JP2012047647A - Reference electrode - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a reference electrode which does not need to use gelatinized hydrophobic ion liquid that is hard to be produced, has hardness or viscosity of a prescribed level or more, and has a large thickness, leading to improvement of a product life.SOLUTION: The reference electrode 100 includes an inner electrode 1, and a housing 3 that houses a filler 2 for electrically connecting the inner electrode 1 and a sample liquid 4. The filler 2 forms a layer from the inner electrode 1 and between an opening 31 that is provided to the housing 3 to make the sample liquid 4 and the filler come into contact each other. The filler 2 is composed of a first layer 21 that comprises a water soluble electrolytic solution, and is formed so as to contact the inner electrode 1; a second layer 22 that comprises a hydrophobic ion liquid, and is formed so as to contact the first layer, and a third layer 23 that comprises a porous material, and is formed in the opening 21 so as to contact the second layer 22.

Description

  The present invention relates to a reference electrode serving as a basis for calculation of electrode potential and electrochemical measurement.

  An internal electrode used for presenting a constant reference potential in pH measurement or the like is, for example, an internal electrode made of silver / silver chloride or the like immersed in an internal solution made of a high-concentration KCl solution. Some of them are configured to come into contact with a sample liquid through a liquid junction made of a porous member.

By the way, when a high-concentration KCl solution is used as the internal liquid of the reference electrode, K ⁺ and Cl ⁻ always flow out into the sample liquid through the liquid junction on the side of the sample liquid, thereby reducing the KCl concentration of the internal liquid. Resulting in. In order to prevent the fluctuation of the reference potential due to the decrease in the KCl concentration, it is necessary to frequently replenish and replace the internal solution. In addition, in consideration of the volatility of the internal liquid, which is a liquid, there are design restrictions such as the need to increase the volume in the support tube that stores the internal liquid.

  For example, a hydrophobic ionic liquid in which the liquid junction is gelled while the KCl solution is used as an internal liquid in order to prevent fluctuations between the liquids, clogging of the liquid junction, or decrease due to the outflow of the KCl solution to the sample liquid. The present applicant has applied for a reference electrode configured as a salt bridge (see Patent Documents 1 and 2).

  However, in these reference electrodes, a small amount of ions constituting the ionic liquid flow out from the gelled hydrophobic ionic liquid in contact with the sample liquid to the sample liquid. Therefore, the ionic liquid in the gel may become a predetermined amount or less, and it may be difficult to extend the product life.

  To solve such a problem, it is conceivable to increase the thickness of the hydrophobic ionic liquid gel to include a large amount of ionic liquid. For example, the hydrophobic ionic liquid gel alone can keep the shape. Increasing the thickness and size of the gel while maintaining a certain degree of hardness is very difficult in terms of manufacturing technology and requires a large cost.

JP 2007-64971 A International Publication No. WO2008 / 032790

  The present invention has been made in view of the problems as described above, and it is not necessary to use a gelled hydrophobic ionic liquid having a predetermined hardness or viscosity that is difficult to manufacture and having a large thickness and the like. It is an object of the present invention to provide a reference electrode that can improve the product life.

That is, the reference electrode of the present invention is a reference electrode including a housing body that houses an internal electrode and a filler that electrically connects the internal electrode and the sample liquid. The filler forms a layer between the liquid and the opening provided in the container for contact with the filler, and the filler is made of a water-soluble electrolyte solution and is connected to the internal electrode. A first layer formed so as to be in contact; a second layer formed of a hydrophobic ionic liquid; and formed in contact with the first layer; a porous material; and in contact with the second layer. And a third layer formed in the opening. The “hydrophobic ionic liquid”, which will be described in detail later, comprises a combination of an organic or inorganic cation and an organic or inorganic anion, has a melting point of 100 ° C. or less, and has a solubility in water of several mM (mmol / Dm ³ ) or less hydrophobic salt is mainly meant. Here, the ionic liquid is also called an ionic liquid or a normally dissolved salt. Further, the “reference electrode” is synonymous with a reference electrode, a verification electrode, a reference electrode, and a comparison electrode. Further, in the present specification, “solution” and “liquid” are not only ordinary liquids, but also include not only ordinary liquids but also gelled and flowing states and states that can maintain a shape. is there.

  If it is such, since the porous material which comprises the 3rd layer is contacting the sample liquid and the hydrophobic ionic liquid of the 2nd layer does not contact the sample liquid directly, it comprises a hydrophobic ionic liquid. It is possible to suppress ions from flowing into the sample liquid. Further, since the second layer is covered by the third layer, it is not necessary to gel the hydrophobic ionic liquid of the second layer in order to maintain the shape. Accordingly, it is possible to eliminate the use of gelled hydrophobic ions, thereby eliminating the problem that the sealing function is lowered due to the thinning and thinning of the gel and the product life is shortened.

  In addition, since the first layer is composed of a water-soluble electrolyte solution and the second layer is composed of a hydrophobic ionic liquid, the first layer and the second layer do not dissolve in each other and are mixed. Even if it is, it can be separated naturally.

  For example, in order to prevent the aqueous electrolyte solution constituting the first layer and the hydrophobic ionic liquid constituting the second layer from being mixed when the reference electrode is tilted sideways, the first layer is constituted. The water-soluble electrolyte solution to be used may be a gelled one.

  As a specific embodiment for preventing the first layer and the second layer from intermingling so that the reference electrode can always be used immediately, the water solution constituting the first layer can be used. It is sufficient that the viscosity of the aqueous electrolyte solution is suppressed to become an emulsion, for example, 20 mPa · s, more preferably 100 mPa · s or more.

  In order to facilitate the production, the hydrophobic ionic liquid constituting the second layer may be a liquid that is not gelled.

  In order to make it easier to prevent the first layer and the second layer from being mixed, the hydrophobic ionic liquid constituting the second layer may be a gelled liquid. Furthermore, considering the ease of manufacturing, the hardness or viscosity of the hydrophobic ionic liquid of the second layer may be smaller than the hardness or viscosity of the hydrophobic ionic liquid of the third layer.

  As a specific aspect that can facilitate the manufacture even if the hydrophobic ionic liquid is gelled while suitably preventing the mixing of the first layer and the second layer, the hydrophobicity constituting the second layer is described as follows. The viscosity of the ionic liquid may be 300 mPa · s or more and 1000 mPa · s or less.

  Even if the first layer and the second layer are mixed, in order for the first layer and the second layer to be separated in this order naturally, the specific gravity of the water-soluble electrolyte solution constituting the first layer is As long as it is lighter than the specific gravity of the hydrophobic ionic liquid constituting the second layer.

  In order to prevent the hydrophobic ionic liquid itself constituting the second layer from passing through the porous material constituting the third layer and flowing out directly into the sample liquid, the porous material constituting the third layer May be hydrophilic. If it is such, since it is a hydrophobic ionic liquid that comprises the 2nd layer, it will be repelled on the surface of a hydrophilic porous material, and it can prevent passing a 3rd layer. .

  As another aspect for preventing the hydrophobic ionic liquid itself constituting the second layer from flowing out, the diameter of the pores of the porous material constituting the third layer is such that the hydrophobic ionic liquid constituting the second layer It is sufficient if the size is such that cannot enter.

  As a preferred embodiment for preventing the hydrophobic ionic liquid from flowing out, the pore diameter of the porous material constituting the third layer may be in the range of 100 nm to 100 μm.

  Specific embodiments of the porous material include those in which the porous material constituting the third layer is polycarbonate.

  Thus, according to the reference electrode of the present invention, the porous material constituting the third layer is configured so that the hydrophobic ionic liquid constituting the second layer and the sample liquid are not in direct contact with each other. It is possible to prevent ions constituting the ionic liquid from flowing into the sample liquid. In addition, since the second layer is covered with the container by the third layer, it is not necessary to use a gel with high hardness in order to maintain the shape. Therefore, the hydrophobic ionic liquid of the second layer may be a liquid or a gel having a low hardness that is easy to manufacture. That is, the gelled hydrophobic ionic liquid can not be used, and the problem that the gel of the hydrophobic ionic liquid is thinned and the product life is shortened can be eliminated.

The schematic diagram which shows the reference electrode which concerns on 1st Embodiment of this invention. The schematic diagram which shows the reference electrode concerning 2nd Embodiment of this invention. The typical sectional view showing the internal structure in the support tube tip part in a 2nd embodiment. The typical sectional view showing the internal structure in the support pipe tip part in modification of a 2nd embodiment. The typical sectional view showing the internal structure in the support pipe tip part in modification of a 2nd embodiment.

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

  As shown in FIG. 1, the reference electrode 100 according to the first embodiment includes a cylindrical support tube 3 (corresponding to a housing portion of the present invention), and an opening 31 provided at the tip of the support tube 3. And a filling material 2 for electrically connecting the internal electrode 1 and the sample liquid 4 is filled therein. The filler 2 is layered, and in particular, the porous material film constituting the third layer 23 provided in the opening 31 is fixed to the support tube 3 by the film fixing part 32.

  The support tube 3 accommodates the internal electrode 1 and the filler 2 and includes PP, PE, acrylic, PTFE (tetrafluoroethylene resin), PVDF (vinylidene fluoride resin), PEEK (polyethylene). A resin such as an ether / ether / ketone resin), glass, metal, ceramic, or the like is conceivable. In this embodiment, it shape | molds using PVDF. At the base end portion of the support tube 3, a seal packing 33 that comes into liquid-tight contact with the base end portion so that the filler 2 does not leak out of the support tube 3, and a cap 34 that covers the seal packing 33. Is provided.

  The distal end portion of the support tube 3 has a small outer diameter, and a male screw portion 32a is provided on the outer peripheral surface of the tip portion. The film fixing part 32 in which the part is formed is screwed. In addition, an accommodation groove for accommodating the O-ring 35 is provided on the distal end surface of the distal end portion concentrically with the central axis of the support tube 3. And the film | membrane by the porous material which is the 3rd layer 23 is provided so that the front end surface may be covered.

The internal electrode 1 is, for example, an Ag / AgCl electrode, and is configured by covering the internal silver with silver chloride. As other embodiments, an Hg / Hg ₂ Cl ₂ electrode or an Hg / Hg ₂ SO ₄ electrode may be used.

  As shown in FIG. 1, the filler 2 is filled so as to form a plurality of layers between the internal electrode 1 and the opening 31 at the tip of the support tube 3. More specifically, the filler 2 is made of a water-soluble electrolyte solution, and is formed of a first layer 21 formed so as to be in contact with the internal electrode 1, a hydrophobic ionic liquid, and the first layer 21. The second layer 22 formed so as to be in contact with the third layer 23 made of a gelled hydrophobic ionic liquid, which is in contact with the second layer 22 and formed in the opening 31. is there.

The water-soluble electrolyte solution constituting the first layer 21 is, for example, a KCl solution. In addition, as the water-soluble electrolyte solution, when the internal electrode 1 is made of Ag / AgCl, a solution containing Cl ⁻ can be used as long as it does not enter the hydrophobic ionic liquid of the second layer 22 described later. Further, since the hydrophobic ionic liquid of the second layer described later functions as a salt bridge, generation of an inter-liquid potential can be suppressed, and for example, a NaCl solution or the like can be used. Alternatively, an electrolyte solution composed of Cl ⁻ and the same cation as the cation of the hydrophobic ionic liquid described later may be used. This is because the same ions as those constituting the hydrophobic ionic liquid are not particularly problematic even if they enter from the electrolyte solution.

  This KCl solution is gelled and always covers the internal electrode 1 and is provided at least around the internal electrode 1 with a viscosity sufficient to seal the inside of the support tube 3 around it. Here, the method for gelling the water-soluble electrolyte solution is not particularly limited. For example, vinylidene fluoride-hexafluoropropylene copolymer, polymethyl methacrylate, polyacrylonitrile, polybutyl acrylate, and other synthetic rubbers. A method using a polymer such as The viscosity of the gel is adjusted by adjusting the mixing ratio of the water-soluble electrolyte solution and the polymer. More specifically, the viscosity of the water-soluble electrolyte solution constituting the first layer 21 is set to an extent that suppresses the formation of an emulsion, for example, 20 mPa · s, more preferably 100 mPa · s or more.

In the hydrophobic ionic liquid constituting the second layer 22, the cation is at least one of a quaternary ammonium cation, a quaternary phosphonium cation, and a quaternary arzonium cation, and the anion is [R _{1 ^{SO 2 NSO 2 R 2] -}} (R1, R2 are each a perfluoroalkyl group having 1 to 5 carbon atoms), fluorine and tetravalent borate ions containing boron, bis (2-ethylhexyl) sulfosuccinate Nate, AlCl ₄ ^- , Al ₃ Cl ₇ ⁻ , NO ₃ ⁻ , BF ₄ ⁻ , PF ₆ ⁻ , CH ₃ COO ⁻ , CF ₃ COO ⁻ , CF ₃ SO ₃ ⁻ , (CF ₃ SO ₂ ) ₂ N ⁻ , (CF ₃ SO _{2 ^{) 3 C -, AsF 6 -}} , SbF 6 -, F (HF) n -, CF 3 CF 2 CF 2 CF 2 SO 3 -, (CF 3 CF 2 SO 2) N ^-, or _CF 3 _CF 2 _CF 2 COO ^- those at least one or more can be mentioned, and is used appropriately selected according to the use of these hydrophobic ionic liquid, constituting a first layer 21 A function as a salt bridge is exhibited between the water-soluble electrolyte solution and the sample liquid.

  The hydrophobic ionic liquid constituting the second layer 22 is a liquid that is not gelled, and can be easily manufactured even if the thickness of the second layer 22 is large. Further, the specific gravity of the electrolyte solution constituting the first layer 21 is lighter than the specific gravity of the hydrophobic ionic liquid constituting the second layer 22.

  The third layer 23 is provided so as to close the opening 31, and is made of a porous film with polycarbonate. This porous membrane is hydrophilic and contains moisture in the sample liquid 4, but the hydrophobic ionic liquid is repelled on the surface. In addition, the pore diameter of the porous membrane is set to about 100 nm to 100 μm so that the hydrophobic ionic liquid constituting the second layer 22 cannot enter the inside of the porous membrane due to surface tension or the like. The viscosity of the hydrophobic ionic liquid may be set higher as the pore diameter is larger so that the surface tension or the like can be easily applied.

  According to the reference electrode 100 configured in this way, the porous film constituting the third layer 23 is in contact with the sample liquid 4, and the hydrophobic ionic liquid of the second layer 22 does not directly contact the sample liquid. Therefore, ions constituting the hydrophobic ionic liquid can be prevented from flowing out into the sample liquid 4. Further, since the second layer 22 is covered with the third layer 23 in the support tube 3, the hydrophobic ionic liquid does not need to be gelled in order to maintain the shape. Accordingly, the gelled hydrophobic ionic liquid can be prevented from being used for the reference electrode 100, and the problem that the sealing function is lowered and the product life is shortened due to the thinning and thinning of the gel can be eliminated. it can.

  In addition, since the first layer 21 is composed of a water-soluble electrolyte solution and the second layer 22 is composed of a hydrophobic ionic liquid, the first layer 21 and the second layer 22 may be dissolved together. The first layer 21 is lighter in specific gravity than the second layer 22 even if it is mixed, and the order of the layers can be restored simply by raising the reference electrode 100. Can be returned to.

  Further, since the water-soluble electrolyte solution constituting the first layer 21 is gelled so that there is no gap in the support tube 3, even when the reference electrode 100 is turned sideways, It is possible to prevent the second layer 22 from being mixed.

  Other embodiments will be described. In the first embodiment, the third-layer porous membrane is fixed by being sandwiched between the support tube main body and the membrane fixing portion 33, but may be provided in the opening 31 by other methods. For example, the porous membrane may be heat-sealed so as to cover the tip of the membrane fixing portion 33. Further, a porous film may be heat-sealed at the tip of the main body of the support tube 3.

  In the first embodiment, the hydrophobic ionic liquid constituting the second layer is in a liquid state that is not gelled, but may be gelled. In this case, it is preferable that the gel is made loose to facilitate the production. The specific viscosity of the hydrophobic ionic liquid constituting the second layer may be in the range of 300 mPa · s to 1000 mPa · s. By gelling the second layer in such a range, it is easy to manufacture and it is also possible to prevent the first layer and the second layer from being mixed. The hydrophobic ionic liquid may be gelled by the same method as the gelation of the water-soluble electrolyte solution described above.

  Moreover, in the said 1st Embodiment, although the water-soluble electrolyte solution which comprises a 1st layer was gelatinized, you may be a liquid.

  A multi-pinhole reference electrode 100 different from that in the above embodiment may be used. More specifically, the reference electrode 100 of the second embodiment is a glass support tube having a substantially cylindrical shape as shown in the external view of FIG. 2 and the enlarged view of the sample liquid 4 in FIG. 3 (corresponding to the container of the present invention). The support tube 3 contains an internal electrode 1 and is filled with a filler 2 that electrically connects the internal electrode 1 and the sample liquid 4. A lead wire 11 is connected to the internal electrode 1, and the lead wire 11 extends outside from the base end portion of the support tube 3 and is connected to a measuring device (not shown).

  The support tube 3 has an opening 31 formed at its tip so that the sample liquid 4 and the filler 2 can come into contact with each other. It is smaller than the end side.

  In the second embodiment, the third layer is provided so as to block only the protruding portion at the tip of the support tube. However, the third layer may have a thickness up to the inner side. As shown in FIG. 4, if the third layer 23 is made of a porous material in which a thin flat plate-like central portion is slightly protruded, the third layer is formed with respect to the support tube 3. Easy to catch and easy to fix.

  In addition, the opening 31 of the second embodiment has a hole formed straight, but for example, as shown in FIG. 5, the opening 31 is tapered, and the inside of the support tube 3. The opening diameter may be set larger than the opening diameter on the tip side. If it is such, it can make it easy to prevent that the porous material which comprises a 3rd layer falls from the opening part 31. FIG.

  In addition, the thicknesses of the first layer and the second layer can be appropriately changed. For example, the internal electrode may be in contact with the first layer and the second layer. In this case, the reference voltage may be prevented from fluctuating using a correction means such as temperature compensation. Moreover, you may use for the ion concentration measurement, pH measurement, etc. by combining the reference electrode of this invention and the electrode for a various measurement.

  In each of the above embodiments, the porous material constituting the third layer is formed in a film shape, but may have a shape other than the film. In addition, a material other than polycarbonate may be used, and a porous sheet-like film made of glass, glass fiber, ceramic, thermoplastic resin, or the like may be used. Examples of the thermoplastic resin include polypropylene, polyethylene, polyester, nylon, and PET other than polycarbonate. Moreover, you may adjust the hole of the porous material which comprises a 3rd layer, for example according to the viscosity of the hydrophobic ionic liquid which comprises the said 2nd layer. Specifically, a multi-pin hole is formed in the member constituting the third layer to make it porous, and the internal electrode and the sample liquid are electrically and appropriately adjusted by adjusting the hole diameter and number. While being connected, the hydrophobic ionic liquid of the second layer itself may be prevented from flowing into the sample liquid through the hole.

  In addition, various modifications and combinations of embodiments may be performed without departing from the spirit of the present invention.

DESCRIPTION OF SYMBOLS 100 ... Reference electrode 1 ... Internal electrode 2 ... Filler 21 ... 1st layer 22 ... 2nd layer 23 ... 3rd layer 3 ... Support tube (container)
4 ... Sample liquid

Claims (4)

A reference electrode including an internal electrode and a container that stores a filler that electrically connects the internal electrode and the sample liquid,
The filler forms a layer between the internal electrode and the opening provided in the container for the sample liquid and the filler to contact with each other;
The filler is made of a water-soluble electrolyte solution and is formed to be in contact with the internal electrode; and the second layer is made of a hydrophobic ionic liquid and is made to be in contact with the first layer; A reference electrode comprising a third layer formed of a porous material and in contact with the second layer and formed in the opening.   The reference electrode according to claim 1, wherein the water-soluble electrolyte solution constituting the first layer is gelled.   The reference electrode according to claim 1 or 2, wherein the hydrophobic ionic liquid constituting the second layer is gelled.   The reference electrode according to claim 1, wherein the specific gravity of the water-soluble electrolyte solution constituting the first layer is lighter than the specific gravity of the hydrophobic ionic liquid constituting the second layer.