JP2017075883A - Washing apparatus, and washing method for immersion type detectors - Google Patents

Abstract

PROBLEM TO BE SOLVED: To enable detecting units to be effectively washed by additional equipment of only a limited scale.SOLUTION: A washing apparatus 20 is equipped with a nozzle 22 arranged in a water sample 1A to be measured, a tank 25 communicating with the nozzle 22 and a discharging means controller 36 for controlling discharging means 34. The nozzle 22 opens toward the detecting unit 12 of an immersion type detector 10 immersed in the water sample 1A. The tank 25 stores part of the water sample 1A as washing water 1B via the nozzle 22 for instance. The discharging means 34 removes smear sticking to the detector 12 by discharging the washing water 1B in the tank 25 from the nozzle 22 toward the detector 12.SELECTED DRAWING: Figure 1A

Description

  The present invention relates to a cleaning device and a cleaning method for an immersion detector.

  In sewage treatment plants and wastewater treatment facilities in factories, an immersion detector is immersed in water to be measured (sample water), and the quality of the sample water is detected by the immersion detector. This immersion detector includes a dissolved oxygen meter that detects oxygen dissolved in water, a pH meter that detects the pH (hydrogen ion index) of water, an ORP meter that detects ORP (oxidation-reduction potential), and turbidity A turbidity meter for detecting the degree of turbidity, an MLSS meter for detecting suspended solids in the sludge mixture, and the like. However, the detection performance and detection accuracy of the submerged detector deteriorates when dirt such as a suspension in the sample water or microorganisms adheres to the detection unit.

  Patent Documents 1 and 2 disclose a cleaning device that removes dirt from a detection unit of an immersion detector. The cleaning device of Patent Document 1 includes a nozzle attached in the vicinity of the immersion detector, and a pump and a tank for discharging compressed air from the nozzle. By discharging compressed air from the nozzle to the detection unit of the submerged detector, dirt on the detection unit is removed by the foaming effect. The cleaning device of Patent Literature 2 removes dirt from the detection unit by discharging cleaning water to the detection unit of the immersion detector.

Japanese Patent No. 4787027 Japanese Patent Laid-Open No. 52-60691

  However, in the cleaning apparatus using compressed air of Patent Document 1, a sufficient cleaning effect may not be obtained depending on the property of dirt. Further, the cleaning device using the cleaning water of Patent Document 2 has a higher cleaning effect than the cleaning device of Patent Document 1. However, it is necessary to install a pipe from the water source of the cleaning water to the cleaning device (tank), and further to the vicinity of the immersion detector in the sample water.

  It is an object of the present invention to provide a cleaning device and a cleaning method for an immersion detector that can effectively clean the detection unit with as few additional equipment as possible.

  The present invention is disposed in the sample water to be measured, and is communicated with the nozzle that opens toward the detection unit of the immersion type detector immersed in the sample water, A tank for storing a part of the sample water as cleaning water; and a discharge means that communicates with the tank and discharges the cleaning water in the tank from the nozzle toward the detection unit; and There is provided a cleaning device for an immersion type detector, comprising: a discharge means control unit that controls and removes dirt adhered to the detection unit of the immersion type detector.

  This cleaning device discharges cleaning water to the detection unit of the immersion type detector, thereby removing dirt attached to the detection unit, so that the cleaning effect can be enhanced. In addition, since the wash water is a part of the sample water to be measured and there is no need to lay a dedicated pipe from a remote water source to the tank, it is possible to reduce the cost increase related to the piping work. Further, by selecting the shape of the nozzle opening (discharge port), the discharge capacity of the discharge means, and the volume of the tank according to the level of dirt in the detection unit, a cleaning device having an effective cleaning power can be realized.

  The discharge means is an air pump or a compressor that discharges compressed air, and the discharge means control section discharges the compressed air by the discharge means so that the washing water in the tank is discharged from the nozzle to the detection section. Then, compressed air is discharged from the nozzle to the detection unit via the tank. According to this aspect, stains with different properties attached to the detection unit can be reliably removed by the cleaning effect of the cleaning water and the foaming effect of the compressed air.

  A switching valve that can be switched between a discharge position for preventing the sample water from entering the tank and a suction position for allowing the sample water to enter the tank is provided. According to this aspect, since the sample water is prevented from entering at the discharge position, the cleaning water can be discharged at a pressure set by the discharge means.

  Specifically, the switching valve has a first connection part connected to the tank, a second connection part connected to the discharge means, and a third connection part opened to the atmosphere. A three-way valve that can be switched by a valve control unit between a discharge position where the first connection part and the second connection part communicate with each other and a suction position where the first connection part and the third connection part communicate with each other. is there. According to this aspect, since the tank and the discharge means communicate with each other by setting the discharge position, the cleaning water in the tank can be discharged reliably. Further, since the tank and the atmosphere communicate with each other by setting the suction position, the sample water can be stored in the tank as cleaning water through the nozzle due to a pressure difference between the sample water and the atmosphere. That is, since cleaning water can be stored in the tank without using a pump or the like, the cost of the cleaning device can be reduced. Further, by setting the discharge position when cleaning and the suction position when cleaning is stopped, the sample water can be stored in the tank as cleaning water until the next cleaning is started, so that convenience can be improved.

  Water supply means for storing the sample water in the tank is provided. According to this aspect, since a desired amount of sample water can be stored in the tank as washing water when desired, convenience can be improved.

  In addition, the method for cleaning the immersion detector is to store a part of the sample water to be measured in the tank as cleaning water, and to wash the inside of the tank in the detection unit of the immersion detector immersed in the sample water. By discharging water by a discharge means, the dirt adhering to the detection part of the immersion type detector is removed. In this cleaning method, by discharging compressed air from the discharge unit, the cleaning water in the tank is discharged to the detection unit, and then the detection unit is allowed to discharge compressed air through the tank. preferable.

  In the present invention, a portion of the sample water to be measured is stored in the tank as cleaning water, and the cleaning water in the tank is discharged to the detection unit of the immersion detector by the discharge means, so that the dirt attached to the detection unit is removed. Since it is removed, the cleaning effect can be enhanced. Moreover, since it is not necessary to lay dedicated piping from a remote water source to the tank, additional equipment can be suppressed as much as possible, and the cost increase related to piping work can be reduced.

Schematic which shows the suction state of the washing | cleaning apparatus of the immersion type detector of 1st Embodiment. Schematic which shows the discharge state of the washing | cleaning apparatus of FIG. 1A. Schematic which shows the relationship between the detection part of an immersion type detector, and the nozzle of a washing | cleaning apparatus. The time chart which shows the relationship of control of an air pump, control of a three-way valve, and the amount of water in a tank. Schematic which shows the washing | cleaning apparatus of 2nd Embodiment. Schematic which shows the washing | cleaning apparatus of 3rd Embodiment. Schematic which shows the washing | cleaning apparatus of 4th Embodiment. Schematic which shows the washing | cleaning apparatus of 5th Embodiment. Schematic which shows the washing | cleaning apparatus of 6th Embodiment. Schematic which shows the washing | cleaning apparatus of 7th Embodiment. Schematic which shows the washing | cleaning apparatus of 8th Embodiment. Schematic which shows the washing | cleaning apparatus of 9th Embodiment. Schematic which shows the washing | cleaning apparatus of 10th Embodiment. Schematic which shows the washing | cleaning apparatus of 11th Embodiment. The graph which shows the measurement result of the conventional washing | cleaning apparatus by compressed air. The graph which shows the measurement result of the washing | cleaning apparatus of 1st Embodiment.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings.

(First embodiment)
1A and 1B show a cleaning device 20 for an immersion detector 10 according to a first embodiment of the present invention. This cleaning device 20 removes dirt adhering to the detection unit 12 by discharging (injecting) the cleaning water 1B to the detection unit 12 of the immersion detector 10 at a predetermined pressure. In the present embodiment, the detection unit 12 is effectively cleaned with a small amount of additional equipment by using the measurement target water (sample water) 1A as the cleaning water 1B.

(Details of immersion type detector)
The immersion type detector 10 is used in a sewage treatment plant or a waste water treatment facility of a factory, and is disposed in a state of being immersed in the sample water 1A, as in the past. The immersion detector 10 includes a substantially cylindrical casing 11. One end of the casing 11 is provided with a detection unit 12 that detects the quality of the sample water 1A. The immersion detector 10 is arranged in the vertical direction so that the end surface of the detection unit 12 extends in the horizontal direction, but may be arranged in the horizontal direction so that the end surface of the detection unit 12 extends in the vertical direction. The part 12 may be positioned downward and inclined at a predetermined angle, or the detection part 12 may be arranged in any direction regardless of the above, depending on the normality of the sample water 1A.

  The immersion detector 10 is a dissolved oxygen meter that detects, for example, oxygen dissolved in water. This dissolved oximeter is optical, and the detection film penetrated by the sample water 1A is irradiated with excitation light by the first light emitting element and reference light by the second light emitting element. Thereby, light according to the oxygen concentration around the detection film is generated, and the light concentration is detected by the light receiving element, thereby detecting the oxygen concentration of the sample water 1A. The light corresponding to the oxygen concentration has a longer emission time when the oxygen concentration is lower, and a shorter emission time when the oxygen concentration is higher. Therefore, the oxygen concentration can be detected by detecting the emission time. The immersion detector 10 is not limited to an optical dissolved oxygen meter, but a pH meter that detects the pH (hydrogen ion index) of water, an ORP meter that detects ORP (oxidation-reduction potential), and the degree of turbidity. It may be a turbidity meter, an MLSS meter that detects suspended solids in the sludge mixture, or the like.

  The immersion detector 10 is communicably connected to an output control unit 15 disposed outside (on the ground) of the sample water 1A. The immersion detector 10 and the output control unit 15 may be wired by a communication cable or may be wirelessly connected by wireless communication at a predetermined frequency. The output control unit 15 transmits an execution signal for executing water quality detection to the immersion detector 10. The output control unit 15 receives a measurement signal corresponding to the detection value detected by the immersion detector 10 and stores the detection value obtained by restoring the reception signal. Moreover, the output control part 15 is provided with the display part which displays the water quality measurement result based on the received detected value. The output control unit 15 can use a personal computer.

(Details of cleaning equipment)
The cleaning device 20 includes a nozzle 22 disposed in the vicinity of the detection unit 12, a tank 25 communicated with the nozzle 22, and an air pump 34 communicated with the tank 25. The cleaning device 20 includes a three-way valve 28 that is a switching valve between the tank 25 and the air pump 34. The tank 25 and the air pump 34 are communicated with each other through the three-way valve 28.

  The nozzle 22 is arranged in a state of being immersed in the sample water 1 </ b> A together with the immersion detector 10. As specifically shown in FIG. 2, the nozzle 22 is a cylindrical member (pipe) whose front end side (lower side in FIG. 2) is closed, and extends to the lower side of the detection unit 12. The nozzle 22 is provided with a discharge port 23 that opens toward the detection unit 12 on the tip side located below the detection unit 12. The discharge port 23 is provided at a position where the cleaning water 1 </ b> B and the compressed air accurately hit the detection unit 12. The discharge port 23 of the present embodiment is formed by an elongated slit that is cut out in a range of approximately 180 degrees. Further, the discharge port 23 is set so that the discharged cleaning water 1B and the compressed air collide with the inclination angle α (for example, 10 degrees) set with respect to the end surface of the detection unit 12. However, the discharge port 23 may be set so that the discharged cleaning water 1B and the compressed air collide with the end surface of the detection unit 12 in the orthogonal direction. The discharge port 23 has an opening area through which the external sample water 1A can flow in, and the nozzle 22 has an inner diameter through which the sample water 1A flows into the tank 25.

  As shown in FIGS. 1A and 1B, the tank 25 is arranged in the state of being immersed in the sample water 1 </ b> A together with the immersion detector 10, similarly to the nozzle 22. To the bottom wall of the tank 25, an end portion of the piping portion 24 opposite to the discharge port 23 of the nozzle 22 is connected. The tank 25 is disposed above the detection unit 12 (on the water surface side of the sample water 1A), and a part of the sample water 1A is stored as cleaning water 1B through the nozzle 22. A first pipe 26 is connected to the top wall of the tank 25, and the first pipe 26 is connected to a three-way valve 28. In addition, by connecting the nozzle 22 and the three-way valve 28 using the first pipe 26 having a large inner diameter, the first pipe 26 can have the function of the tank 25. In other words, the tank 25 may be configured to be able to accommodate the set capacity of the wash water 1B.

  The three-way valve 28 includes a first connection portion 29, a second connection portion 30, and a third connection portion 31, and is disposed on the ground, which is outside the sample water 1A. The first connection part 29 is connected to the tank 25 in the sample water 1 </ b> A via the first pipe 26. The second connection unit 30 is connected to the air pump 34 via the second pipe 32. The third connection part 31 is open to the atmosphere. The three-way valve 28 allows the first connection portion 29 and the third connection portion 31 to communicate with each other, the discharge position where the first connection portion 29 and the second connection portion 30 communicate with each other and the third connection portion 31 side is blocked. Thus, it is possible to switch to the suction position where the second connecting portion 30 side is shut off. At the suction position, the tank 25 and the atmosphere communicate with each other, thereby allowing the sample water 1 </ b> A to enter the tank 25 through the nozzle 22. At the discharge position, the tank 25 and the air pump 34 communicate with each other, and the communication between the tank 25 and the atmosphere is blocked, thereby preventing the sample water 1A from entering the nozzle 22.

  The air pump 34 is discharge means for discharging compressed air, and is disposed on the ground. The air pump 34 is operated in a state where the three-way valve 28 is switched to the discharge position, thereby discharging the cleaning water 1B in the tank 25 to the detection unit 12 through the nozzle 22 at a predetermined pressure. Further, when the washing water 1 </ b> B in the tank 25 is exhausted, the compressed air is discharged to the detection unit 12 through the tank 25 and the nozzle 22.

  The cleaning device 20 includes a pump control unit 36 that controls the air pump 34 and a valve control unit 38 that controls the three-way valve 28. The pump control unit 36 is communicably connected to the air pump 34 and switches the air pump 34 between a driving state and a stopped state. The valve control unit 38 is communicably connected to the three-way valve 28 and switches the three-way valve 28 between a discharge position and a suction position. The pump control unit 36 is communicably connected to the output control unit 15, and outputs a control signal to the air pump 34 based on a control signal from the output control unit 15. Similarly, the valve control unit 38 is communicably connected to the output control unit 15 and outputs a switching signal to the three-way valve 28 based on the control signal from the output control unit 15. Note that the output control unit 15, the pump control unit 36, and the valve control unit 38 preferably execute control in conjunction with each other, but may perform control individually. Further, even if the output control unit 15 functions as the functions of the pump control unit 36 and the valve control unit 38, the immersion type detector 10, the air pump 34, and the three-way valve 28 are controlled by one centralized control unit. Good.

(Cleaning method with cleaning equipment)
The cleaning device 20 stores a part of the sample water 1A to be measured in the tank 25 as the cleaning water 1B, and discharges the cleaning water 1B in the tank 25 to the detection unit 12 by the air pump 34. Remove the attached dirt. Further, after the cleaning water 1B in the tank 25 is discharged to the detection unit 12 by the air pump 34, the compressed air is subsequently discharged to the detection unit 12 through the tank 25, so that the cleaning water 1B cannot be removed. Remove different stains.

  Specifically, the air pump 34 and the three-way valve 28 are controlled by the output control unit 15, the pump control unit 36, and the valve control unit 38 as shown in FIG. In the storage means of the output control unit 15, the cleaning cycle T1 and the cleaning time (total cleaning time) T2 of the detection unit 12 are set (stored). As shown in FIG. 1B, at the total cleaning time T2, the air pump 34 is operated and the three-way valve 28 is switched to the discharge position. The time obtained by subtracting the total cleaning time T2 from the cleaning cycle T1 is a cleaning standby time T1-T2. As shown in FIG. 1A, in the cleaning standby time T1-T2, the operation of the air pump 34 is stopped, and the three-way valve 28 is switched to the suction position. The cleaning cycle T1 is set based on the progress of contamination of the detection unit 12 by the sample water 1A. The total cleaning time T2 is set according to the degree of contamination of the detection unit 12.

  As shown in FIGS. 1B and 3, at the start of the total cleaning time T <b> 2, the cleaning water 1 </ b> B in the tank 25 is discharged through the nozzle 22 by the compressed air from the air pump 34. The cleaning water 1B is discharged at a pressure corresponding to the discharge pressure performance of the air pump 34 due to the resistance at the discharge port 23 of the nozzle 22. Thereby, the detection part 12 is wash | cleaned by the wash water 1B collided with the predetermined pressure. The cleaning water 1B in the tank 25 gradually decreases due to the discharge, and when the cleaning time (first cleaning time) T3 with the cleaning water 1B elapses, the cleaning water 1B in the tank 25 including the nozzle 22 disappears. The first cleaning time T3 can be changed according to the opening area of the discharge port 23, the capacity of the tank 25, and the discharge capacity per unit time of the air pump 34. By selecting the shape of the discharge port 23 of the nozzle 22, the discharge capacity of the air pump 34, and the volume of the tank 25 according to the level of contamination of the detection unit 12, an effective cleaning function can be realized.

  The first cleaning time T3 is set to be shorter than the total cleaning time T2. The time obtained by subtracting the first cleaning time T3 from the total cleaning time T2 is a cleaning time using compressed air (second cleaning time) T2-T3. In the second cleaning time T <b> 2-T <b> 3, the compressed air discharged from the air pump 34 is jetted from the nozzle 22 to the detection unit 12 through the tank 25. The detection unit 12 is cleaned by the foaming effect of the compressed air following the cleaning with the cleaning water 1B.

  As shown in FIGS. 1A and 3, when the total cleaning time T2 elapses and the cleaning standby time T1-T2, the air pump 34 is stopped and the three-way valve 28 is switched to the suction position. Communication with the atmosphere. Then, the sample water 1A flows into the tank 25 through the nozzle 22 due to a pressure difference between the sample water 1A and the atmosphere. When the opening area of the discharge port 23, the inner diameter of the nozzle 22, and the backflow time T4 of the sample water 1A related to the water head have elapsed, the tank 25 is filled with the wash water 1B, which is the sample water 1A. Of course, the backflow time T4 is set to be shorter than the washing standby time T1-T2.

  The output control unit 15 measures the water quality of the sample water 1A through the immersion detector 10 during the cleaning standby time T1-T2. Further, the output control unit 15 stops the water quality measurement of the sample water 1A by the immersion detector 10 during the total cleaning time T2. However, when the cleaning process of the detection unit 12 using the cleaning water 1B or the compressed air does not affect the water quality measurement by the immersion detector 10, the water quality of the sample water 1A may be measured.

  As described above, in the cleaning apparatus 20, the air pump 34 and the three-way valve 28 are repeatedly operated by the output control unit 15 through the pump control unit 36 and the valve control unit 38 at a constant cleaning cycle T1. Accordingly, the cleaning device 20 stores a part of the sample water 1A to be measured in the tank 25 as the cleaning water 1B, and discharges the stored cleaning water 1B through the nozzle 22 by the air pump 34, thereby detecting the detection unit 12. Regularly remove dirt adhering to. Further, during the total cleaning time T2, the detection unit 12 is cleaned by the foaming effect of the compressed air by continuing to operate the air pump 34 even when the cleaning water 1B in the tank 25 becomes empty.

  And since the washing | cleaning apparatus 20 of this embodiment removes the stain | pollution | contamination adhering to the detection part 12 by discharging the washing water 1B to the detection part 12, it can make a cleaning effect high. In addition, the cleaning water 1B is a part of the sample water 1A to be measured, and there is no need to lay a dedicated pipe from a remote water source to the tank 25. Therefore, the cost for piping work can be reduced, and with few additional facilities The detection unit 12 can be effectively cleaned. Further, since the compressed air is discharged subsequent to the discharge of the cleaning water 1B, stains with different properties attached to the detection unit 12 can be reliably removed by the cleaning effect of the cleaning water 1B and the foaming effect of the compressed air.

  In the present embodiment, the tank 25 and the air pump 34 are connected by switching the three-way valve 28 to the discharge position, and the tank 25 and the atmosphere are shut off, so that the cleaning water in the tank 25 is reliably discharged. it can. Furthermore, the sample water 1A can be stored in the tank 25 as the wash water 1B through the nozzle 22 by the pressure difference by switching the three-way valve 28 to the suction position when washing is stopped and allowing the tank 25 and the atmosphere to communicate with each other. . Therefore, convenience can be improved. Further, since the cleaning water 1B can be stored in the tank 25 without using a pump or the like, the cost of the cleaning device 20 can be reduced.

(Second Embodiment)
FIG. 4 shows the cleaning device 20 of the immersion detector 10 of the second embodiment. The second embodiment is different from the first embodiment in that a pair of discharge ports 23 and 23 are provided in the nozzle 22. In the second embodiment, it is possible to obtain the same operation and effect as the first embodiment. Moreover, since the angles of the cleaning water 1B and the compressed air discharged from the discharge ports 23 and 23 toward the detection unit 12 can be changed, the cleaning can be performed more reliably.

(Third embodiment)
FIG. 5 shows a cleaning device 20 of the immersion detector 10 of the third embodiment. The third embodiment is different from the first embodiment in that a pair of a nozzle 22 and a tank 25 is provided on both the left and right sides of the immersion detector 10. The pair of tanks 25, 25 are branched and connected to the first connection portion 29 of the three-way valve 28. In the third embodiment thus configured, the same operations and effects as in the second embodiment can be obtained.

  As in the second embodiment and the third embodiment described above, in the cleaning device 20 of the present invention, the discharge port 23 of the nozzle 22 is not limited to one location, and may be provided in two or more locations. At this time, two or more discharge ports 23 may be provided in one nozzle 22, or two or more nozzles 22 may be arranged. One tank 25 may be arranged for each nozzle 22, or only one tank 25 may be arranged for a plurality of nozzles 22.

(Fourth embodiment)
FIG. 6 shows a cleaning device 20 of the immersion detector 10 of the fourth embodiment. The fourth embodiment is different from the first embodiment in that the nozzle 22 is provided integrally with the tank 25. The tank 25 is disposed in the sample water 1 </ b> A so as to be positioned below the detection unit 12. The nozzle 22 is integrally provided on the upper portion of the tank 25 so as to be positioned below the detection unit 12. In the fourth embodiment, the nozzle 22 can be installed at the same time by installing the tank 25, so that the workability related to installation can be improved.

(Fifth embodiment)
FIG. 7 shows a cleaning device 20 of the immersion detector 10 of the fifth embodiment. The fifth embodiment is different from the first embodiment in that the nozzle 22 is provided integrally with the immersion detector 10. The nozzle 22 is connected (communicated) to a separate tank 25 (not shown) by piping. In the fifth embodiment thus configured, it is possible to obtain the same operations and effects as in the first embodiment. Moreover, since the nozzle 22 can be installed at the same time when the immersion detector 10 is installed, it is not necessary to adjust the positions of the detection unit 12 and the nozzle 22 in the sample water 1A.

(Sixth embodiment)
FIG. 8 shows a cleaning device 20 of the immersion detector 10 of the sixth embodiment. The sixth embodiment is different from the first embodiment in that a tank 25 and a nozzle 22 are provided integrally with the immersion detector 10. The tank 25 is provided so as to cover the upper side of the casing 11 of the immersion detector 10. The nozzle 22 is provided in the lower part of the tank 25 so that the discharge port 23 is located below the detection unit 12. In the sixth embodiment thus configured, the same operations and effects as those of the first embodiment can be obtained. In addition, since the tank 25 and the nozzle 22 can be installed simultaneously with the installation of the immersion detector 10, it is not necessary to adjust the positions of the detection unit 12 and the nozzle 22.

  As in the fourth to sixth embodiments, the nozzle 22 may be provided integrally with the tank 25 or the immersion detector 10. Further, the tank 25 may be provided integrally with the immersion detector 10. Thus, the configuration of the immersion detector 10, the nozzle 22 and the tank 25 arranged in the sample water 1A can be changed as desired. Of course, the second embodiment and the third embodiment in which two or more discharge ports 23 are provided may be combined with the cleaning device 20 of the fourth to sixth embodiments.

(Seventh embodiment)
FIG. 9 shows a cleaning device 20 of the immersion detector 10 of the seventh embodiment. In the seventh embodiment, the tank 25 can be switched between a discharge state that prevents the sample water 1A from entering the tank 25 and a suction state that allows the sample water 1A to enter the tank 25. It differs from 1st Embodiment by the point which has arrange | positioned the non-return valve 40 as a switching valve. The check valve 40 allows the sample water 1A to flow into the tank 25 from the outside of the tank 25, and prevents the sample water 1A from flowing out of the tank 25 into the tank 25. In the seventh embodiment, the sample water 1A can be stored in the tank 25 regardless of the inner diameter of the nozzle 22 including the opening area of the discharge port 23. Further, in the discharge state by the air pump 34, the pressure in the tank 25 increases, but it is possible to reliably prevent the cleaning water 1B stored by the check valve 40 from leaking out of the tank 25. In the seventh embodiment, an electromagnetic valve may be used instead of the check valve 40.

(Eighth embodiment)
FIG. 10 shows a cleaning device 20 of the immersion detector 10 of the eighth embodiment. The eighth embodiment is different from the first embodiment in that a submersible pump 42 forcibly supplying the sample water 1A as the cleaning water 1B is disposed in the tank 25. The submersible pump 42 is a water supply means that can be disposed in the sample water 1A and fills the tank 25 with the wash water 1B. This submersible pump 42 is connected to the tank 25 via a third pipe 43. The third pipe 43 is provided with a check valve 44 that allows the flow from the submersible pump 42 to the tank 25 and prevents the flow from the tank 25 to the submersible pump 42. In the eighth embodiment thus configured, the same operations and effects as in the first embodiment can be obtained. Moreover, since the desired amount of sample water 1A can be stored in the tank 25 when desired by the submersible pump 42, the convenience can be improved.

  As in the seventh and eighth embodiments described above, the method of filling the cleaning water 1B is not limited to the configuration in which the sample water 1A is filled into the tank 25 via the nozzle 22, but is filled directly from the outer wall of the tank 25. May be. Of course, in the cleaning device 20 of the seventh and eighth embodiments, the second embodiment and the third embodiment in which two or more discharge ports 23 are provided, and the nozzle 22 is provided integrally with the tank 25 and the immersion detector 10. The fourth embodiment to the sixth embodiment may be combined.

(Ninth embodiment)
FIG. 11 shows the cleaning device 20 of the immersion detector 10 of the ninth embodiment. The ninth embodiment is different from the first embodiment in that a suction pump 46 is branched and connected to the second pipe 32 in order to supply the sample water 1A as cleaning water 1B into the tank 25 via the nozzle 22. To do. The tank 25 and the air pump 34 communicate with each other via a check valve 47 instead of the three-way valve 28. The check valve 47 allows the flow from the air pump 34 to the tank 25 and prevents the flow from the tank 25 to the air pump 34. The suction pump 46 is a water supply unit that fills the tank 25 with the cleaning water 1 </ b> B, and is branched and connected between the check valve 47 and the tank 25. The suction pump 46 is controlled by a second pump control unit 48 different from the first pump control unit 36 for the air pump 34. In the ninth embodiment thus configured, the same operations and effects as those of the first embodiment can be obtained. In addition, since the sample water can be forcibly filled into the tank 25 by the suction pump 46 instead of the pressure difference between the sample water 1A and the atmosphere, the same operations and effects as in the eighth embodiment can be obtained.

  As in the above eighth and ninth embodiments, the configuration in which the sample water 1A is filled in the tank 25 as the cleaning water 1B is not limited to the configuration using the pressure difference between the sample water 1A and the atmosphere, You may forcibly fill using a pump. Further, the second embodiment and the third embodiment in which two or more discharge ports 23 are provided in the cleaning device 20 of the ninth embodiment, and the fourth embodiment in which the nozzle 22 is provided integrally with the tank 25 and the immersion detector 10 are described. The sixth embodiment and the seventh embodiment in which the check valve 40 is provided in the tank 25 may be combined.

(10th Embodiment)
FIG. 12 shows the cleaning device 20 of the immersion detector 10 of the tenth embodiment. The tenth embodiment is different from the ninth embodiment in that the tank 25 is disposed on the ground outside the sample water 1A and connected to the nozzle 22 via the fourth pipe 49. In the tenth embodiment thus configured, the same operations and effects as those of the ninth embodiment can be obtained. The configuration in which the tank 25 is disposed on the ground may be combined with the configurations of the second to eighth embodiments as desired.

(Eleventh embodiment)
FIG. 13 shows the cleaning device 20 of the immersion detector 10 of the eleventh embodiment. In the eleventh embodiment, the air pump 50 and the pump control unit 51 already installed in the sewage treatment plant or the wastewater treatment facility of the factory are used, and the air pump 50 is connected to the second connection unit 30 of the three-way valve 28. This is different from the first embodiment. In the eleventh embodiment thus configured, the output control unit 15 is communicably connected to the pump control unit 51, so that the same operations and effects as those of the first embodiment can be obtained. Further, the output control unit 15 may be controlled independently without being connected to the pump control unit 51. Further, the configuration of the eleventh embodiment using the existing air pump 50 and pump control unit 51 may be combined with the configurations of the second to tenth embodiments as desired.

(Experimental example)
The present inventors conducted an experiment to compare the cleaning ability using a conventional product that is cleaned only with compressed air and an inventive product that was cleaned with compressed air after the sample water 1A was cleaned as the cleaning water 1B. A dissolved oxygen meter was used as the immersion detector 10. Moreover, as each operation time in the time chart of FIG. 3, the cleaning cycle T1 was set to 30 minutes, and the cleaning time T2 was set to 30 seconds. For the cleaning device 20 of the present invention, a 500 mL tank 25 was used, the cleaning time T3 with the sample water 1A was 15 seconds, and the backflow time T4 of the sample water 1A was 15 minutes. Under these conditions, the quality of the sample water 1A was continuously measured with a dissolved oxygen meter for about one month. The results are shown in the graphs of FIGS. 14A and 14B.

  FIG. 14A shows the measurement result of the conventional product, and FIG. 14B shows the measurement result of the invention product. In these graphs, the vertical axis represents the dissolved oxygen concentration (mg / L) detected by the dissolved oxygen meter, and the horizontal axis represents the number of measurement days (days). As shown in FIG. 14A, in the conventional cleaning device using only compressed air, a decrease in output was observed from the 14th day due to contamination of the detection unit of the dissolved oxygen meter. Therefore, when the dissolved oxygen meter was pulled up on the 21st day and the detection unit was washed manually, the output was restored. On the other hand, as shown in FIG. 14B, it was confirmed that the cleaning apparatus 20 of the present invention did not show a decrease in output even after the 14th day and could be measured stably for one month.

  In the present invention, a part of the sample water 1A to be measured is stored in the tank 25 as the wash water 1B, and the wash water 1B in the tank 25 is discharged by the discharge means, thereby detecting the detection unit of the immersion detector 10. 12 is characterized by a cleaning method for removing dirt. In particular, the configuration of the cleaning device 20 can be variously changed as shown in the above embodiments.

  In the above embodiment, the cleaning water 1B is discharged using the air pump 34. However, the cleaning water 1B may be discharged by a compressor, and the discharge means for the cleaning water 1B can be changed as desired. . Further, the arrangement and shape of the nozzles 22 can be changed as desired according to the contamination of the detection unit 12. Further, after the cleaning water 1B in the tank 25 is discharged (injected) to the detection unit 12 by the discharge means, the compressed air is subsequently discharged to the detection unit 12, but the compressed air is not discharged. Also good.

DESCRIPTION OF SYMBOLS 1A Sample water 1B Washing water 10 Immersion type detector 11 Casing 12 Detection part 15 Output control part 20 Cleaning device 22 Nozzle 23 Discharge port 24 Piping part 25 Tank 26 First piping 28 Three-way valve 29 First connection part 30 Second connection part 31 3rd connection part 32 2nd piping 34 Air pump (discharge means)
36 Pump control unit (discharge means control unit)
38 Valve control unit 40 Check valve 42 Submersible pump (water supply means)
43 3rd piping 44 Check valve 46 Suction pump (water supply means)
47 Check valve 48 Second pump controller 49 Fourth pipe 50 Air pump (discharge means)
51 Pump control unit (discharge means control unit)

Claims (7)

A nozzle that is arranged in the sample water to be measured and is open toward the detection part of the immersion detector immersed in the sample water;
A tank that communicates with the nozzle and stores a portion of the sample water as wash water;
A discharge means that is communicated with the tank and discharges the cleaning water in the tank from the nozzle toward the detection unit;
A cleaning device for an immersion type detector, comprising: an ejection unit control unit that controls the ejection unit and removes dirt attached to the detection unit of the immersion type detector. The discharge means is an air pump or a compressor that discharges compressed air,
The discharge means control section discharges the cleaning water in the tank from the nozzle to the detection section by discharging compressed air by the discharge means, and then continuously from the nozzle through the tank to the nozzle. The cleaning device for an immersion detector according to claim 1, wherein compressed air is discharged to the detection unit.   The switch valve which can be switched to the discharge position which prevents that the sample water permeates into the tank, and the suction position where the sample water can permeate into the tank is provided. The cleaning device for the immersion detector according to 2.   The switching valve has a first connection connected to the tank, a second connection connected to the discharge means, and a third connection open to the atmosphere, and the first connection 4. A three-way valve that can be switched by a valve control unit between a discharge position in which the part and the second connection part communicate with each other and a suction position in which the first connection part and the third connection part communicate with each other. The immersion detector cleaning apparatus according to 1.   The immersion detector cleaning device according to any one of claims 1 to 4, further comprising water supply means for storing the sample water in the tank. A part of the sample water to be measured is stored in the tank as wash water,
By discharging the cleaning water in the tank by the discharge means to the detection unit of the immersion detector immersed in the sample water,
A method for cleaning an immersion detector, wherein dirt attached to the detection portion of the immersion detector is removed.   The compressed air is discharged from the discharge unit to discharge the cleaning water in the tank to the detection unit, and then the compressed air is discharged to the detection unit via the tank. Cleaning method for immersion type detector.

Images