the load applied to the quartz tube (12) can be made zero or very small, and the quartz tube (12) can be prevented from being distorted or broken. Further, if stress is applied to both ends of the guide shaft (14), that is, the extending direction by tightening both ends of the guide shaft (14) to the lid (4) with nuts (33) or the like, the guide shaft (14) It is possible to further improve the linearity of the quartz tube 12 and prevent a load from being applied to the quartz tube 12.

  Further, the connection between the drive shaft (7) and the cylinder mechanism (9) is made of a metal bearing (one end of the drive shaft (7) fixed to the lid (4) of the casing (1) as shown in FIG. 24) projecting to the outside of the casing (1) via a cylinder rod (27) of the cylinder mechanism (9) via a universal joint (26). Thus, by connecting the cylinder mechanism (9) and the drive shaft (7) via the universal joint (26), a displacement occurs in the axial direction in which the cylinder rod (27) of the cylinder mechanism (9) moves horizontally. Even in this case, since the universal joint (26) absorbs this deviation, the horizontal movement of the drive shaft (7) is stabilized without affecting the horizontal movement of the drive shaft (7). It becomes possible to do.

  Further, as described above, one end of the drive shaft (7) is connected to the bearing (24). By connecting with the bearing (24) in this way, the forward / backward movement of the drive shaft (7) can be made smoother without any blurring. In the present embodiment, as shown in FIG. 14, a slide bearing (25) is used as the bearing (24). By using the slide bearing (25) in this way, it becomes possible to ensure horizontal movement of the drive shaft (7) without blurring.

  Further, as shown in FIG. 12, an annular seal material (28) having a U-shaped cross section is provided at the end of the inner peripheral surface of the slide bearing (25) on the lid (4) side, and a U-shaped opening. Is placed facing the liquid to be treated in the casing (1). When the sealing material (28) receives water pressure from the liquid to be treated in the casing (1), both ends of the U-shape are expanded outward, and the expanded both ends are driven shaft (7). And the inner peripheral surface of the slide bearing (25). Therefore, it is possible to prevent the liquid to be treated from leaking outside the casing (1) even at high water pressure.

  The sliding bearing (25) has a contact surface with the driving shaft (7) formed of a resin member (30) as shown in FIG. 12, and the driving shaft (7) is made of a metal sliding bearing (25). To prevent direct contact with wear. The resin member (30) has an annular groove (31) in the circumferential direction on both sides of the inner surface. By forming the annular groove (31) in this way, burrs generated due to wear of the contact between the sliding bearing (25) and the drive shaft (7) and foreign matters mixed during operation are removed from the annular groove ( 31) so that the burr and foreign matter may enter between the drive shaft (7) and the slide bearing (25) and the forward and backward movement of the drive shaft (7) is not disabled. Smooth horizontal movement is possible.

  In this embodiment, an electric cylinder (32) is used as a cylinder mechanism (9) for moving the drive shaft (7) forward and backward, and a ball screw (not shown) is provided by an electric motor (not shown). And the drive shaft (7) can be moved back and forth in the horizontal direction. The cylinder mechanism (9) only needs to be able to advance and retract the drive shaft (7) in the horizontal direction. For example, a hydraulic cylinder or an air cylinder can be used. The drive shaft (7) is advanced and retracted by the cylinder mechanism (9) provided outside the casing (1) as described above, so that the wiper blade (8) is provided as in the case where the ball screw mechanism is provided in the casing (1). Therefore, it is possible to prevent the quartz tube (12) from being broken by suppressing the load applied to the quartz tube (12).

  Further, since the drive shaft (7) and the wiper blade (8) are integrally moved horizontally by the cylinder device (9), there is no movement relationship between the wiper blade (8) and the drive shaft (7). For this reason, there is no fear that gravel or dust will enter the connecting portion as in the case of using a ball screw, causing the wiper blade (8) to tilt in the forward / backward direction, or causing the wiper blade (8) to be unable to move. ) Can be prevented, and the quartz tube (12) can be cleaned smoothly and reliably. In this embodiment, the apparatus comprising the casing (1), the quartz tube (12) and the like is set horizontally, but it is of course possible to use it as a vertical position.

The top view which shows arrangement | positioning of a quartz tube. The expanded sectional view of a sensor mounting part. The front view which shows the state which the drive shaft moved to the electric cylinder side. The front view which shows the state which the drive shaft moved to the in-cylinder direction. The top view of a wiper blade. The expanded sectional view of the connection part of a wiper blade, a quartz tube, a drive shaft, and a guide shaft. The expanded sectional view of the connection part of a wiper blade and a quartz tube. The partial enlarged front view of the drive shaft which fixed the wiper blade. The front view of a guide bush. FIG. 10 is a cross-sectional view taken along line AA in FIG. 9. The front view of a wiper ring. BB sectional drawing of FIG. The elements on larger scale of the connection part of an electric cylinder and a casing. The expanded sectional view of the bearing part of a drive shaft.

Explanation of symbols

1 Casing 5 Inlet
6 Outlet
12 Quartz tube
16 UV lamp
37 Measuring sensor
38 Sensor mounting part
42 Guide holder
43 Sensor fixing part
44 Holder body 46 Abutting portion 47 Fitting flange
48 Fiber cable
50 insertion hole

Claims (5)

  In the casing provided with the inlet and outlet for the liquid to be processed, an ultraviolet lamp for sterilizing the liquid to be processed is inserted into the quartz tube, and the axial length of the ultraviolet lamp inserted into the quartz tube is set. This sensor is formed shorter than the length of the quartz tube in the axial direction, and a sensor mounting portion is formed in which a measurement sensor for measuring the ultraviolet intensity of the ultraviolet lamp is attached to one end of the quartz tube with the ultraviolet lamp inserted into the quartz tube. An ultraviolet sterilizer characterized in that at least two quartz tubes provided with mounting parts are arranged in the casing in parallel, and the sensor mounting parts are arranged in the opposite direction in the axial direction.   2. The ultraviolet sterilizer according to claim 1, wherein the measurement sensor is disposed in a resin guide holder, and is disposed in the sensor mounting portion of the quartz tube through the guide holder.   The guide holder is provided with a sensor fixing portion that fixes a measurement sensor at one end, passes through a fiber cable insertion hole that transmits a signal of the measurement sensor to the measurement portion, and projects the other end out of the casing. A holder main body provided with a fitting flange for fitting the sensor, and the abutting portion of the ultraviolet lamp is arranged by a support rod through the arrangement interval of the sensor fixing portion of the holder main body and the measurement sensor. The ultraviolet sterilizer according to claim 2.   The ultraviolet sterilizer according to claim 2, wherein the guide holder is made of a fluorine resin.   The quartz tubes arranged in the casing have the same axial length, and in the case where no measurement sensor is arranged, an ultraviolet lamp is arranged at the center of the axial length of the quartz tube. The ultraviolet sterilizer according to claim 1.

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