JP5829949B2 - Ozone water concentration detection sensor - Google Patents

Description

  The present invention relates to an ozone water concentration detection sensor.

Ozone water has been recognized for its contributions in many fields, such as its bactericidal and deodorizing properties, as well as its activity on cells, and ozone dissolved in water has no effect on respiratory organs. Widely used in fields such as nursing care. However, since the concentration of ozone water attenuates in a short time, there is a strong demand for indication and confirmation of the concentration at the site of use.
Conventionally, as a concentration calibration method for ozone water, a titration method that looks at the color change of a test reagent such as potassium iodide was a regular measurement method, but it requires chemicals and a precision pipette and should be used in the laboratory. However, it is complicated and cannot be put into practical use at a general ozone water use site. Therefore, an ultraviolet absorption method for examining the ultraviolet absorption rate of ozone water, a polarographic method using an ozone permeable membrane, and the like are also used. However, the ultraviolet absorption method is extremely expensive, both of which have advantages and disadvantages, and it has been difficult to easily know the ozone concentration instantaneously.

Therefore, a simpler electrode method has been attracting attention by simply converting the ozone water concentration into an electrical signal. In this electrode method, a first electrode and a second electrode are immersed in a flowing ozone water stream, the first electrode is composed of metallic silver coated with metallic silver or silver chloride, and the second electrode is A voltage change following a change in the concentration of ozone water generated between the first electrode and the second electrode is detected (see, for example, Patent Document 1). . Such a bare electrode type electrode method has an excellent feature that the structure is particularly simple and the response is quick.
Further, a technique in which such a bare electrode type concentration measuring means is attached to an ozone water production apparatus is known (for example, see Patent Document 2). Specifically, an electromotive force measurement electrode body configured by arranging an electromotive force measurement electrode body made of a dissimilar metal and a counterpart electrode body at predetermined intervals in the flow path of ozone water is provided.

JP-A-8-136501 Japanese Patent Laid-Open No. 2004-60010

By the way, in the ozone water production apparatus described in Patent Document 2, the electromotive force measurement electrode body, which is a concentration measuring means, is attached and fixed to the wall surface of the cleaning water container so as to be disposed in the flow path of ozone water. Yes.
However, when such a concentration measuring means is used continuously for a long period of time, problems such as calcium and magnesium adhering to the surface of the electrode body in ozone water and lowering the sensitivity occur, and concentration measurement should be performed accurately. I can't. Therefore, it is necessary to replace the electrode body after use for a predetermined period.
On the other hand, it is required to measure the concentration by bringing the electrode body into contact with ozone water flowing in the flow path at an optimal position.
However, Patent Document 2 does not describe anything about the replacement of the electrode body and the method of attaching / detaching the cleaning water container. When the electrode body is bonded and fixed to the cleaning water container, the electrode body cannot be removed and the position of the electrode body in the flow path cannot be finely adjusted.
The present invention has been made in view of the above circumstances, and it is possible to easily replace the detection electrode and the comparison electrode, and to adjust the position of the detection electrode and the comparison electrode in the flow path. It aims to provide a detection sensor.

According to the invention of claim 1, an ozone water concentration detection sensor detachably provided on a wall surface forming a flow path through which ozone water flows,
An opening communicating with the flow path is formed in the wall surface,
A base provided detachably on the opening so as to close the opening;
A detection electrode and a comparison electrode provided through the base and having a tip disposed in the flow path,
An ozone water concentration detection sensor is provided in which the detection electrode and the comparison electrode are detachably attached to the base.

  According to a second aspect of the present invention, the base is provided with first position adjusting means for adjusting the positions of the detection electrode and the comparison electrode in the radial direction of the flow path. The ozone water concentration detection sensor according to 1, is provided.

  According to invention of Claim 3, the said base is provided with the 2nd position adjustment means which adjusts the position of the said detection electrode and comparison electrode in the axial direction of the said flow path. The ozone water concentration detection sensor according to 1 or 2 is provided.

  According to the present invention, the detection electrode and the comparison electrode can be easily exchanged, and the position of the detection electrode and the comparison electrode in the flow path can be adjusted.

The case where the ozone water density | concentration detection sensor of 1st Embodiment is arrange | positioned in a flow path was shown, (a) is a sectional side view, (b) is when cut along cutting line II. An arrow sectional view, (c) is an arrow sectional view when cut along the cutting line II-II, and (d) is a top view. 2A and 2B show a chuck body, wherein FIG. 1A is a top view of the chuck body, FIG. 1B is a side sectional view of the chuck body, and FIG. 2C is a side view of the chuck body. FIG. 2 shows a collet chuck, wherein (a) is a top view of the collet chuck, (b) is a side sectional view of the collet chuck, and (c) is a side view of the collet chuck. The case where the ozone water density | concentration detection sensor of 2nd Embodiment is arrange | positioned in a flow path was shown, (a) is a sectional side view, (b) is when cut along cutting line III-II. An arrow sectional view, (c) is a top view. It shows the internal structure of the detachable device, (a) is the state before the detection electrode or comparison electrode is attached, (b) is the state where the detection electrode or comparison electrode is attached, (c), The detection electrode or the comparison electrode can be adjusted in position. The case where the ozone water density | concentration detection sensor of 3rd Embodiment is arrange | positioned in a flow path was shown, (a) is a sectional side view, (b) is when cut along cutting line IV-IV. An arrow sectional view, (c) is an arrow sectional view when cut along a cutting line V-V, and (d) is a top view. FIG. 2 shows a nut, (a) is a top view of the nut, (b) is a side sectional view of the nut, and (c) is a side view of the nut.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
[First Embodiment]
FIG. 1 shows a case where the ozone water concentration detection sensor according to the first embodiment is arranged in a flow path, where (a) is a side sectional view and (b) is along a cutting line II. An arrow sectional view at the time of cutting, (c) is an arrow sectional view at the time of cutting along the cutting line II-II, and (d) is a top view.
As shown in FIG. 1, the ozone water concentration detection sensor 100 is a sensor that is provided in, for example, a flow path (in a pipe) 200 or a water tank through which ozone water flows and detects the ozone concentration of flowing ozone water. In the present embodiment, an ozone water concentration detection sensor when disposed in the flow path 200 will be described.
The ozone water concentration detection sensor 100 is detachably provided on a wall surface 201 that forms the flow path 200. An opening 202 communicating with the flow path 200 is formed in the wall surface 201.
The ozone water concentration detection sensor 100 includes a base 1 that is detachably provided in the opening 202 so as to close the opening 202, and is provided so as to penetrate the base 1. The detection electrode 2 and the comparison electrode 3 are provided.
The detection electrode 2 and the comparison electrode 3 are detachably provided on the base 1.

The base 1 has, for example, a rectangular plate shape, and the size thereof is larger than that of the opening 202 and is large enough to close the opening 202. The base 1 is installed with a bolt V on a wall surface 201 that forms the flow path 200 so as to close the opening 202.
The base 1 is provided with two collet chuck type attaching / detaching devices 4 (first position adjusting means) for adjusting and holding the detection electrode 2 and the comparison electrode 3 at predetermined positions in the flow path 200.

The attachment / detachment device 4 includes a collet chuck 42 and a chuck main body 41.
The chuck body 41 is incorporated in the base 1. Specifically, as shown in FIG. 1 (c), a mounting hole 11 into which the chuck body 41 is mounted is formed in the base 1. The mounting hole 11 is a cylindrical hole formed inwardly from the upper surface of the base 1. A female screw 11 a that is screwed into the outer peripheral surface of the chuck body 41 is formed on the inner peripheral surface that forms the mounting hole 11.
In addition, a rod-shaped insertion hole 12 through which the detection electrode 2 or the comparison electrode 3 is inserted is formed at the bottom of the mounting hole 11 so as to penetrate the lower surface of the base 1. The assembly hole 11 and the insertion hole 12 communicate with each other.

FIG. 2 shows the chuck body, (a) is a top view of the chuck body, (b) is a side sectional view of the chuck body, (c) is a side view of the chuck body, and FIG. FIG. 2 shows a collet chuck, wherein (a) is a top view of the collet chuck, (b) is a side sectional view of the collet chuck, and (c) is a side view of the collet chuck.
As shown in FIG. 2, a male screw 41 b that engages with the female screw 11 a of the mounting hole 11 is formed on the outer peripheral surface of the chuck body 41.
Further, the chuck body 41 has a collet chuck 42 inserted therein, and a tightening hole 411 for tightening and fixing the collet chuck 42 from the outside is formed.
On the inner peripheral surface of the tightening hole 411, a female screw 411a that is screwed into the outer peripheral surface of the collet chuck 42 is formed.
The tightening hole 411 has substantially the same shape as the outer shape of the collet chuck 42. That is, the tightening hole 411 has a wedge shape in a side sectional view so that the diameter decreases toward the tip. The collet chuck 42 inserted into the tightening hole 411 and screwed in the tightening direction is tightened from the outside by a tapered surface 412 that forms the tightening hole 411 and is fixed to the chuck body 41. .

As shown in FIG. 3, the collet chuck 42 has a wedge shape as viewed from the side and has a tapered surface 422 so that the diameter decreases toward the tip.
On the outer peripheral surface of the collet chuck 42, a male screw 42 b is formed that is screwed into a female screw 411 a formed in the fastening hole 411 of the chuck body 41.
The collet chuck 42 is formed with an insertion hole 421 into which the detection electrode 2 or the comparison electrode 3 is inserted. The diameter of the insertion hole 421 is substantially equal to the diameters of the detection electrode 2 and the comparison electrode 3.
On the tapered surface 422 of the collet chuck 42, a vertically long slot 423 that penetrates the inside of the collet chuck 42 is formed. Then, the collet chuck 42 is inserted into the tightening hole 411 of the chuck main body 41, screwed in the tightening direction, and tightened by the tapered surface 412 of the chuck main body 41, thereby closing the elongated hole 423. As a result, since the diameter of the elongated hole portion of the collet chuck 42 is reduced, the detection electrode 2 or the comparison electrode 3 inserted into the insertion hole 421 of the collet chuck 42 is tightened by the inner peripheral surface forming the insertion hole 421. And fixed at a predetermined position.

As shown in FIG. 1, the comparison electrode 3 is formed by forming a metal wire in a coil shape, and a detection electrode 2 made of a metal wire is spaced apart from the comparison electrode 3 inside the coil shape of the comparison electrode 3. Is provided. That is, the detection electrode 2 and the comparison electrode 3 are formed so as not to contact each other.
The detection electrode 2 is bent linearly at the tip thereof, and the bent portion is arranged inside the coil of the comparison electrode 3. The shape of the detection electrode 2 is not limited to this, and may be a coil shape in which a metal wire is wound a plurality of times, for example. Also in this case, the reference electrode 3 is arranged on the coiled inner side so as not to contact the comparison electrode 3. The winding number of the metal wire is preferably 3 or more. The coiled winding interval is preferably 1 mm or more. This is preferable in that the ozone water appropriately flows from the gap between the winding intervals of the metal wire into the detection electrode 2 to increase the contact area between the ozone water and the detection electrode 2 and increase the sensor output.
As the detection electrode 2, for example, a metal wire coated with gold or platinum is preferably used. The wire diameter is preferably φ0.5 mm or more.

The comparison electrode 3 is formed in a coil shape in which a metal wire is wound a plurality of times. For example, the number of turns of the metal wire forming the comparison electrode 3 is preferably 3 turns or more. The coiled winding interval is preferably 1.2 mm or more. This is preferable in that the ozone water appropriately flows from the gap between the winding intervals of the metal wire into the inside of the reference electrode 3 to increase the contact area between the ozone water and the comparison electrode 3 and increase the sensor output.
As the comparative electrode 3, for example, a metal wire having a silver surface coated with silver chloride is preferably used, and the wire diameter is preferably 0.8 mm or more.

A lead (not shown) is connected to the base end of the reference electrode 3 protruding from the base 1. The lead is connected to the negative electrode of an ammeter (not shown).
A lead wire (not shown) is connected to the base end portion protruding from the base 1 of the detection electrode 2. The lead wire is connected to the positive electrode of an ammeter (not shown).
A micro-ampere ammeter can be used as the ammeter.

The detection electrode 2 and the comparison electrode 3 are held by the attachment / detachment devices 4 incorporated in the base 1, and the distal ends of the detection electrode 2 and the comparison electrode 3 are arranged in the flow path 200.
An O-ring 203 is provided on the contact surface between the base 1 and the opening 202, and the O-ring 203 ensures water tightness between the base 1 and the opening 202. .
Further, an O-ring 204 is also provided between the tip of the chuck body 41 and each of the electrodes 2 and 3, and the O-ring 204 ensures water tightness between the chuck body 41 and each of the electrodes 2 and 3. doing.

Next, a procedure for arranging the ozone water concentration detection sensor 100 in the flow path will be described.
First, the detection electrode 2 and the comparison electrode 3 are attached to the base 1.
That is, the chuck body 41 is screwed and fixed to the mounting hole 11 of the base 1 in the tightening direction, and the collet chuck 42 is inserted into the tightening hole 411 of the chuck body 41.
Next, the detection electrode 2 is inserted from the insertion hole 421 of one collet chuck 42, and the comparison electrode 3 is inserted from the insertion hole 421 of the other collet chuck 42.
Next, the collet chuck 42 is screwed into the tightening hole 411 in the tightening direction, and the collet chuck 42 is fixed to the chuck body 41. Thereby, the detection electrode 2 and the comparison electrode 3 are attached to the base 1.
Thereafter, the base 1 on which the detection electrode 2 and the comparison electrode 3 are installed is fixed to the wall surface 201 that forms the flow path 200 with a bolt V.
When adjusting the position of the detection electrode 2 and the comparison electrode 3 in the vertical direction (radial direction X of the flow path 200 (pipe)) in the flow path 200, the collet chuck 42 is temporarily attached to the chuck body 41. The position of the detection electrode 2 and the comparison electrode 3 in the vertical direction is adjusted by loosening the screwing. Then, the collet chuck 42 is again screwed into the chuck body 41 in the tightening direction and fixed while holding the positions of the detection electrode 2 and the comparison electrode 3 adjusted.

  In addition, when exchanging the detection electrode 2 and the comparison electrode 3, the bolt V that fastens the base 1 and the wall surface 201 is removed, and the screwing of the collet chuck 42 to the chuck body 41 is further loosened. This is performed by removing the detection electrode 2 and the comparison electrode 3 from the collet chuck 42.

As described above, according to the embodiment of the present invention, the base 1 provided detachably so as to close the opening 202 is provided, and the detection electrode 2 and the comparison electrode 3 are provided detachably with respect to the base 1. Therefore, the detection electrode 2 and the comparison electrode 3 can be easily replaced by removing the detection electrode 2 and the comparison electrode 3 from the base 1.
Further, after adjusting the position of the detection electrode 2 and the comparison electrode 3 with respect to the base 1, the position of the detection electrode 2 and the comparison electrode 3 in the flow path 200 is adjusted by attaching the base 1 to the opening 202. be able to.
In particular, in this embodiment, the base 1 is provided with a collet chuck type attachment / detachment device 4 that adjusts the positions of the detection electrode 2 and the comparison electrode 3 in the vertical direction (radial direction X) of the flow path 200. With this attachment / detachment device 4, the position adjustment of the detection electrode 2 and the comparison electrode 3 in the vertical direction (radial direction X) of the flow path 200 can be easily performed. As a result, the detection electrode 2 and the comparison electrode 3 can be arranged at a position where the ozone water can be more easily contacted to increase the contact area with the ozone water, so that the detection accuracy can be increased.
Further, the use of the collet chuck type attachment / detachment device 4 is preferable in that it can be fixed firmly because it is fixed over a wide area.

[Second Embodiment]
FIG. 4 shows a case where the ozone water concentration detection sensor according to the second embodiment is arranged in the flow path, where (a) is a side sectional view and (b) is taken along a cutting line III-II. A cross-sectional view taken along the line, (c) is a top view.
In the second embodiment, as a method for attaching and detaching the detection electrode and the comparison electrode to the base, the terminal block type is used instead of the collet chuck type as in the first embodiment.
Specifically, as shown in FIG. 4, the ozone water concentration detection sensor 100 </ b> A includes a base 1 </ b> A that is detachably provided in the opening 202 so as to close the opening 202, and a base 1 </ b> A that penetrates the base 1 </ b> A. In addition, the detection electrode 2 and the comparison electrode 3 are provided with the tip portion disposed in the flow path 200.
The detection electrode 2 and the comparison electrode 3 are detachably attached to the base 1A.

The base 1A is provided in contact with the wall surface 201 that forms the flow path 200, and includes a contact portion 1a that closes the opening 202, and a protruding portion 1b that protrudes upward from the upper surface of the contact portion 1a. It has. The base 1 </ b> A has an L shape in a side view including a contact portion 1 a and a protruding portion 1 b.
The contact portion 1a is larger than the size of the opening 202, and has a size capable of closing the opening 202.

The protruding portion 1b is provided with two terminal block type attachment / detachment devices 4A (first position adjusting means) for adjusting and holding the detection electrode 2 and the comparison electrode 3 at predetermined positions in the flow path 200.
More specifically, an assembling hole 11A into which the attaching / detaching device 4A is incorporated is formed in the protruding portion 1b. The built-in hole 11A is a rectangular parallelepiped hole formed inwardly from the upper surface of the protruding portion 1b. The assembly hole 11A is formed larger than the attachment / detachment device 4A. Therefore, the attachment / detachment device 4A can be easily inserted into and removed from the assembly hole 11A.
Further, an insertion hole 12A is formed at the bottom of the mounting hole 11A so as to penetrate the lower surface of the base 1A and into which the detection electrode 2 or the comparison electrode 3 is inserted. The assembly hole 11A and the insertion hole 12A communicate with each other.
The detection electrode 2 and the comparison electrode 3 are inserted into the upper end portion of the insertion hole 12A, and a support screw N that supports the detection electrode 2 and the comparison electrode 3 is fitted therein. Below the support screw N in the insertion hole 12A, an O-ring 204A is provided to ensure watertightness between the detection electrode 2 and the comparison electrode 3 inserted into the support screw N and the chuck device 4A. Yes. The support screw N also has a function for pressing and fixing the O-ring 204A downward.

The attaching / detaching device 4A inserted into the mounting hole 11A of the base 1A is covered with the fixing plate 13A from above, and bolts V are inserted from both side surfaces of the fixing plate 13A toward the projecting portion 1a and fastened. At the same time, the bolt V is inserted and fastened from the upper surface of the fixing plate 13A toward the protruding portion 1a. In this way, the attachment / detachment device 4A is fixed to the base 1A.
Further, an O-ring 203A is provided between the contact portion 1a of the base 1A and the opening 202, and the O-ring 203A ensures the watertightness between the base 1A and the opening 202. Yes.

  Since the detection electrode 2 and the comparison electrode 3 have the same configuration as that of the first embodiment, the same reference numerals are given and description thereof is omitted.

Next, the attachment / detachment device 4A will be described.
FIG. 5 shows the internal structure of the attachment / detachment device. (A) is a state before the detection electrode or comparison electrode is attached, (b) is a state where the detection electrode or comparison electrode is attached, ( c) is a state in which the position of the detection electrode or the comparison electrode can be adjusted.
As shown in FIG. 5A, the attachment / detachment device 4A includes a case body 41A, a spring 42A provided inside the case body 41A, and a locking member that locks the spring 42A and restricts the operation of the spring 42A. 43A and a lever 44A that is provided on the case body 41A and rotates the spring 42A against the urging force.
In the case body 41A, an insertion hole 411A is formed through the lower surface in FIG. 5A and into which the detection electrode 2 or the comparison electrode 3 is inserted. The diameter of the insertion hole 411A is substantially equal to the diameters of the detection electrode 2 and the comparison electrode 3.

The locking member 43A includes two leg portions 431A extending vertically and two connecting portions 432A provided so as to connect the leg portions 431A and be substantially parallel to each other.
In FIG. 5 (a), the right leg 431A is formed with a groove 433A in which the right end of the spring 42A is inserted and locked from below.
As shown in FIG. 5 (b), in the lower connecting portion 432A, the first hole portion 434A into which the left end portion of the spring 42A is inserted, and the second hole into which the detection electrode 2 or the comparison electrode 3 is inserted. Holes 435A are respectively formed.
A third hole 436A into which the tip of the detection electrode 2 or the comparison electrode 3 inserted into the second hole 435A is inserted is formed in the upper connecting part 432A.
Further, the left end portion of the spring 42A is brought into contact with the left leg portion 431A by an urging force, and the case body 41A is disposed between the left leg portion 431A and the left end portion of the spring 42A. The detection electrode 2 or the comparison electrode 3 inserted through the insertion hole 411A and the second hole portion 435A is sandwiched and fixed.

The spring 42A is provided to engage around a shaft portion 45A provided inside the case body 41A, and is locked by a locking member 43A provided inside the case body 41A.
Specifically, the right end portion of the spring 42A is inserted into the groove portion 433A of the locking member 43A and locked and fixed to the wall surface forming the groove portion 433A, and the left end portion of the spring 42A is fixed to the locking member 43A. The first hole 434A is inserted into the first hole 434A, and the position is regulated by contacting the left leg 431A.

The lever 44A is provided so as to cover a part of the locking member 43A and the spring 42A from the front surface side (the paper surface side in FIG. 5), and a part of the lever 44A protrudes outside the case body 41A.
The lever 44A is formed with a spring hole 441A into which the left end of the spring 42A is fitted and a shaft hole (not shown) into which the shaft 45A is fitted.
The shaft portion 45A is fitted into the shaft portion hole, and the left end portion of the spring 42A is fitted into the spring hole 441A, whereby the lever 44A is attached to the case body 41A.
As shown in FIG. 5B, the lever 44A is rotated clockwise around the shaft portion 45A when the protrusion 442A protruding outward from the case body 41A is pressed upward as shown in FIG. The left end of the spring 42A fitted in the spring hole 441A is rotated against the urging force by the rotation of the lever 44A.
As a result, the tip of the other end of the spring 42A is separated from the left leg 431A of the locking member 43A (see FIG. 5C).

In such an attachment / detachment device 4A, the detection electrode 2 or the comparison electrode 3 is inserted into the second hole 435A of the locking member 43A via the insertion hole 411A of the case body 41A, and the tip of the detection electrode 2 or the comparison electrode 3 is inserted. When reaching the left end of the spring 42A and further inserting, the gap between the left end of the spring 42A and the left leg 431A is pushed open against the biasing force of the spring 42A. As a result, the detection electrode 2 or the comparison electrode 3 is inserted between the left end portion of the spring 42A and the left leg portion 431A, and is sandwiched between them. Further, the tip of the detection electrode 2 or the comparison electrode 3 is inserted and fixed in the third hole 436A (see FIG. 5B).
From this state, as shown in FIG. 5 (b), the lever 44A is rotated clockwise about the shaft 45A against the biasing force of the spring 42A by pressing the protrusion 442A of the lever 44A upward as shown in FIG. While rotating, the left end of the spring 42A is separated from the left leg 431A (see FIG. 5C). As a result, the detection electrode 2 or the comparison electrode 3 held between the left leg portion 431A and the left end portion of the spring 42A is released. As a result, the detection electrode 2 or the comparison electrode 3 can be moved to a predetermined position in the vertical direction with respect to the case body 41A.
Then, by releasing the pressing of the protruding portion 442A again, the lever 44A rotates counterclockwise about the shaft portion 45A by the biasing force of the spring 42A. Accordingly, the detection electrode 2 or the comparison electrode 3 positioned between the left leg portion 431A and the left end portion of the spring 42A is sandwiched (see FIG. 5B).

  As described above, the detection electrode 2 and the comparison electrode 3 are held by the attachment / detachment devices 4A incorporated in the base 1A, so that the distal ends of the detection electrode 2 and the comparison electrode 3 are arranged in the flow path 200. Has been.

Next, a procedure for arranging the ozone water concentration detection sensor 100A in the flow path will be described.
First, the detection electrode 2 and the comparison electrode 3 are attached to the base 1A.
That is, the attaching / detaching device 4A is inserted into the mounting hole 11A of the base 1A, the upper surface of the attaching / detaching device 4A is covered with the fixing plate 13A, and the bolts V are inserted and tightened from both side surfaces of the fixing plate 13A toward the protruding portion 1b.
Next, the detection electrode 2 and the comparison electrode 3 are inserted from the insertion hole 12A of the base 1A toward the attachment / detachment device 4A. As a result, the detection electrode 2 and the comparison electrode 3 are sandwiched and fixed between the left leg portion 431A of the locking member 43A and the left end portion of the spring 42 as described above.
Thereafter, the base 1A on which the detection electrode 2 and the comparison electrode 3 are installed is fixed to the wall surface 201 forming the flow path 200 by inserting and fastening bolts V from the upper surfaces of the contact portion 1a and the fixing plate 13A. . As a result, the detection electrode 2 and the comparison electrode 3 are arranged in the flow path 200.
When adjusting the position of the detection electrode 2 and the comparison electrode 3 in the vertical direction (radial direction X of the flow channel 200 (pipe)) in the flow channel 200, the protruding portion 442A of the lever 44A of the attachment / detachment device 4A faces upward. In this state, the vertical positions of the detection electrode 2 and the comparison electrode 3 are adjusted, and then the pressing of the protruding portion 442A of the lever 44A is released at the position where the detection electrode 2 and the comparison electrode 3 are adjusted. Thereby, the detection electrode 2 and the comparison electrode 3 are fixed at predetermined positions.

  When the detection electrode 2 and the comparison electrode 3 are exchanged, the bolt V that fastens the base 1A and the wall surface 201 is removed, and the lever 44A of the attachment / detachment device 4A is pushed upward, and the detection electrode 2 or The reference electrode 3 is removed.

As described above, according to the embodiment of the present invention, similarly to the first embodiment, the base 1 </ b> A provided detachably so as to close the opening 202 is provided, and the detection electrode 2 and the comparison electrode 3 are the base 1 </ b> A. Since the detection electrode 2 and the comparison electrode 3 are removed from the base 1A, the detection electrode 2 and the comparison electrode 3 can be easily exchanged.
Further, after adjusting the position of the detection electrode 2 and the comparison electrode 3 with respect to the base 1A, the position of the detection electrode 2 and the comparison electrode 3 in the flow path 200 is adjusted by attaching the base 1A to the opening 202. be able to.
In particular, in this embodiment, a terminal block type attachment / detachment device 4A for adjusting the positions of the detection electrode 2 and the comparison electrode 3 in the radial direction X of the flow path 200 is provided on the base 1A. Thus, the position adjustment in the vertical direction (radial direction X) of the flow path 200 of the detection electrode 2 and the comparison electrode 3 can be performed. As a result, the detection electrode 2 and the comparison electrode 3 can be arranged at a position where the ozone water can be more easily contacted to increase the contact area with the ozone water, so that the detection accuracy can be increased.
In addition, since the terminal block type attaching / detaching device 4A is used to fix in a smaller area than the collet chuck type attaching / detaching device 4, the fastening force is inferior, but it is preferable in terms of easy attachment and detachment and manufacturing cost. .

[Third Embodiment]
FIG. 6 shows a case where the ozone water concentration detection sensor according to the third embodiment is arranged in the flow path, where (a) is a side sectional view and (b) is taken along a cutting line IV-IV. An arrow sectional view at the time of cutting, (c) is an arrow sectional view at the time of cutting along the cutting line V-V, and (d) is a top view.
In the third embodiment, the collet chuck type as in the first embodiment is adopted as a method for attaching and detaching the detection electrode and the comparison electrode to the base. Furthermore, in the third embodiment, the position adjustment of the detection electrode and the comparison electrode can be performed not only in the radial direction of the flow path but also in the axial direction (water flow direction).
Specifically, as shown in FIG. 6, the mounting hole 11B of the base 1B is larger than the mounting hole 11 of the first embodiment. 41) nuts 5B (second position adjusting means) disposed outside are incorporated. A female screw (not shown) that is screwed onto the outer peripheral surface of the nut 5B is formed on the inner peripheral surface that forms the assembly hole 11B.
Further, a rod-shaped insertion hole 12B into which the detection electrode 2 or the comparison electrode 3 is inserted is formed at the bottom of the assembly hole 11B.

FIG. 7 shows a nut, (a) is a top view of the nut, (b) is a side sectional view of the nut, and (c) is a side view of the nut.
A male screw 5b is formed on the outer peripheral surface of the nut 5B. The male screw 5b is screwed into the female screw of the mounting hole 11B.
The nut 5B is formed with an assembly hole 51B into which the chuck body 41 of the attachment / detachment device 4 is incorporated. A female screw 51 a that is screwed onto the outer peripheral surface of the chuck body 41 is formed in the mounting hole 51 </ b> B. An insertion hole 52B into which the detection electrode 2 or the comparison electrode 3 is inserted is formed at the bottom of the assembly hole 51B of the nut 5B. The insertion hole 52B and the insertion hole 12B communicate with each other.
On the outer peripheral surface of the chuck body 41, a male screw 41b is formed which is screwed into the female screw 51a of the mounting hole 51B of the nut 5B (see FIGS. 2B and 2C).

  Note that the chuck body 41, the collet chuck 42, the detection electrode 2 and the comparison electrode 3 have the same configurations as those in the first embodiment, and thus the same reference numerals are given and description thereof is omitted. In other respects, the same parts as those in the first embodiment are denoted by the same reference numerals.

Next, a procedure for arranging the ozone water concentration detection sensor 100B in the flow path 200 will be described.
First, the detection electrode 2 and the comparison electrode 3 are attached to the base 1B.
That is, the nut 5B is screwed and fixed to the mounting hole 11B of the base 1B in the tightening direction, and the chuck body 41 is screwed and fixed to the mounting hole 51B of the nut 5B in the tightening direction. The collet chuck 42 is inserted into the tightening hole 411. Next, the detection electrode 2 is inserted from the insertion hole 421 of one collet chuck 42, and the comparison electrode 3 is inserted from the insertion hole 421 of the other collet chuck 42.
Next, the collet chuck 42 is screwed into the tightening hole in the tightening direction to fix the collet chuck 42 to the chuck body 41. Thus, the detection electrode 2 and the comparison electrode 3 are attached to the base 1B.
Thereafter, the base on which the detection electrode 2 and the comparison electrode 3 are installed is fixed to the wall surface 201 forming the flow path 200 with the bolt V.
When adjusting the position of the detection electrode 2 and the comparison electrode 3 in the vertical direction (radial direction X of the flow path 200 (pipe)) in the flow path 200, the collet chuck 42 is temporarily attached to the chuck body 41. The position of the detection electrode 2 and the comparison electrode 3 in the vertical direction is adjusted by loosening the screwing. Then, the collet chuck 42 is again screwed into the chuck body 41 in the tightening direction and fixed while holding the positions of the detection electrode 2 and the comparison electrode 3 adjusted.
When adjusting the positions of the detection electrode 2 and the comparison electrode 3 in the left-right direction (the axial direction Y of the flow path 200 (pipe)) in the flow path 200, the nut 5B is screwed into the mounting hole 11B of the base 1B. The adjustment is performed by adjusting the tightening direction or the loosening direction as appropriate.

  In addition, when exchanging the detection electrode 2 and the comparison electrode 3, after removing the bolt V which fastens the base 1B and the wall surface 201, and further loosening the screwing of the collet chuck 42 to the chuck body 41, The detection electrode 2 and the comparison electrode 3 are removed from the collet chuck 42.

  As described above, according to the embodiment of the present invention, in addition to the collet chuck type attachment / detachment device 4 of the first embodiment, the positions of the detection electrode 2 and the comparison electrode 3 in the left-right direction (axial direction Y) of the flow path 200 are determined. Since the nut 5B to be adjusted is provided, the position of the detection electrode 2 and the comparison electrode 3 in the vertical direction (radial direction X) can be adjusted by the attachment / detachment device 4, and the detection can be performed by the nut 5B. Position adjustment in the left-right direction (axial direction Y) of the flow path 200 of the electrode 2 and the comparison electrode 3 can also be performed. Therefore, the detection electrode 2 and the comparison electrode 3 can be arranged at a position where the ozone water can easily come into contact with the ozone water, and the contact area with the ozone water can be increased, so that the detection accuracy can be further improved.

  In addition, this invention is not limited to the said embodiment, In the range which does not deviate from the summary of invention, it can change suitably.

1, 1A, 1B Base 2 Detection electrode 3 Comparison electrode 4, 4A Detachment device (first position adjusting means)
5B Nut (second position adjustment means)
100, 100A, 100B Ozone water concentration detection sensor 200 Flow path 201 Wall surface 202 Opening X Radial direction Y Axial direction

Claims (3)

An ozone water concentration detection sensor detachably provided on a wall surface forming a flow path through which ozone water flows,
An opening communicating with the flow path is formed in the wall surface,
A base provided detachably on the opening so as to close the opening;
A detection electrode and a comparison electrode provided through the base and having a tip disposed in the flow path,
The ozone water concentration detection sensor, wherein the detection electrode and the comparison electrode are detachably provided on the base.   2. The ozone water concentration detection sensor according to claim 1, wherein the base is provided with first position adjustment means for adjusting positions of the detection electrode and the comparison electrode in a radial direction of the flow path. .   The ozone water concentration according to claim 1 or 2, wherein the base is provided with second position adjusting means for adjusting the positions of the detection electrode and the comparison electrode in the axial direction of the flow path. Detection sensor.

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