JP2009098103A - Cover for sensor - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a cover for a sensor allowing the liquid physical property of liquid to be measured highly stably with a sensor without using a gas-liquid separator. <P>SOLUTION: This cover 1 for the sensor is attached to the sensor for measuring the liquid physical property of the liquid, and has a multiple structure where two or more cylindrical objects 10 and 20 are arranged in a multiple manner. A sensor insertion hole 11a for inserting the sensor is formed at one end of each of the cylindrical objects 10 and 20, the other end of at least one cylindrical object 20 is sealed, distribution ports 12a and 22a for passing the liquid are formed in the side surface of each of the cylindrical objects 10 and 20, and at least a part of the distribution port 12a of the outermost cylindrical object 10 is blocked by the side surface 24 of the other cylindrical object 20. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a sensor cover attached around various sensors installed in a liquid.

In a cooling water pit, a water treatment tank, a pipe, and the like, a sensor such as an electrode may be installed in order to measure a liquid property such as an ion concentration in the liquid.
By the way, when a liquid flows violently, it entrains air and includes bubbles. When the liquid physical properties of a liquid containing bubbles are measured with a sensor, the bubbles may adhere to the sensor, which may reduce the measurement stability.
Therefore, Patent Documents 1 and 2 propose a method in which a liquid from which bubbles are separated by a gas-liquid separator is used for measurement. Patent Document 3 proposes a method of bringing a liquid into contact so that bubbles do not easily adhere to the sensor.
Japanese Patent Laid-Open No. 2003-14644 JP 2005-81830 A JP 2006-317206 A

However, the methods described in Patent Documents 1 and 2 have a problem that a space for installing a gas-liquid separator and a pipe for connecting to the gas-liquid separator is required and the equipment cost increases. Was.
In addition, the method described in Patent Document 3 cannot sufficiently suppress the adhesion of bubbles to the sensor, and thus the measurement stability is not sufficiently improved.
The present invention has been made in view of the above circumstances, and an object of the present invention is to provide a sensor cover that enables liquid properties of a liquid to be measured with high stability using a sensor without using a gas-liquid separator. .

[1] A sensor cover attached to a sensor for measuring a liquid property of a liquid,
Having a multiple structure in which two or more cylindrical bodies are arranged in multiple,
At one end of each cylindrical body, a sensor insertion hole for inserting a sensor is formed,
The other end of the at least one tubular body is sealed,
A flow hole for passing a liquid is formed on the side surface of each cylindrical body, and at least a part of the flow hole of the outermost cylindrical body is blocked by the side surface of the other cylindrical body. Sensor cover.
[2] The through hole of each cylindrical body is arranged so as not to communicate linearly from the outside of the outermost cylindrical body to the inside of the innermost cylindrical body. cover.
[3] A cylindrical body other than the innermost cylindrical body has a shoulder portion that gradually becomes thinner toward the sensor insertion hole side, and a bubble discharge hole is formed in the shoulder portion [1] or [ 2] The sensor cover according to [2].
[4] The sensor cover according to any one of [1] to [3], wherein the sensor is a liquid film type ion electrode.

  If the sensor cover of the present invention is used, the liquid physical properties of the liquid can be measured with high stability by the sensor without using the gas-liquid separator.

An embodiment of a sensor cover (hereinafter abbreviated as a cover) of the present invention will be described.
FIG. 1 shows a cover according to this embodiment. The sensor cover 1 according to the present embodiment includes a first cylindrical body 10 and a second cylindrical body 20 disposed inside the first cylindrical body 10 and has a double structure. It is what has become.

(First cylindrical body)
The first cylindrical body 10 in the present embodiment includes a cylindrical insertion portion 11 in which a sensor insertion hole 11a for inserting a sensor is formed, a cylindrical main body portion 12 thicker than the insertion portion 11, and a main body. A shoulder portion 13 that gradually becomes thinner from the portion 12 side toward the insertion portion 11 side. The main body 12 of the first cylindrical body 10 is open at the end opposite to the insertion portion 11. In addition, a bubble discharge hole 13 a is formed in the shoulder portion 13.

The overall length of the first cylindrical body 10 is preferably 14 to 18 cm, although it depends on the dimensions of the sensor attached to the cover 1. If the length of the entire first cylindrical body 10 is 14 cm or more, the sensor and the second cylindrical body 20 that are normally used can be easily accommodated, and if the length is 18 cm or less, the cover 1 can be reduced in size. .
Although the internal diameter of the main-body part 12 of the 1st cylindrical body 10 is based also on the dimension of the sensor attached to the cover 1, it is preferable that it is 4-10 cm. If the inner diameter of the main body 12 is 4 cm or more, the sensor that is normally used and the second cylindrical body 20 can be easily accommodated, and if it is 10 cm or less, the cover 1 can be made small.

A circular circulation hole 12 a is formed on the side surface of the main body 12 of the first cylindrical body 10.
The hole diameter of the flow hole 12a of the first cylindrical body 10 is preferably 10 to 20 mm. If the hole diameter of the flow hole 12a is 10 mm or more, the liquid can be easily passed from the outside to the inside of the first cylindrical body 10, and if it is 20 mm or less, the bubbles can be further separated from the liquid.

  It is preferable that the area ratio of the opening area of the flow hole 12a of the first tubular body 10 when the area of the entire side surface of the main body 12 is 100% by mass is 3 to 10% by area. If the area ratio of the opening area of the flow hole 12a is 3 area% or more, the liquid can be easily passed from the outside to the inside of the first cylindrical body 10, and if it is 10 area% or less, the liquid to the bubbles Can be separated more.

  It is preferable that the bubble discharge hole 13a of the 1st cylindrical body 10 is circular shape, and the hole diameter is 5-10 mm. If the hole discharge hole 13a has a hole diameter of 5 mm or more, the bubbles can be easily discharged from between the first tubular body 10 and the second tubular body 20 to the outside of the first tubular body 10. Moreover, if the hole diameter of the bubble discharge hole 13a is 10 mm or less, the inflow of the liquid from the bubble discharge hole 13a can be suppressed.

  The material in particular of the 1st cylindrical body 10 is not restrict | limited, For example, plastics, such as a metal and a polypropylene, ceramics etc. are mentioned. Among these, when the 1st cylindrical body 10 is made from metal, since electrical noise can be shielded, the stability of a measurement improves more. Further, when the first cylindrical body 10 is made of plastic, it can be easily formed into a desired shape.

(Second cylindrical body)
Similarly to the first cylindrical body 10, the second cylindrical body 20 has a cylindrical insertion portion 21 in which a sensor insertion hole 21a for inserting a sensor is formed, and an insertion portion, as shown in FIG. 21 has a cylindrical main body portion 22 thicker than 21 and a shoulder portion 23 that gradually becomes thinner from the main body portion 22 side toward the insertion portion 21 side.
However, the outer diameter of the main body portion 22 of the second cylindrical body 20 is smaller than the inner diameter of the main body portion 12 of the first cylindrical body 10. Further, unlike the first cylindrical body 10, the end of the main body portion 22 of the second cylindrical body 20 on the side opposite to the insertion portion 21 is sealed, and the shoulder portion 23 has a bubble discharge hole. Not formed. Note that bubble discharge holes may also be formed in the shoulder portion 23.
The material of the second cylindrical body 20 is the same as that of the first cylindrical body 10, but need not be the same as the material of the first cylindrical body 10.

Although the length of the whole 2nd cylindrical body 20 is based also on the dimension of the sensor attached to the cover 1, it is preferable that it is 12-16 cm. If the length of the entire second cylindrical body 20 is 12 cm or more, a normally used sensor can be easily accommodated, and if it is 16 cm or less, the cover 1 can be made small.
Although the internal diameter of the main-body part 22 of the 2nd cylindrical body 20 is based also on the dimension of the sensor attached to the cover 1, it is preferable that it is 3-8 cm. If the inner diameter of the main body 22 is 3 cm or more, a normally used sensor can be easily accommodated, and if it is 8 cm or less, the cover 1 can be made small.

  A circular circulation hole 22 a is formed on the side surface of the main body portion 22 of the second cylindrical body 20. The diameter of the flow hole 22a of the second cylindrical body 20 is preferably 10 to 20 mm. If the hole diameter of the flow hole 22a is 10 mm or more, the liquid can be easily passed from the outside to the inside of the second cylindrical body 20, and if it is 20 mm or less, the bubbles can be further separated from the liquid.

  The area ratio of the opening area of the flow hole 22a of the second cylindrical body 20 when the area of the entire side surface of the main body 22 is 100% by mass is preferably 3 to 10% by area. If the area ratio of the opening area of the flow hole 22a is 3 area% or more, the liquid can be easily passed from the outside to the inside of the second cylindrical body 20, and if it is 10 area% or less, the liquid to the bubble Can be separated more.

(Arrangement of each cylindrical body)
It is preferable that the space | interval of the main-body part 12 of the 1st cylindrical body 10 and the main-body part 22 of the 2nd cylindrical body 20 is 5-10 mm. If the distance is 5 mm or more, a sufficient amount of liquid can be allowed to flow between the first cylindrical body 10 and the second cylindrical body 20, and if it is 10 mm or less, bubbles can be generated from the liquid. More separable.

In this embodiment, the flow holes 12a of the first tubular body 10 and the flow holes 22a of the second tubular body 20 are all the second flow holes 12a of the first tubular body 10 being the second. It is blocked by the side surface 24 of the cylindrical body 20 and is arranged so as not to communicate linearly from the outside of the first cylindrical body 10 to the inside of the second cylindrical body 20.
Here, "the entire flow hole 12a of the first cylindrical body (outermost cylindrical body) 10 is blocked by the side surface 24 of the second cylindrical body (other cylindrical body) 20" In the front view of the flow hole 12a of the first tubular body 10, only the side surface 24 of the second tubular body 20 is visible through the flow hole 12a of the first tubular body 10.
In addition, “the first cylindrical body (outermost cylindrical body) 10 does not communicate linearly from the outside of the second cylindrical body (innermost cylindrical body) 20”. As shown in FIG. 3, the flow holes 12a and 22a do not overlap with each other even when the flow holes 12a of the first cylindrical body 10 are viewed from any direction (for example, the oblique directions of arrows S1 and S2 in FIG. 3). That is.
In this embodiment, the flow hole 12a of the first tubular body 10 and the flow hole 22a of the second tubular body 20 are not at the same height, but in FIG. Shown to be at the same height.

(how to use)
When the cover 1 is attached to the sensor, as shown in FIGS. 4 and 5, the sensor 2 is inserted and fixed in the sensor insertion hole 11a and the sensor insertion hole 21a. Normally, the sensor 2 has a holding portion 2b for holding the sensor body 2a. In this embodiment, the holding portion 2b is fitted into the sensor insertion hole 11a and the sensor insertion hole 21a to fix the sensor 2. ing.
Then, the sensor 2 with the cover 1 attached is placed in the liquid and used for measurement.

Examples of the liquid properties measured by the sensor 2 to which the cover 1 is attached include pH, ion concentration, electrical conductivity, oxidation-reduction potential, dissolved oxygen concentration, and the like.
In particular, when the liquid physical property measured by the sensor 2 is an ion concentration, the type of the sensor 2 is classified according to the material of the ion sensitive film such as a solid film type, a liquid film type, a glass film type, and a diaphragm type. Of these, a liquid film type is suitable. This is because the liquid film type has a hydrophobic surface and easily attaches bubbles, so that the effect of the present invention is particularly exerted.
The liquid in which the sensor 2 is disposed may be water or an organic solvent, but is usually water.
Examples of the place where the sensor 2 is installed include a cooling tower, a water treatment facility, a public bath, a lake, a river, and a pool.

(Function and effect)
As described above, in the cover 1, the flow hole 12 a of the first tubular body 10 and the flow hole 22 a of the second tubular body 20 are the same as the second flow hole 12 a of the first tubular body 10. Is arranged so as not to communicate linearly from the outside of the first cylindrical body 10 to the inside of the second cylindrical body 20, and the second cylindrical shape. The end of the body portion 22 of the body 20 opposite to the insertion portion 21 is sealed. Therefore, the liquid that has entered the inside of the first cylindrical body 10 from the flow hole 12a is temporarily retained between the first cylindrical body 10 and the second cylindrical body 20, and the second Direct flow into the cylindrical body 20 can be suppressed. Between the first cylindrical body 10 and the second cylindrical body 20, the flow of the liquid outside the first cylindrical body 10 is easily blocked, and the liquid is more liquid than the outside of the first cylindrical body 10. The flow of is calm. Therefore, the bubbles contained in the liquid can be lifted and separated. Furthermore, since the bubble discharge hole 13a is formed in the shoulder portion 13 of the first cylindrical body 10, the bubbles can be easily discharged from between the first cylindrical body 10 and the second cylindrical body 20. .
Since the liquid from which the bubbles are separated passes through the flow hole 22a of the second cylindrical body 20 and comes into contact with the sensor 2, the bubbles are unlikely to adhere to the sensor 2. Moreover, since the cover 1 is composed of multiple cylindrical bodies, the temperature of the liquid around the sensor is unlikely to fluctuate.
Therefore, by attaching the cover 1 to the sensor 2, even when the liquid physical property of the liquid flowing vigorously is measured by the sensor 2, it can be measured with high stability without using the gas-liquid separator.

(Other forms)
The cover of the present invention is not limited to the above-described embodiment example. For example, the shape of the flow hole does not have to be circular, and may be, for example, an elliptical shape, a triangular shape, a polygonal shape such as a rectangular shape, or a slit shape.
In the above embodiment, the insertion portions 11 and 21 and the main body portions 12 and 22 are cylindrical. However, in the present invention, other shapes such as an elliptical shape, a triangular shape, and a quadrangular shape are used. Also good.
In the above-described embodiment, the first cylindrical body 10 and the second cylindrical body 20 have the insertion portion 11, the main body portion 12, and the shoulder portion 13. However, the present invention is not limited to this. For example, the sensor insertion holes 11a and 21 may have a hemispherical portion formed at the top and a straight body portion.
In the above embodiment, the end portion of the main body portion 22 of the second cylindrical body 20 opposite to the insertion portion 21 is sealed, but the main body portion 12 of the first cylindrical body 10 is sealed. The end portion on the opposite side to the insertion portion 11 may be sealed. Moreover, both the main-body part 12 of the 1st cylindrical body 10 and the main-body part 22 of the 2nd cylindrical body 20 may be sealed.
Further, the flow hole 12 a of the first cylindrical body 10 and the flow hole 22 a of the second cylindrical body 20 are linear from the outside of the first cylindrical body 10 to the inside of the second cylindrical body 20. It does not need to be arranged so as not to communicate with. However, in the point which can isolate | separate a bubble more, like the said embodiment, it arrange | positions so that it may not communicate linearly from the exterior of the 1st cylindrical body 10 to the inside of the 2nd cylindrical body 20. Is preferred.

In the present invention, only a part of the flow hole 12a of the first tubular body 10 may be blocked by the side surface 24 of the second tubular body 20 (see FIGS. 6 and 7). When only a part of the circulation hole 12a is blocked by the side surface 24 of the second cylindrical body 20, as shown in FIG. 6, only a part of the circulation hole 12a is the second cylinder. It may be blocked by the side surface 24 of the shaped body 20. In addition, as shown in FIG. 7, only a part of the flow holes 12a is blocked by the side surface 24 of the second cylindrical body 20, and the whole of the second flow holes 12b is the second cylinder. It may be blocked by the side surface 24 of the shaped body 20.
Thus, even if only a part of the flow hole 12a of the first cylindrical body 10 is blocked by the side surface 24 of the second cylindrical body 20, the bubbles in the liquid can be separated, but the bubbles can be further separated. In terms of the point, it is preferable that all the through holes 12a of the first cylindrical body 10 are blocked by the side surfaces 24 of the second cylindrical body 20 as in the above-described embodiment.

  Further, the cover of the above embodiment example has a double structure having two cylindrical bodies, but a multiple structure such as a triple structure having three cylindrical bodies and a quadruple structure having four cylindrical bodies. There may be.

  A sensor composed of an ion-selective electrode was installed in the pit of a cooling tower having a retained water amount of 10 tons. During the operation of the cooling tower, the concentration of the chemical for preventing scale adhesion in the cooling water was measured with a sensor (Orchase III manufactured by Organo Corporation). The drug concentration was fixed at 400 mg / L.

(Example)
The cover 1 shown in FIG. 1 was attached to the sensor, and the drug concentration was measured. The measurement result of the drug concentration is shown in FIG.
As the 1st cylindrical body 10 and the 2nd cylindrical body 20 of the cover 1, the following were used.
Dimensions of the first cylindrical body 10: total length 18 cm, inner diameter 9 cm of the main body 12
Hole diameter of flow hole 12a of first tubular body 10: 3.14 cm ²
Total number of flow holes 12a of the first cylindrical body 10: 12 (rows with three flow holes arranged in the length direction are arranged in four rows at equal intervals on the side surface).
Dimensions of second cylindrical body 20: overall length 15 cm, inner diameter of main body 22 7.5 cm
Hole diameter of flow hole 22a of second cylindrical body 20: 3.14 cm ²
Total number of flow holes 22a of second cylindrical body 20: 8 (four rows with two flow holes arranged in the length direction are arranged at equal intervals on the side surface).
Material of the first tubular body 10 and the second tubular body 20: polypropylene The flow hole 12a of the first tubular body 10 and the flow hole 22a of the second tubular body 20 are the first tubular body. The entire 10 through holes 12a are blocked by the side surface of the second cylindrical body 20, and are arranged so as not to communicate linearly from the outside of the first cylindrical body 10 to the inside of the second cylindrical body 20. Has been.

(Comparative example)
The drug concentration was measured in the same manner as in Example except that the cover 1 was not attached to the sensor. The measurement result of the drug concentration is shown in FIG.

As is apparent from the measurement result of the chemical concentration for preventing adhesion of scale in the cooling water shown in FIG. 8, when the cover 1 described above is attached to the sensor, bubbles are difficult to adhere to the sensor, so the measurement value is stable. It was.
On the other hand, when the cover 1 was not attached to the sensor, the measured value was not stable.

It is a perspective view which shows one Embodiment of the cover for sensors of this invention. It is a perspective view which shows the 2nd cylindrical body which comprises the cover for sensors shown in FIG. It is a figure which shows arrangement | positioning of the through-hole in this example of an embodiment. It is a perspective view which shows the aspect which attached the cover for sensors shown in FIG. 1 to the sensor. It is sectional drawing which shows the aspect which attached the cover for sensors shown in FIG. 1 to the sensor. It is a side view which shows the other embodiment of the sensor cover of this invention. It is a side view which shows the other embodiment of the sensor cover of this invention. It is a graph which shows the measurement result of the chemical | medical agent density | concentration for scale adhesion prevention in an Example and a comparative example.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Cover 2 Sensor 2a Sensor main body 2b Holding part 10 1st cylindrical body 11 Insertion part 11a Sensor insertion hole 12 Main body part 12a, 12b Flowing hole 13 Shoulder part 13a Bubble discharge hole 20 2nd cylindrical body 21 Insertion part 21a Sensor insertion hole 22 Body 22a Flow hole 23 Shoulder 24 Side

Claims (4)

A sensor cover attached to a sensor for measuring liquid physical properties of a liquid,
Having a multiple structure in which two or more cylindrical bodies are arranged in multiple,
At one end of each cylindrical body, a sensor insertion hole for inserting a sensor is formed,
The other end of the at least one tubular body is sealed,
A flow hole for passing a liquid is formed on the side surface of each cylindrical body, and at least a part of the flow hole of the outermost cylindrical body is blocked by the side surface of the other cylindrical body. Sensor cover.   The flow hole of each cylindrical body is disposed so as not to communicate linearly from the outside of the outermost cylindrical body to the inside of the innermost cylindrical body. Sensor cover.   The cylindrical body other than the innermost cylindrical body has a portion that becomes gradually thinner toward the sensor insertion hole side, and a bubble discharge hole is formed in the portion. The sensor cover described in 1.   The sensor cover according to claim 1, wherein the sensor is a liquid film type ion electrode.

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