JP2013213840A - Electrode, electrochemical cell, analyzer, method of manufacturing electrode and method of manufacturing electrochemical cell - Google Patents
Electrode, electrochemical cell, analyzer, method of manufacturing electrode and method of manufacturing electrochemical cell Download PDFInfo
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- JP2013213840A JP2013213840A JP2013154095A JP2013154095A JP2013213840A JP 2013213840 A JP2013213840 A JP 2013213840A JP 2013154095 A JP2013154095 A JP 2013154095A JP 2013154095 A JP2013154095 A JP 2013154095A JP 2013213840 A JP2013213840 A JP 2013213840A
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Landscapes
- Investigating Or Analysing Biological Materials (AREA)
Abstract
Description
本発明は、電気化学測定用電極,電気化学セルおよび電気化学的分析装置ならびにそれらの製造方法に係り、特に、血液・尿など液体試料中に含まれる微量の化学的成分を電気化学的に分析する電極,電気化学セルおよび分析装置に関する。 The present invention relates to an electrode for electrochemical measurement, an electrochemical cell, an electrochemical analyzer, and a method for producing them, and in particular, electrochemically analyzes a trace amount of chemical components contained in a liquid sample such as blood and urine. The present invention relates to an electrode, an electrochemical cell, and an analyzer.
電気化学測定は、比較的簡単な装置構成で高感度測定が可能であり、分析化学の分野で多用されている。電気化学測定手法として、ポテンシオメトリ,アンペロメトリ,ボルタンメトリ,インピーダンス測定等、さらにこれらと他の検出手段、例えば光学素子等との組み合わせにより光子を検出する方法がある。 Electrochemical measurement enables high-sensitivity measurement with a relatively simple apparatus configuration, and is frequently used in the field of analytical chemistry. Electrochemical measurement methods include potentiometry, amperometry, voltammetry, impedance measurement, and the like, and methods for detecting photons by combining these with other detection means such as optical elements.
一般的に測定に用いられる電極は、その化学的な安定性に優れた特性から白金族金属、とりわけ白金が多用されている。近年、血液・尿など液体試料に含まれる化学的成分の分析においてもフローセル内に組み込む電極として白金が用いられている。例えば、特許文献1に記載のように、血液や尿中の化学的成分を連続計測する場合、洗浄、本測定を始めとして、一分析毎に作用極,対極間に複数の電位印加するプロセスを経ることで繰り返し計測を可能としている。 In general, platinum group metals, particularly platinum, is frequently used for electrodes used for measurement because of its excellent chemical stability. In recent years, platinum has been used as an electrode incorporated in a flow cell in the analysis of chemical components contained in liquid samples such as blood and urine. For example, as described in Patent Document 1, when chemical components in blood and urine are continuously measured, a process of applying a plurality of potentials between the working electrode and the counter electrode for each analysis, including washing and main measurement, is performed. Through this, repeated measurement is possible.
白金と金属酸化物の混合材料を電極として用いている例としては、特許文献2において、金属基体表面に酸化錫と酸化アンチモンとが固溶して形成された表面層を具備した電極であって、金属基体と表面層との間に、白金族金属またはその酸化物と第4族または第5族金属の酸化物の混合層を中間層として設けた電極が開示されている。また、特許文献3において、チタンまたはチタン合金体表面上に中間層を介して酸化イリジウムと白金と酸化ニオブ,酸化タンタル,酸化ジルコニウムより少なくとも1種の金属酸化物からなる混合金属酸化物から構成される外層を設けた電解用電極が開示されている。 As an example of using a mixed material of platinum and metal oxide as an electrode, in Patent Document 2, an electrode having a surface layer formed by solid solution of tin oxide and antimony oxide on the surface of a metal substrate. An electrode is disclosed in which a mixed layer of a platinum group metal or an oxide thereof and a group 4 or group 5 metal oxide is provided as an intermediate layer between a metal substrate and a surface layer. Further, in Patent Document 3, a mixed metal oxide composed of at least one metal oxide of iridium oxide, platinum, niobium oxide, tantalum oxide, and zirconium oxide is formed on the surface of titanium or a titanium alloy body via an intermediate layer. An electrode for electrolysis provided with an outer layer is disclosed.
特許文献4では、酸化物半導体又は固体電解質表面に前記構成金属の酸化物と白金を含む電極材料を被覆した酸素センサの電極が開示されている。 Patent Document 4 discloses an electrode of an oxygen sensor in which an oxide semiconductor or a solid electrolyte surface is coated with an electrode material containing the constituent metal oxide and platinum.
白金族金属、特に白金が電極として使用された場合、実験的に行うような数十〜数百回の分析においては大変優れた特性を示す。しかしながら、特許文献1に示したような分析系、例えば、血液・尿など液体試料に含まれる化学的成分の分析において、成分中に蛋白質やハロゲン元素を多く含む試料を長期間にわたり繰り返し測定する場合、あるいは電極表面を洗浄するための洗浄剤として水酸化カリウムなどの強アルカリ成分を含む試料を電極表面に接触させ、電圧を長期間反復印加した場合、電極表面が徐々に侵食され、表面状態が変動し、結果的に測定結果に悪影響を与えるという問題があった。 When a platinum group metal, particularly platinum, is used as an electrode, it exhibits very excellent characteristics in the analysis of several tens to several hundreds of times that is experimentally performed. However, in the analysis system shown in Patent Document 1, for example, in the analysis of chemical components contained in a liquid sample such as blood and urine, when a sample containing a large amount of protein or halogen element is repeatedly measured over a long period of time Alternatively, when a sample containing a strong alkali component such as potassium hydroxide is brought into contact with the electrode surface as a cleaning agent for cleaning the electrode surface, and the voltage is repeatedly applied for a long period of time, the electrode surface is gradually eroded and the surface state is changed. There is a problem that the measurement results fluctuate and adversely affect the measurement results.
特許文献2では、金属基体と実際に電気化学反応が生じる酸化錫と酸化アンチモンとの固溶体との間の密着性および導電性向上を図るために中間層として白金と金属酸化物混合材料が用いられている。文献2では、白金と金属酸化物混合材料を電気化学反応を生じさせる表面として用いるものではない。酸化錫と酸化アンチモンの固溶体が実際に電気化学反応を生じさせる表面となるが、本発明者が対象とする、強アルカリ成分を含む試料においては、電極表面からの溶出が著しく、表面状態が大きく変動する結果、分析データの安定性向上には繋がらないものであった。 In Patent Document 2, a mixed material of platinum and metal oxide is used as an intermediate layer in order to improve adhesion and conductivity between a metal substrate and a solid solution of tin oxide and antimony oxide that actually cause an electrochemical reaction. ing. In Document 2, platinum and metal oxide mixed materials are not used as a surface for causing an electrochemical reaction. The solid solution of tin oxide and antimony oxide is the surface that actually causes the electrochemical reaction. However, in the sample containing the strong alkali component, which is the object of the present inventor, the elution from the electrode surface is remarkable and the surface state is large. As a result of fluctuation, the stability of the analysis data was not improved.
特許文献3では、外層の混合金属酸化物が塗布,焼成により形成された電極材料であり、前記材料は海水の電解,金属の表面処理,金属箔の製造,回収等の陽極として効果を示すことが知られているが、本発明者らが対象とする、成分中に蛋白質やハロゲン元素を多く含む試料を長期間にわたり繰り返し測定する場合、あるいは電極表面を洗浄するための洗浄剤として水酸化カリウムなどの強アルカリ成分を含む試料を電極表面に接触させて電圧を長期間反復印加する場合においては、電極の消耗が激しく、電極表面状態の変動が大きくなり、結果的に分析データの安定性向上には効果が小さいものであった。また、前記材料の電極表面にはクラックが存在するため、液体試料の残存が次の試料の測定結果に悪影響を及ぼす場合が見られた。 In Patent Document 3, an outer layer mixed metal oxide is an electrode material formed by coating and baking, and the material exhibits an effect as an anode for seawater electrolysis, metal surface treatment, metal foil production, recovery, etc. However, potassium hydroxide is used as a cleaning agent for cleaning the electrode surface when a sample containing a large amount of protein or halogen element in its components is repeatedly measured over a long period of time. When a sample containing a strong alkali component such as is in contact with the electrode surface and a voltage is repeatedly applied for a long period of time, the electrode is heavily consumed and the electrode surface condition fluctuates greatly, resulting in improved stability of the analytical data The effect was small. Further, since cracks exist on the electrode surface of the material, it was observed that the remaining liquid sample adversely affects the measurement result of the next sample.
特許文献4では、例えば酸素センサの検出電極として安定化ジルコニアを固体電解質とする場合、その表面に白金とジルコニウム酸化物の混合物の塗布することにより、下地の固体電解質との密着性を向上させ、また三相界面の形成による反応効率の向上を達成している。詳細は記載されていないが、反応効率の向上の効果が得られていることから、白金とジルコニウムの混合物の膜密度は低いと考えられる。すなわち、前記混合物は本発明者らが対象とする、液体試料に含まれる化学的成分を繰り返し測定する電極としては、膜中への液体試料の残存により測定結果の信頼性が低下するおそれが考えられる。 In Patent Document 4, for example, when stabilized zirconia is used as a solid electrolyte as a detection electrode of an oxygen sensor, by applying a mixture of platinum and zirconium oxide to the surface, adhesion with a solid electrolyte as a base is improved, In addition, the reaction efficiency is improved by the formation of a three-phase interface. Although details are not described, it is considered that the film density of the mixture of platinum and zirconium is low because the effect of improving the reaction efficiency is obtained. That is, the above mixture is an electrode for which the present inventors are intended to repeatedly measure chemical components contained in a liquid sample, and there is a possibility that the reliability of the measurement result may be reduced due to the liquid sample remaining in the film. It is done.
本発明者らが鋭意検討した結果、血液・尿など液体試料に含まれる極微量濃度の化学的成分を同一の電極を用いて複数回測定する分析においては、電極の表面状態、特に結晶組織および配向性が分析データに影響を及ぼすことがわかってきた。本発明の目的は、長期間にわたりデータが安定で適正な分析測定を行うことができる電極、その電極を用いた電気化学セルおよび電気化学的分析装置を実現することである。 As a result of intensive studies by the present inventors, in an analysis in which a very small concentration of a chemical component contained in a liquid sample such as blood and urine is measured a plurality of times using the same electrode, the surface state of the electrode, particularly the crystal structure and It has been found that orientation affects analytical data. An object of the present invention is to realize an electrode capable of performing appropriate analytical measurement with stable data over a long period of time, an electrochemical cell using the electrode, and an electrochemical analyzer.
上記目的を達成するために、本発明は以下のように構成される。 In order to achieve the above object, the present invention is configured as follows.
本発明の電極は、液体試料中に含まれる化学的成分の電気化学的応答を測定する電気化学的分析装置に用いる電気化学測定用電極において、白金または白金合金を母材として母材中に、ジルコニウム,タンタル,ニオブからなる群より選ばれる金属の酸化物が分散して含有される複合材料を用いることを特徴とする電気化学測定用電極である。白金または白金合金中における含有比率を金属換算で0.005〜1%とする。尚、本明細書における、化学的成分の含有比率の百分率は重量%で記述する。 The electrode of the present invention is an electrode for electrochemical measurement used in an electrochemical analyzer for measuring an electrochemical response of a chemical component contained in a liquid sample. In the base material using platinum or a platinum alloy as a base material, An electrode for electrochemical measurement, characterized by using a composite material in which an oxide of a metal selected from the group consisting of zirconium, tantalum, and niobium is dispersed. The content ratio in platinum or a platinum alloy is 0.005 to 1% in terms of metal. In this specification, the percentage of the content ratio of the chemical component is described in wt%.
本発明の電極は、電極表面のX線回折測定より得られる結晶方位の配向率(%)を、I(hkl)/ΣI(hkl)×100(但し、I(hkl)は各面の回折強度積分値であり、ΣI(hkl)は(hkl)の回折強度積分値の総和)とすると、得られる複数の結晶方位の内の一つの結晶方位の配向率が80%以上とする電極である。 In the electrode of the present invention, the crystal orientation ratio (%) obtained by X-ray diffraction measurement on the electrode surface is I (hkl) / ΣI (hkl) × 100 (where I (hkl) is the diffraction intensity of each surface) An integrated value, where ΣI (hkl) is the sum of the integrated values of diffraction intensity of (hkl), this is an electrode in which the orientation rate of one crystal orientation among the obtained crystal orientations is 80% or more.
本発明の電極は、電極表面の一部を除き、電極材料を絶縁樹脂に包埋した電極である。 The electrode of the present invention is an electrode in which an electrode material is embedded in an insulating resin except for a part of the electrode surface.
本発明の電気化学セルは、液体試料中に含まれる化学的成分の電気化学的応答を測定する電気化学セルであり、対極,参照極および作用極として上述した本発明の電極をセル内部に配置する電気化学セルである。上述の電気化学セルに、液体試料をセル内部へ注入する注入口およびセル外部へ排出する排出口を配置したフローセルとしてもよい。 The electrochemical cell of the present invention is an electrochemical cell that measures the electrochemical response of chemical components contained in a liquid sample, and the above-described electrode of the present invention is disposed inside the cell as a counter electrode, a reference electrode, and a working electrode. It is an electrochemical cell. The electrochemical cell described above may be a flow cell in which an inlet for injecting a liquid sample into the cell and an outlet for discharging it out of the cell are arranged.
本発明の電気化学的分析装置は、上述の本発明の電気化学セルと、上記電気化学セル内へ測定溶液,緩衝溶液および洗浄溶液を注入する溶液注入手段と、上記作用極,対極,参照極に電位を印加する電位印加手段と、上記作用極,対極,参照極に接続され上記測定溶液の電気化学的特性を測定する測定手段とを備える電気化学的分析装置である。 The electrochemical analyzer of the present invention includes the above-described electrochemical cell of the present invention, solution injection means for injecting a measurement solution, a buffer solution, and a cleaning solution into the electrochemical cell, and the working electrode, the counter electrode, and the reference electrode. An electrochemical analyzer comprising: a potential applying means for applying a potential to the electrode; and a measuring means connected to the working electrode, the counter electrode, and the reference electrode for measuring the electrochemical characteristics of the measurement solution.
本発明の電気化学測定用電極の製造方法は、以下(a)〜(d)に従う方法である。 The method for producing an electrode for electrochemical measurement of the present invention is a method according to the following (a) to (d).
(a)白金または白金合金を母材として前記母材中に、ジルコニウム,タンタル,ニオブからなる群より選ばれる金属の酸化物が分散して含有される複合材料を用いて電極化する工程、(b)前記電極表面の一部を除いて電極を絶縁樹脂中に包埋する工程、(c)前記の樹脂に包埋された電極の表面を機械研磨する工程、(d)前記電極表面を電解研磨し、表面変質層を除去する工程、からなる。電解研磨は、電解液中で電位を水素発生領域から酸素発生領域の電位間で複数回繰り返し印加する工程とすることが好ましい。印加する電位の波形は矩形波とすることがより好ましい。電解研磨処理後、サイクリックボルタンメトリを行い、測定結果で見られる複数の水素吸脱着ピークのうち少なくとも2つのピークの面積比から電極表面状態を診断し、所定ピーク比となるまで電解研磨を繰り返すことが更に好ましい。 (A) A step of forming an electrode using a composite material in which a metal oxide selected from the group consisting of zirconium, tantalum, and niobium is dispersed and contained in the base material using platinum or a platinum alloy as a base material. b) a step of embedding the electrode in an insulating resin excluding a part of the electrode surface, (c) a step of mechanically polishing the surface of the electrode embedded in the resin, and (d) electrolyzing the electrode surface. Polishing, and removing the surface-affected layer. The electropolishing is preferably a step of repeatedly applying a potential multiple times between the hydrogen generation region and the oxygen generation region in the electrolytic solution. The waveform of the applied potential is more preferably a rectangular wave. After the electropolishing treatment, perform cyclic voltammetry, diagnose the electrode surface state from the area ratio of at least two of the plurality of hydrogen adsorption / desorption peaks found in the measurement results, and perform electropolishing until the predetermined peak ratio is reached. It is more preferable to repeat.
本発明の電気化学セルの製造方法は、以下(a)〜(e)に従う方法である。 The method for producing an electrochemical cell of the present invention is a method according to the following (a) to (e).
(a)白金または白金合金を母材として前記母材中に、ジルコニウム,タンタル,ニオブからなる群より選ばれる金属の酸化物が分散して含有される複合材料を用いて電極化する工程、(b)予め溶液注入口および排出口を形成した絶縁性基板に、前記電極を接着剤により埋め込む工程、(c)前記の絶縁性基板に包埋された電極の表面を機械研磨する工程、(d)前記電極表面を電解研磨し、表面変質層を除去する工程、(e)前記の研磨を施した電極が包埋した絶縁性基板、開口部を有するシール部材、別の絶縁性基板を積層一体化し、対極,参照極を付設する工程からなる。 (A) A step of forming an electrode using a composite material in which a metal oxide selected from the group consisting of zirconium, tantalum, and niobium is dispersed and contained in the base material using platinum or a platinum alloy as a base material. b) a step of embedding the electrode with an adhesive in an insulating substrate in which a solution injection port and a discharge port are formed in advance; (c) a step of mechanically polishing the surface of the electrode embedded in the insulating substrate; ) A step of electropolishing the surface of the electrode to remove the surface alteration layer; (e) an insulating substrate embedded with the polished electrode, a sealing member having an opening, and another insulating substrate laminated together And a process of attaching a counter electrode and a reference electrode.
本発明の測電気化学測定用電極の製造装置は、
(a)白金または白金合金を母材として前記母材中に、ジルコニウム,タンタル,ニオブからなる群より選ばれる金属の酸化物が分散して含有される複合材料を用いる電極化部、(b)前記電極表面の一部を除いて電極を絶縁樹脂中に包埋する樹脂包埋部、
(c)前記の樹脂に包埋された電極の表面を機械研磨する機械研磨部、
(d)前記電極表面を電解研磨し、表面変質層を除去する電解研磨部、を備える製造装置である。
An apparatus for producing an electrode for electrometric measurement according to the present invention comprises:
(A) an electrode-forming part using a composite material in which a metal oxide selected from the group consisting of zirconium, tantalum and niobium is dispersed and contained in the base material using platinum or a platinum alloy as a base material; (b) A resin embedding part for embedding the electrode in an insulating resin except for a part of the electrode surface;
(C) a mechanical polishing unit that mechanically polishes the surface of the electrode embedded in the resin;
(D) A manufacturing apparatus including an electropolishing unit that electropolishes the surface of the electrode and removes a surface-modified layer.
本発明の電気化学セルの製造装置は、
(a)白金または白金合金を母材として前記母材中に、ジルコニウム,タンタル,ニオブからなる群より選ばれる金属の酸化物が分散して含有される複合材料を用いる電極化部、(b)予め溶液注入口および排出口を形成した絶縁性基板に、前記電極を接着剤により埋め込む樹脂包埋部、
(c)前記の絶縁性基板に包埋された電極の表面を機械研磨する機械研磨部、
(d)前記電極表面を電解研磨し、表面変質層を除去する電解研磨部、
(e)前記の研磨を施した電極が包埋した絶縁性基板、開口部を有するシール部材、別の絶縁性基板を積層一体化し、対極,参照極を付設するセル組立部、を備える製造装置である。
The electrochemical cell production apparatus of the present invention comprises:
(A) an electrode-forming part using a composite material in which a metal oxide selected from the group consisting of zirconium, tantalum and niobium is dispersed and contained in the base material using platinum or a platinum alloy as a base material; (b) A resin-embedded part in which the electrode is embedded with an adhesive in an insulating substrate in which a solution injection port and a discharge port are formed in advance,
(C) a mechanical polishing unit that mechanically polishes the surface of the electrode embedded in the insulating substrate;
(D) electropolishing the electrode surface to remove the surface alteration layer,
(E) Manufacturing apparatus comprising an insulating substrate in which the polished electrode is embedded, a sealing member having an opening, and a cell assembly unit in which another insulating substrate is laminated and integrated, and a counter electrode and a reference electrode are provided. It is.
本発明によれば、白金または白金合金を母材として母材中に金属酸化物が分散して含有される複合材料を用いて構成される電極、好ましくは金属酸化物を酸化ジルコニウム,酸化タンタル,酸化ニオブとし、白金または白金合金中における含有比率を金属換算で0.005〜1%とする電極、特に、電極表面のX線回折測定より得られる複数の結晶方位の内の一つの結晶方位の配向率を80%以上とする電極、その電極を用いた電気化学セルおよび電気化学的分析装置を用いることにより、液体試料中に含まれる化学的成分の電気化学的応答を測定する電気化学的分析、特に、血液・尿など液体試料に含まれる化学的成分を繰り返し測定する分析において、長期間安定した電極表面状態を確保し、より信頼性の高い測定結果を得ることが可能となる。 According to the present invention, an electrode configured using a composite material in which a metal oxide is dispersed and contained in a base material using platinum or a platinum alloy as a base material, preferably the metal oxide is zirconium oxide, tantalum oxide, An electrode having niobium oxide and a content ratio in platinum or a platinum alloy of 0.005 to 1% in terms of metal, particularly one of a plurality of crystal orientations obtained from X-ray diffraction measurement of the electrode surface. Electrochemical analysis for measuring electrochemical response of chemical components contained in a liquid sample by using an electrode having an orientation ratio of 80% or more, an electrochemical cell using the electrode, and an electrochemical analyzer In particular, it is possible to ensure a stable electrode surface condition for a long period of time and obtain more reliable measurement results in analysis that repeatedly measures chemical components contained in liquid samples such as blood and urine. Become.
本発明の実施例の説明に先立って、本発明の原理について説明する。 Prior to the description of the embodiments of the present invention, the principle of the present invention will be described.
血液・尿など液体試料に含まれる化学的成分の分析において、長期間にわたり繰り返し測定する場合、測定結果が変動する原因について、本発明者らが種々解析を行った結果、分析の繰り返しに伴う電極表面状態の変化に主に起因することが判明した。すなわち、蛋白質などを含む液体試料中での電位印加過程、電極表面を洗浄するための洗浄剤として水酸化カリウムなどの強アルカリ成分を含む液体中での電位印加過程、前記両者を長期間反復した場合、電極表面が徐々にエッチングされ、繰り返し分析後の表面状態が分析初期のそれに対して変動する。結果的に測定結果に悪影響を与える。 In the analysis of chemical components contained in liquid samples such as blood and urine, in the case of repeated measurement over a long period of time, the results of various analyzes conducted by the present inventors on the cause of fluctuations in the measurement results show that the electrodes accompanying repeated analysis It was found to be mainly due to the change of the surface condition. That is, the process of applying a potential in a liquid sample containing protein, the process of applying a potential in a liquid containing a strong alkali component such as potassium hydroxide as a cleaning agent for cleaning the electrode surface, both of which were repeated for a long time. In this case, the electrode surface is gradually etched, and the surface state after repeated analysis varies with respect to that at the beginning of analysis. As a result, the measurement result is adversely affected.
白金表面のエッチング挙動を調べたところ、例えば熱処理等により結晶組織が粗大化した白金電極の場合、分析繰り返しに伴い、エッチングのされやすい結晶面が優先的に溶出し、電極面内において比較的大きい凹んだ部分が局所的に発生する場合が見られた。これは、表面の結晶方位によりエッチング速度が変化することに起因する。また、液体試料に含まれる化学的成分によっては電極表面の結晶方位により反応性が異なることがわかった。すなわち、分析の繰り返しにより最表面に露出する各結晶方位の比率が変動し、結果的に電気化学反応の応答量が異なり、分析データに影響を及ぼすことがわかった。この現象は、特にフローセル内に電極を設置する場合、安定した液流を確保できなくなり、分析液,洗浄液の液置換を十分に行えず、適正な分析ができなくなってしまう。 As a result of examining the etching behavior of the platinum surface, for example, in the case of a platinum electrode whose crystal structure is coarsened by heat treatment or the like, the crystal surface that is easily etched is preferentially eluted with repeated analysis, and is relatively large in the electrode surface. There was a case where a concave portion occurred locally. This is because the etching rate varies depending on the crystal orientation of the surface. It was also found that the reactivity varies depending on the crystal orientation of the electrode surface depending on the chemical components contained in the liquid sample. That is, it was found that the ratio of each crystal orientation exposed on the outermost surface fluctuates by repeating the analysis, resulting in a difference in the amount of response of the electrochemical reaction, which affects the analysis data. In particular, when an electrode is installed in the flow cell, a stable liquid flow cannot be ensured, the analysis solution and the cleaning solution cannot be sufficiently replaced, and an appropriate analysis cannot be performed.
一方、結晶組織を微細にし、かつ結晶配向性をいずれかの方位に優先配向させた電極を用いた場合、分析繰り返しにより、電極表面がエッチングされる条件下においても、エッチングによる溶出が電極面内で比較的均一に進行し、エッチングにより形成される微細な孔、すなわちエッチピットが多数発生するものの、電極面内で局所的な凹みが形成されないことがわかった。特に、血液・尿などの液体試料中に含まれる微量濃度の化学的成分を磁性粒子を用いて選択的に電極上に捕捉し、分析する系においては、表面に発生するエッチピットと磁性粒子間の摩擦力が増大し、結果的に電極上での磁性粒子の安定性を向上、ひいては分析データを安定化することがわかった。 On the other hand, when an electrode with a fine crystal structure and a crystal orientation that is preferentially oriented in any orientation is used, elution due to etching does not occur within the electrode plane even under conditions where the electrode surface is etched by repeated analysis. It has been found that although the process proceeds relatively uniformly, many fine holes formed by etching, that is, many etch pits are generated, but no local recess is formed in the electrode surface. In particular, in a system that selectively captures and analyzes a chemical component in a trace concentration contained in a liquid sample such as blood or urine on an electrode using magnetic particles, it is between the etch pit generated on the surface and the magnetic particles. As a result, it was found that the magnetic force on the electrode was increased, and as a result, the stability of the magnetic particles on the electrode was improved, and the analysis data was stabilized.
上記理由から、分析データ安定性の向上には、実際に電気化学反応を発生させる電極材料の結晶組織が微細であり、かつ表面がエッチングされていく条件下において露出する結晶面の変動を抑制することが有効であるとの考えに至った。 For the above reasons, to improve the stability of analysis data, the crystal structure of the electrode material that actually generates the electrochemical reaction is fine, and the fluctuation of the exposed crystal plane is suppressed under the condition that the surface is etched. It came to the idea that this is effective.
本発明の電極材料は、母材である白金または白金合金中に金属酸化物を微細分散させた酸化物分散型の複合材料であり、以下詳説する。 The electrode material of the present invention is an oxide-dispersed composite material in which a metal oxide is finely dispersed in platinum or a platinum alloy as a base material, and will be described in detail below.
本発明の電極の母材となる白金または白金合金については、白金−ロジウム,白金−金,白金−イリジウムなど、液体試料中に含まれる化学的成分に応じて適宜選択することができる。本明細書においては、母材はバルク状態の白金または白金合金であって、母材に対する母材中に存在する空隙の割合の体積換算での百分率値を空隙率と定義した場合に、空隙率が1%以下、好ましくは0.2%以下の材料である。空隙の孔径は5μm以下であることが好ましい。空隙率が1%、空隙の孔径が5μmを上回ると、分析繰り返しの過程において、母材内部が存在していた空隙が表層に露出し、分析データに影響を及ぼす場合があるからである。 The platinum or platinum alloy used as the base material of the electrode of the present invention can be appropriately selected according to chemical components contained in the liquid sample, such as platinum-rhodium, platinum-gold, platinum-iridium. In the present specification, the base material is platinum or a platinum alloy in a bulk state, and when the percentage value in terms of volume of the ratio of voids existing in the base material to the base material is defined as the porosity, the porosity is Is 1% or less, preferably 0.2% or less. The pore diameter is preferably 5 μm or less. This is because if the porosity is 1% and the pore diameter exceeds 5 μm, the void in which the inside of the base material was present is exposed to the surface layer in the process of repeated analysis, and the analysis data may be affected.
本発明における金属酸化物は、複合材料の作製工程において白金,白金合金中に安定に存在し、母材の結晶組織を微細に保つことを役割の一つとして担う。また、電極表面に存在する金属酸化物は液体試料など各種電解液と接触するため、広いpH領域で電気化学反応への関与が小さいものであることが望ましい。これらの理由および電位−pH図(プルベーダイヤグラム)からわかるように、ジルコニウム,タンタル,ニオブの酸化物などを用いることができる。 The metal oxide in the present invention is stably present in platinum and a platinum alloy in the composite material production process, and plays a role in maintaining the fine crystal structure of the base material. In addition, since the metal oxide present on the electrode surface comes into contact with various electrolytes such as a liquid sample, it is desirable that the metal oxide is less involved in the electrochemical reaction in a wide pH range. As can be seen from these reasons and the potential-pH diagram (Pluve diagram), oxides of zirconium, tantalum, niobium, and the like can be used.
母材中の金属酸化物の含有比率は0.005〜1%であることが好ましい。0.005%以下の場合、母材中に含まれる酸化物の量が低すぎるため、場所によって母材の結晶が粗大化する領域が存在するためである。1%を超える場合、電気化学反応への寄与が大きくなり、分析データに影響を及ぼしてしまうため、および加工性が悪化してしまうためである。絞り加工性や展延性が要求される形状に電極を加工する場合には、加工性をより高くするため分散粒子濃度を0.01〜0.15%とすることがより好ましい。 The content ratio of the metal oxide in the base material is preferably 0.005 to 1%. In the case of 0.005% or less, the amount of oxide contained in the base material is too low, and there is a region where the crystal of the base material becomes coarse depending on the location. If it exceeds 1%, the contribution to the electrochemical reaction will increase, affecting the analytical data, and the processability will deteriorate. When the electrode is processed into a shape that requires drawing workability and spreadability, the concentration of dispersed particles is more preferably 0.01 to 0.15% in order to improve the workability.
母材中の添加金属は必ずしも全て酸化物の状態にある必要はない。例えば、金属材料分散型複合材料の製造方法としては、添加金属担持白金粉末を酸化して添加金属を酸化させて分散粒子を形成するものがあるが、この場合、酸化処理において全ての添加金属を酸化物としなくても、必要量の分散粒子が微細分散していればよい。電気化学反応への影響を小さくするためには、酸化処理を十分に行うことが好ましい。 All the added metals in the base material need not be in the oxide state. For example, as a method for producing a metal material-dispersed composite material, there is a method in which an additive metal-supported platinum powder is oxidized to oxidize the additive metal to form dispersed particles. Even if it is not an oxide, the required amount of dispersed particles may be finely dispersed. In order to reduce the influence on the electrochemical reaction, it is preferable to sufficiently perform the oxidation treatment.
本発明の金属酸化物分散型の複合材料の形状は、線状,棒状,網状など特に限定されないが、特に圧延加工等により板状としたものがよく、冷間圧延時に強圧延することにより複合材料の結晶配向性を高めたものが好ましい。 The shape of the composite material of the metal oxide dispersion type of the present invention is not particularly limited, such as a line shape, a rod shape, a net shape, etc., but it is particularly preferable to have a plate shape by rolling or the like, and it can be combined by strongly rolling during cold rolling. What improved the crystal orientation of the material is preferable.
金属酸化物分散型の複合材料は公知の方法により作製できる。 A metal oxide-dispersed composite material can be manufactured by a known method.
例えば、以下の方法が挙げられる。白金にジルコニウムを添加した白金合金を形成した後、白金合金をフレームガン等により水へ溶融噴霧することで白金合金粉末を形成する、いわゆるフレーム溶射法を使用して白金合金粉末を形成する。この白金合金粉末は、高温下の大気中雰囲気で、酸化処理を行う。酸化処理した白金合金粉末を型成形により所定形状に圧縮成形し、その後高温下で焼結処理を行う。得られる成形体をエアハンマにより形状加工し、冷間圧延処理し、再結晶加熱処理を行う。 For example, the following method is mentioned. After forming a platinum alloy in which zirconium is added to platinum, the platinum alloy powder is formed using a so-called flame spraying method in which a platinum alloy powder is formed by melting and spraying the platinum alloy into water with a flame gun or the like. This platinum alloy powder is oxidized in an air atmosphere at a high temperature. The oxidized platinum alloy powder is compression-molded into a predetermined shape by molding and then sintered at a high temperature. The resulting molded body is shaped with an air hammer, cold-rolled, and recrystallized and heated.
また別の方法として、以下の方法が挙げられる。粉末調製した白金を準備し、化学的沈殿反応を利用して、水酸化ジルコニウムを担持した水酸化ジルコニウム担持白金を形成する。この水酸化ジルコニウム担持白金の粉末を用いて、成形,焼結,鍛造,冷間圧延処理,再結晶化熱処理を順次行う。最終の仕上がり品において金属酸化物を均一に分散させるため、出発材料の白金粉末の粒径を、0.05〜10μmの範囲とすることが好ましい。 Another method includes the following method. The powdered platinum is prepared, and a zirconium hydroxide-supported platinum carrying a zirconium hydroxide is formed using a chemical precipitation reaction. Using this zirconium hydroxide-supported platinum powder, forming, sintering, forging, cold rolling, and recrystallization heat treatment are sequentially performed. In order to uniformly disperse the metal oxide in the final finished product, it is preferable that the particle diameter of the starting platinum powder be in the range of 0.05 to 10 μm.
また別の方法として、以下の方法が挙げられる。共同沈殿法により白金に酸化ジルコニウムを担持させた状態の白金粉末を形成し、その白金粉末を使用して複合材料を製造する。すなわち、ヘキサクロロ白金酸溶液および硝酸ジルコニウム溶液を混合し、還元剤としてのヒドラジンヒドラートと、pH調整用の水酸化カルシウムを加えることによって、共同沈殿反応を生じさせることにより、白金−水酸化ジルコニウム粉末を得る。その後、濾過,乾燥処理をして焼成処理することにより、酸化ジルコニウム担持白金の粉末を得る。
以後、焼結,鍛造,冷間圧延処理,再結晶化処理を順次行う。
Another method includes the following method. A platinum powder in which zirconium oxide is supported on platinum is formed by a coprecipitation method, and a composite material is manufactured using the platinum powder. That is, a platinum-zirconium hydroxide powder is produced by mixing a hexachloroplatinic acid solution and a zirconium nitrate solution, and adding a hydrazine hydrate as a reducing agent and calcium hydroxide for pH adjustment to cause a coprecipitation reaction. Get. Thereafter, filtration and drying are performed, followed by firing to obtain zirconium oxide-supported platinum powder.
Thereafter, sintering, forging, cold rolling treatment, and recrystallization treatment are sequentially performed.
本発明の金属酸化物分散型複合材料は、電極表面の結晶配向率において、複数の結晶方位の内の一つの結晶方位が優先的に配向していることが好ましい。電極表面の結晶配向率は次式(1)で定義されるものである。 In the metal oxide dispersed composite material of the present invention, it is preferable that one of the crystal orientations is preferentially oriented in the crystal orientation ratio on the electrode surface. The crystal orientation rate on the electrode surface is defined by the following formula (1).
(結晶方位の配向率)=I(hkl)/ΣI(hkl)×100 ・・・(1)
但し、I(hkl)は電極表面のX線回折測定より得られる各面の回折強度積分値であり、ΣI(hkl)は(hkl)の回折強度積分値の総和である。尚、本明細書では、X線回折測定より得られる(111)面,(200)面,(220)面、あるいは(311)面のそれぞれの回折強度積分値から上式(1)に従って優先配向性を算出する。
(Orientation ratio of crystal orientation) = I (hkl) / ΣI (hkl) × 100 (1)
Here, I (hkl) is the integrated value of diffraction intensity of each surface obtained by X-ray diffraction measurement of the electrode surface, and ΣI (hkl) is the sum of the integrated values of diffraction intensity of (hkl). In this specification, the preferred orientation according to the above equation (1) from the respective diffraction intensity integral values of the (111) plane, (200) plane, (220) plane, or (311) plane obtained by X-ray diffraction measurement. Calculate gender.
好ましい面方位は特に限定されないが、電極表面のX線回折において(111)面,(200)面,(220)面、あるいは(311)面のいずれかの面を優先配向させた金属酸化物分散型複合材料が好ましい。所定の面方位がピーク積分値で80%以上を占める電極が好ましいが、より好ましくは、(220)面の配向率が80%を示す材料である。そのためには、冷間圧延処理において圧下率70%以上、好ましくは90%以上の条件で実施し、後述するように、得られた材料の表面を更に機械研磨,電解研磨することが好ましい。尚、圧下率は次式(2)で定義する。 Although the preferred plane orientation is not particularly limited, metal oxide dispersion in which any of the (111) plane, (200) plane, (220) plane, or (311) plane is preferentially oriented in X-ray diffraction of the electrode surface Mold composite materials are preferred. An electrode in which the predetermined plane orientation occupies 80% or more of the peak integral value is preferable, but a material showing an orientation rate of (220) plane of 80% is more preferable. For this purpose, it is preferable that the cold rolling treatment is performed under conditions of a rolling reduction of 70% or more, preferably 90% or more, and the surface of the obtained material is further mechanically polished and electropolished as described later. The rolling reduction is defined by the following equation (2).
(圧下率)=(t0−t)/t0×100 ・・・(2) 但し、上記(2)式において、t0は圧延前の板厚であり、tは圧延後の板厚である。 (Rolling ratio) = (t 0 −t) / t 0 × 100 (2) However, in the above formula (2), t 0 is the thickness before rolling, and t is the thickness after rolling. is there.
金属酸化物分散型複合材料に接続する電気配線材料は、広く用いられている銅,アルミニウム,銀,白金等の電気抵抗の低い金属材料、またそれらを絶縁被覆した配線を用いることができるが、特に限定されるものではない。電気配線と分散型複合材料との接続は、溶接やはんだ付け等公知の方法で実施することができる。 The electrical wiring material connected to the metal oxide dispersed composite material can be a widely used metal material with low electrical resistance, such as copper, aluminum, silver, platinum, etc. It is not particularly limited. The connection between the electric wiring and the dispersed composite material can be performed by a known method such as welding or soldering.
電極面積を規定する場合や電気配線材料または接続部の液体試料への浸漬を回避したい場合には、電極表面の一部を除き、絶縁性樹脂に包埋してもよい。絶縁性樹脂としては、特に限定されないが、フッ素系樹脂,ポリエチレン,ポリプロピレン,ポリエステル,ポリ塩化ビニル,エポキシ樹脂,ポリエーテルエーテルケトン,ポリイミド,ポリアミドイミド,ポリスチレン,ポリスルホン,ホリエーテルスルホン,ホリフェニレンサルファイド,アクリル樹脂など耐薬品性に優れ、また分析対象とする液体試料に応じて適宜選択することができる。 When the electrode area is specified, or when it is desired to avoid the immersion of the electrical wiring material or the connection part in the liquid sample, the electrode surface may be partly embedded in an insulating resin. The insulating resin is not particularly limited, but fluorine resin, polyethylene, polypropylene, polyester, polyvinyl chloride, epoxy resin, polyether ether ketone, polyimide, polyamide imide, polystyrene, polysulfone, polyethersulfone, polyphenylene sulfide, It is excellent in chemical resistance such as acrylic resin, and can be appropriately selected according to the liquid sample to be analyzed.
本発明の電極を、接着剤を用いて絶縁性基板に固定してもよい。絶縁性基板は上記した絶縁性樹脂と同様の材料を用いることができる。接着剤には、エポキシ系,アクリル系など熱可塑性,熱硬化性あるいは光硬化性の樹脂を用いることができるが、絶縁性樹脂と同様、耐薬品性に優れたものであれば、特に限定されず適宜選択することができる。 The electrode of the present invention may be fixed to an insulating substrate using an adhesive. The insulating substrate can be made of the same material as the insulating resin described above. As the adhesive, thermoplastic, thermosetting or photo-curing resins such as epoxy and acrylic resins can be used. However, as long as the resin has excellent chemical resistance, it is not particularly limited. It can be selected as appropriate.
電極を絶縁性樹脂に埋め込む場合や絶縁性基板に固定する場合には、本発明の電極の下地に別の金属を配置したクラッド材を用いることもできる。例えば、酸化物分散型複合材料とチタンなど弁金属とを接合した材料などが挙げられる。接合に関しては、チタンなどの表面が酸素,炭素,窒素などと反応し、不活性皮膜を形成することから、チタンの金属表面を露出させて、速やかに白金と接合する必要がある。そのためには、例えば、チタン表面に形成された不活性皮膜を真空雰囲気下でドライエッチングなどにより除去した後、複合材料と付き合わせて鍛接することにより接合が可能である。また、公知の爆発圧接法によりチタンと酸化物分散型複合材料を接合した後、冷間圧延加工することも可能である。また、冷間圧延加工した酸化物分散型複合材料とチタン表面に白金めっきを施したもの面同士を付き合わせ、鍛接することにより作製することがより好ましい。チタン表面に白金めっきを施す場合、密着性を向上させるための前処理として、チタン表面をサンドブラスト法は化学エッチング法により処理してもよい。化学エッチング法においては、フッ酸,フッ化物含有フッ酸,濃硫酸,塩酸,蓚酸など、またそれらの混合溶液を用いることができる。 When the electrode is embedded in an insulating resin or fixed to an insulating substrate, a clad material in which another metal is disposed on the base of the electrode of the present invention can also be used. For example, a material obtained by joining an oxide-dispersed composite material and a valve metal such as titanium can be used. Regarding bonding, since the surface of titanium reacts with oxygen, carbon, nitrogen and the like to form an inactive film, it is necessary to expose the metal surface of titanium and quickly bond to platinum. For this purpose, for example, the inactive film formed on the titanium surface is removed by dry etching or the like in a vacuum atmosphere, and then bonded by forging with the composite material. It is also possible to cold-roll after joining titanium and the oxide-dispersed composite material by a known explosive pressure welding method. It is more preferable that the oxide-dispersed composite material that has been cold-rolled and the surface of the titanium surface plated with platinum are attached to each other and forged. When platinum plating is performed on the titanium surface, the titanium surface may be treated by a chemical etching method or a sand blasting method as a pretreatment for improving adhesion. In the chemical etching method, hydrofluoric acid, fluoride-containing hydrofluoric acid, concentrated sulfuric acid, hydrochloric acid, oxalic acid, or a mixed solution thereof can be used.
下地金属の板厚は特に限定されないが、曲げや切削等の加工性の観点から0.01〜5mmが好ましい。酸化物分散型複合材料の板厚としては、0.01〜0.3mmであることが好ましい。より好ましくは、0.02〜0.15mmである。圧延工程において局所的な熱,圧力集中などの影響を受け、表層に内部とは異なる結晶組織状態が形成される場合があり、その深さは場合によっては表層から0.01mm程度に及ぶ。そのため、酸化物分散型複合材料の厚みを0.01mm以上とし、表層を機械研磨により除去して内部の結晶組織を表層に露出して使用することがより好ましい。0.3mm以上では白金量が多くなり、高コストになるためである。 Although the plate | board thickness of a base metal is not specifically limited, 0.01-5 mm is preferable from a viewpoint of workability, such as a bending and cutting. The plate thickness of the oxide dispersion type composite material is preferably 0.01 to 0.3 mm. More preferably, it is 0.02 to 0.15 mm. Under the influence of local heat and pressure concentration in the rolling process, a crystal structure state different from the inside may be formed on the surface layer, and the depth may reach about 0.01 mm from the surface layer depending on the case. Therefore, it is more preferable to use the oxide-dispersed composite material having a thickness of 0.01 mm or more, removing the surface layer by mechanical polishing and exposing the internal crystal structure to the surface layer. This is because when the thickness is 0.3 mm or more, the amount of platinum increases and the cost increases.
金属酸化物分散型複合材料は、前述したように、その表面を機械的に研磨することが好ましい。さらに、機械的研磨した後、さらに電解研磨することがより好ましい。電解研磨は、酸あるいは水酸化カリウムなどの強アルカリ成分を含む電解液中で水素発生領域と酸素発生領域間で繰り返し電位印加する方法が好ましい。印加電位波形は三角波,矩形波などを用いることができるが、本発明においては、特に限定する必要はない。 As described above, the surface of the metal oxide dispersed composite material is preferably mechanically polished. Furthermore, it is more preferable to perform electrolytic polishing after mechanical polishing. For the electropolishing, a method in which a potential is repeatedly applied between the hydrogen generation region and the oxygen generation region in an electrolytic solution containing a strong alkali component such as acid or potassium hydroxide is preferable. The applied potential waveform may be a triangular wave, a rectangular wave, or the like, but is not particularly limited in the present invention.
上記の機械研磨および電解研磨は、圧下率の大きい条件下で冷間圧延加工処理を行う場合に特に有効な処理である。すなわち、特に圧延加工を経た材料の表面近傍の結晶配向性は比較的ランダムであったり、局所的に表面に熱が加わることにより板内部と表層部とでは結晶粒径および配向性が異なることがわかった。機械研磨後の材料では圧延加工により形成された表面変質層はある程度除去されるが、機械研磨時の加圧により形成される表面変質層や研磨砥粒によるキズなどが依然として存在している。本発明の製造方法においても、冷間圧延加工により白金の内部は結晶配向性を持った状態となるが、表面近傍には結晶配向性の乱れた表面変質層が形成されることが考えられる。機械研磨および電解研磨は前記表面変質層の除去に有効であり、材料内部の高い結晶配向性を有する部分を露出させる工程と言える。 The above mechanical polishing and electrolytic polishing are particularly effective processes when the cold rolling process is performed under a condition with a large rolling reduction. In other words, the crystal orientation in the vicinity of the surface of the material that has undergone the rolling process is relatively random, or the crystal grain size and orientation may differ between the inside of the plate and the surface layer portion due to local heating. all right. In the material after mechanical polishing, the surface deteriorated layer formed by rolling is removed to some extent, but the surface deteriorated layer formed by pressurization at the time of mechanical polishing and scratches due to abrasive grains still exist. Also in the manufacturing method of the present invention, although the inside of platinum is in a state having crystal orientation by cold rolling, it is conceivable that a surface deteriorated layer having disordered crystal orientation is formed in the vicinity of the surface. Mechanical polishing and electropolishing are effective for removing the surface-affected layer, and can be said to be a step of exposing a portion having high crystal orientation in the material.
電極の製造工程において、材料表面の変質層の除去の程度を判断するため、電解研磨処理中に所定の電解液中に前記材料を浸漬し、サイクリックボルタンメトリにより表面状態を診断することが好ましい。すなわち、サイクリックボルタンメトリ結果より複数の水素吸脱着の電流ピークが得られる。これらの電流ピークは電極表面の面方位に依存した電流量となるため、圧延加工により生じた表面変質層の除去の度合いを判断する基準となり得る。得られたピークの内少なくとも2つのピークの面積、ならびに面積比を計算する。計算結果に基づき、所定の面積比になるまで電解研磨することにより、表面変質層を除去した電極を得ることができる。尚、サイクリックボルタンメトリにおいて用いる電解液としては、例えば硫酸,燐酸,過塩素酸,水酸化ナトリウム,水酸化カリウムなどが挙げられる。 In the electrode manufacturing process, in order to determine the degree of removal of the altered layer on the surface of the material, the surface state is diagnosed by cyclic voltammetry by immersing the material in a predetermined electrolytic solution during the electropolishing process. preferable. That is, a plurality of hydrogen adsorption / desorption current peaks are obtained from the cyclic voltammetry results. Since these current peaks are current amounts depending on the surface orientation of the electrode surface, they can be used as a reference for determining the degree of removal of the surface deteriorated layer caused by rolling. The area of at least two of the obtained peaks and the area ratio are calculated. Based on the calculation result, an electrode from which the surface-modified layer has been removed can be obtained by electropolishing until a predetermined area ratio is obtained. Examples of the electrolytic solution used in cyclic voltammetry include sulfuric acid, phosphoric acid, perchloric acid, sodium hydroxide, and potassium hydroxide.
電気化学セルに用いる対極は、分析対象とする液体試料に応じて適宜選択するが、白金または白金合金を用いることができる。また、本発明の電極を対極に用いてもよい。形状は、線状,棒状,網状,板状など特に限定されない。 The counter electrode used in the electrochemical cell is appropriately selected according to the liquid sample to be analyzed, but platinum or a platinum alloy can be used. Moreover, you may use the electrode of this invention for a counter electrode. The shape is not particularly limited, such as a line shape, a rod shape, a net shape, or a plate shape.
電気化学セルに用いる参照極は、銀|塩化銀電極,飽和カロメル電極,銀電極などを用いることができるが、特に限定されない。 A silver | silver chloride electrode, a saturated calomel electrode, a silver electrode, or the like can be used as the reference electrode used in the electrochemical cell, but it is not particularly limited.
上記した電極を作用極として用いた電気化学セルおよび分析装置は、その電気化学応答が長期間にわたり電極の表面状態の変動が少なく、また露出する結晶配向性の変化が小さく、安定した測定結果を示すことがわかった。フローセル内に作用極を設置する場合においても、長期間にわたり電極の表面状態、特に電極面内において局所的な凹みの形成を抑制し、分析液,洗浄液の液置換を安定して実施することが可能となり、結果的にデータ安定性を向上できる。 Electrochemical cells and analyzers using the above electrode as the working electrode have a stable measurement result with little change in the surface state of the electrode over a long period of time and little change in the exposed crystal orientation. I found out. Even when a working electrode is installed in the flow cell, the surface condition of the electrode, especially the formation of local depressions in the electrode surface, can be suppressed over a long period of time, and the liquid replacement of the analysis solution and the cleaning solution can be performed stably. As a result, data stability can be improved.
本発明の電極,電気化学セルおよび電気化学測定装置を用いて、血液・尿など液体試料に含まれる化学的成分として、例えば以下に示す成分を分析することが可能である。例えば、グルコース,糖化ヘモグロビン,糖化アルブミン,乳酸,尿酸,尿素,クレアチニン,胆汁酸、コレステロール,中性脂肪、アンモニア,尿素窒素,ビリルビン,ヒスタミンなどが挙げられるが、酵素やメディエータ等の作用により生じる酸化還元種の電気化学応答を示す成分が挙げられるが、特に限定されない。分析対象とする化学的成分と選択的に結合する成分を表面に修飾した磁性粒子を用いて対象成分を電極表面に捕捉した後、電気化学測定を行う成分も分析することが可能である。 For example, the following components can be analyzed as chemical components contained in a liquid sample such as blood and urine using the electrode, electrochemical cell, and electrochemical measurement device of the present invention. For example, glucose, glycated hemoglobin, glycated albumin, lactic acid, uric acid, urea, creatinine, bile acid, cholesterol, neutral fat, ammonia, urea nitrogen, bilirubin, histamine, etc., but oxidation caused by the action of enzymes, mediators, etc. Although the component which shows the electrochemical response of a reducing species is mentioned, it is not specifically limited. After capturing the target component on the electrode surface using magnetic particles whose surface is modified with a component that selectively binds to the chemical component to be analyzed, it is also possible to analyze the component for which electrochemical measurement is performed.
グルコースを検出する場合にあっては、例えばグルコースオキシダーゼを作用させることにより生成した過酸化水素を電極上で還元あるいは酸化することにより、グルコース濃度を定量することができる。 In the case of detecting glucose, for example, the glucose concentration can be quantified by reducing or oxidizing hydrogen peroxide generated by the action of glucose oxidase on the electrode.
糖化ヘモグロビンや糖化アルブミンなどの糖化タンパク質を検出する場合にあっては、例えばプロテアーゼにより糖化タンパク質より糖化ペプチドを遊離させた後、さらに糖化ペプチドオキシダーゼを作用させることにより生成した過酸化水素を電極上で還元あるいは酸化することにより、糖化タンパク質濃度を定量することができる。 In the case of detecting glycated proteins such as glycated hemoglobin and glycated albumin, for example, after releasing the glycated peptide from the glycated protein by protease, hydrogen peroxide generated by further action of glycated peptide oxidase on the electrode By reducing or oxidizing, the glycated protein concentration can be quantified.
乳酸を検出する場合にあっては、例えば乳酸オキシダーゼを作用させることにより生成した過酸化水素を電極上で還元あるいは酸化することにより、乳酸濃度を定量することができる。 In the case of detecting lactic acid, for example, the concentration of lactic acid can be quantified by reducing or oxidizing hydrogen peroxide generated by the action of lactate oxidase on the electrode.
尿酸を検出する場合にあっては、例えばウリカーゼを作用させることにより生成した過酸化水素を電極上で還元あるいは酸化することにより、尿酸濃度を定量することができる。 In the case of detecting uric acid, the concentration of uric acid can be quantified by, for example, reducing or oxidizing hydrogen peroxide generated by the action of uricase on the electrode.
尿素を検出する場合にあっては、例えばウレアーゼを作用させることにより生じたアンモニアに、β−ニコチンアミドアデニンジヌクレオチド(NADH)およびフェリシアン化カリウム存在下でさらにグルタミン酸脱水素酵素を作用させることにより生成したフェロシアン化カリウムを電極上で酸化することにより、尿素濃度を定量することができる。 In the case of detecting urea, for example, it was produced by further acting glutamate dehydrogenase on ammonia produced by acting urease in the presence of β-nicotinamide adenine dinucleotide (NADH) and potassium ferricyanide. The urea concentration can be quantified by oxidizing potassium ferrocyanide on the electrode.
クレアチニンを検出する場合にあっては、例えばクレアチニナーゼ,クレアチナーゼおよびザルコシンオキシダーゼを順次作用させることにより生成した過酸化水素を電極上で還元あるいは酸化することにより、クレアチニン濃度を定量することができる。 In the case of detecting creatinine, for example, the concentration of creatinine can be quantified by reducing or oxidizing the hydrogen peroxide generated by sequentially acting creatininase, creatinase and sarcosine oxidase on the electrode. .
胆汁酸を検出する場合にあっては、例えば胆汁酸硫酸スルファターゼ,β−ヒドロキシステロイドデヒドロゲナーゼを還元型NADHおよびフェリシアン化カリウム存在下で順次作用させることにより生成したフェロシアン化カリウムを電極上で酸化することにより、胆汁酸濃度を定量することができる。 In the case of detecting bile acids, for example, by oxidizing potassium ferrocyanide produced by sequentially acting bile acid sulfate sulfatase and β-hydroxysteroid dehydrogenase in the presence of reduced NADH and potassium ferricyanide on the electrode, The bile acid concentration can be quantified.
コレステロールを検出する場合にあっては、例えばコレステロールオキシダーゼを作用させることにより生成した過酸化水素を電極上で還元あるいは酸化することにより、コレステロール濃度を定量することができる。 In the case of detecting cholesterol, for example, the cholesterol concentration can be quantified by reducing or oxidizing hydrogen peroxide generated by the action of cholesterol oxidase on the electrode.
中性脂肪を検出する場合にあっては、例えばグリセロフォスフェートオキシダーゼを作用させることにより生成した過酸化水素を電極上で還元あるいは酸化することにより、中性脂肪濃度を定量することができる。 In the case of detecting neutral fat, the concentration of neutral fat can be quantified by reducing or oxidizing, for example, hydrogen peroxide generated by the action of glycerophosphate oxidase on the electrode.
脂肪酸を検出する場合にあっては、例えばアシルCoAオキシダーゼを作用させることにより生成した過酸化水素を電極上で還元あるいは酸化することにより、脂肪酸濃度を定量することができる。 In the case of detecting a fatty acid, the fatty acid concentration can be quantified by, for example, reducing or oxidizing hydrogen peroxide generated by the action of acyl CoA oxidase on the electrode.
アンモニアを検出する場合にあっては、NADHおよびフェリシアン化カリウム存在下でグルタミン酸脱水素酵素を作用させることにより生成したフェロシアン化カリウムを電極上で酸化することにより、アンモニア濃度を定量することができる。 In the case of detecting ammonia, the ammonia concentration can be quantified by oxidizing potassium ferrocyanide produced by the action of glutamate dehydrogenase in the presence of NADH and potassium ferricyanide on the electrode.
ビリルビンを検出する場合にあっては、例えばフェリシアン化カリウム存在下でビリルビンオキシダーゼを作用させることにより生成したフェロシアン化カリウムを電極上で酸化することにより、尿素窒素濃度を定量することができる。 In the case of detecting bilirubin, for example, the concentration of urea nitrogen can be determined by oxidizing potassium ferrocyanide produced by the action of bilirubin oxidase in the presence of potassium ferricyanide on the electrode.
上記した酵素類は電極表面上に固定化される。酵素類の電極表面への固定化方法は特に限定されないが、例えば酵素類を溶解させた水溶液や緩衝液中に電極を浸漬する方法、あるいは電極上に酵素類を溶解させた水溶液や緩衝液を滴下することにより物理的あるいは化学的に酵素類を固定化する方法、末端基にカルボキシル基やアミノ基などの官能基を導入したチオールを含む溶液中に電極を浸漬して電極表面に前記チオールを吸着させた後に酵素などを反応させて固定化する方法、グルタルアルデヒドのような架橋試薬あるいはさらに牛血清アルブミンを用いて酵素などを電極上に固定化する方法、親水性高分子などのゲル膜を電極上に形成させた後に膜中に酵素などを固定化する方法またはポリチオフェンなどの導電性高分子膜を電極上に形成させた後に膜中に酵素などを固定化する方法などが挙げられる。 The enzymes described above are immobilized on the electrode surface. The method for immobilizing the enzyme on the electrode surface is not particularly limited. For example, a method of immersing the electrode in an aqueous solution or buffer solution in which the enzyme is dissolved, or an aqueous solution or buffer solution in which the enzyme is dissolved on the electrode is used. A method of physically or chemically immobilizing enzymes by dripping, immersing the electrode in a solution containing a thiol having a functional group such as a carboxyl group or an amino group introduced into the terminal group, and placing the thiol on the electrode surface A method of immobilizing by adsorbing an enzyme after adsorbing, a method of immobilizing an enzyme on an electrode using a cross-linking reagent such as glutaraldehyde or bovine serum albumin, or a gel membrane such as a hydrophilic polymer A method of immobilizing an enzyme or the like in the film after it is formed on the electrode, or an enzyme or the like is immobilized in the film after a conductive polymer film such as polythiophene is formed on the electrode Law and the like.
分析対象を検出する際、必要に応じて、検出濃度範囲の拡張を目的としてメディエーター分子を利用することが有効である。メディエーター分子を利用する場合においては、電極上に形成させた酵素類の生理活性物質の固定化膜中あるいはこれとは分けて、メディエーター分子を電極上に配置することが好ましい。メディエーター分子の種類は特に限定されないが、例えばフェリシアン化カリウム,フェロシアン化カリウム,フェロセンおよびその誘導体、ビオローゲン類およびメチレンブルーなどの少くとも一種を用いることができる。 When detecting an analysis target, it is effective to use a mediator molecule for the purpose of extending the detection concentration range, if necessary. When using a mediator molecule, it is preferable to dispose the mediator molecule on the electrode in the immobilized membrane of the physiologically active substance of enzymes formed on the electrode or separately from it. The type of the mediator molecule is not particularly limited, and for example, at least one kind such as potassium ferricyanide, potassium ferrocyanide, ferrocene and derivatives thereof, viologens and methylene blue can be used.
次に、以上の原理に基づく、本発明の実施例について説明する。 Next, an embodiment of the present invention based on the above principle will be described.
以下、本発明の一実施形態による電極を用いて、本発明の一実施形態による電気化学的分析装置の全体構成について説明する。 Hereinafter, the overall configuration of an electrochemical analyzer according to an embodiment of the present invention will be described using electrodes according to an embodiment of the present invention.
図1は、本発明の第1の実施形態による電気化学的分析装置の全体構成を示す。第1の実施形態は、バッチ処理方式の形態を有した電気化学的分析装置である。 FIG. 1 shows the overall configuration of an electrochemical analyzer according to a first embodiment of the present invention. The first embodiment is an electrochemical analyzer having a batch processing system.
電気化学セル1の中に、作用極2,対極3および参照極4を配置する。各電極2,3,4は、電気配線7により電位印加手段5および測定手段6に接続されている。対極3は白金を板状に圧延加工し、表面を鏡面研磨したものを用いた。参照極は、Ag|AgCl電極とした。尚、本明細書中において、銀|塩化銀(飽和塩化カリウム水溶液)電極をAg|AgClと記す。 A working electrode 2, a counter electrode 3, and a reference electrode 4 are disposed in the electrochemical cell 1. Each electrode 2, 3, 4 is connected to the potential applying means 5 and the measuring means 6 by electric wiring 7. The counter electrode 3 was obtained by rolling platinum into a plate shape and mirror-polishing the surface. The reference electrode was an Ag | AgCl electrode. In this specification, a silver | silver chloride (saturated potassium chloride aqueous solution) electrode is referred to as Ag | AgCl.
溶液分注機構11は、それぞれ測定溶液容器8から被測定対象化学的成分を含む測定溶液、緩衝液容器9から緩衝液を溶液導入管13内に導入する。導入された測定溶液と緩衝液は、溶液導入管13内にて混合されて、混合液が溶液注入機構12により、電気化学セル1中に注入されて被測定対象物の電気化学的測定が行われる。 The solution dispensing mechanism 11 introduces the measurement solution containing the chemical component to be measured from the measurement solution container 8 and the buffer solution from the buffer solution container 9 into the solution introduction tube 13, respectively. The introduced measurement solution and buffer solution are mixed in the solution introduction tube 13, and the mixed solution is injected into the electrochemical cell 1 by the solution injection mechanism 12 to perform electrochemical measurement of the object to be measured. Is called.
電位印加手段5はポテンシオスタット,ガルバノスタット,直流電源,交流電源あるいはそれらをファンクションジェネレータなどと接続したシステムを用いることができる。
測定手段6は、被測定対象物の電気化学的特性を測定する。電気化学的特性とは、ポテンシオメトリ,アンペロメトリ,ボルタンメトリ,インピーダンス測定等、公知の測定手法のいずれであってもよく、特に限定されることはない。電気化学反応に応じて生じる光子を光学素子により検出する方法等もある。
The potential applying means 5 can be a potentiostat, a galvanostat, a DC power supply, an AC power supply, or a system in which these are connected to a function generator or the like.
The measuring means 6 measures the electrochemical characteristics of the object to be measured. The electrochemical characteristics may be any known measurement technique such as potentiometry, amperometry, voltammetry, impedance measurement, etc., and are not particularly limited. There is also a method of detecting photons generated in response to an electrochemical reaction with an optical element.
測定の終了した測定溶液は、溶液排出機構15によって吸引されて、溶液排出管14を通って廃液容器16に廃棄される。試料の測定終了後、溶液分注機構11によって、洗浄液容器10から洗浄液が吸入され、溶液注入機構12によって電気化学セル1中に供給される。電気化学セル1内を洗浄した洗浄液は、廃液容器16に廃棄される。 The measurement solution for which the measurement has been completed is sucked by the solution discharge mechanism 15 and discarded into the waste liquid container 16 through the solution discharge pipe 14. After the measurement of the sample, the cleaning liquid is sucked from the cleaning liquid container 10 by the solution dispensing mechanism 11 and supplied into the electrochemical cell 1 by the solution injection mechanism 12. The cleaning liquid that has cleaned the inside of the electrochemical cell 1 is discarded in the waste liquid container 16.
ここで、典型例として、電圧印加手段5は、測定溶液の測定中に作用極に対して正の電位と負の電位を所定周期で繰り返すパルス状波形の電位を出力する。このパルス状波形の電位は、血液のような蛋白質,ハロゲン元素を多く含む測定溶液を電解セル内に長期間連続的に流す場合や、水酸化カリウムのような強アルカリ性の洗浄剤が測定容器内に流入する場合に、印加されるように構成されている。本実施例では上記電位印加波形としたが、特に限定されることはない。 Here, as a typical example, the voltage application means 5 outputs a pulse-shaped waveform potential that repeats a positive potential and a negative potential with a predetermined period with respect to the working electrode during measurement of the measurement solution. This pulse-shaped waveform potential is applied when a measurement solution containing a large amount of protein and halogen elements such as blood is continuously flowed into the electrolytic cell for a long period of time, or when a strong alkaline detergent such as potassium hydroxide is used in the measurement container. It is configured so that it is applied when it flows into the. In the present embodiment, the above-described potential application waveform is used.
ここで、作用極2に用いる電極材料として、白金中に酸化ジルコニウムを分散させた複合材料を用いた。前記複合材料は、以下に示す製法に従って作製した。白金−0.2%ジルコニウム合金を真空溶解にてインゴットを製造した。続いて、鍛造処理後、前記インゴットを圧延することにより、伸線処理を行った。前記の伸線処理したものをフレームガンにより蒸留水浴に向けて溶融噴霧し、白金合金粉末とした。得られた白金合金粉末を大気中、1250℃,24時間保持して酸化処理を行った。酸化処理後の合金粉を1250℃で仮焼結し、引き続きホットプレスで成形固化する。緻密度を向上させるため、成形体を熱間鍛造する。最後に、この合金を圧下率90%で冷間圧延処理、1400℃で1時間加熱処理を行うことで、板厚0.2mmの板状の複合材料を得た。 Here, as an electrode material used for the working electrode 2, a composite material in which zirconium oxide was dispersed in platinum was used. The composite material was produced according to the manufacturing method shown below. An ingot was produced by vacuum melting a platinum-0.2% zirconium alloy. Subsequently, after the forging process, the ingot was rolled to perform a wire drawing process. The drawn wire was melt sprayed with a flame gun toward a distilled water bath to obtain a platinum alloy powder. The obtained platinum alloy powder was oxidized in the atmosphere at 1250 ° C. for 24 hours. The alloy powder after the oxidation treatment is pre-sintered at 1250 ° C., and subsequently formed and solidified by hot pressing. In order to improve the density, the compact is hot forged. Finally, this alloy was cold-rolled at a reduction rate of 90% and heat-treated at 1400 ° C. for 1 hour to obtain a plate-like composite material having a plate thickness of 0.2 mm.
前記の複合材料を用いて、作用極2を以下の手順に従って作製した。 Using the composite material, the working electrode 2 was produced according to the following procedure.
前記複合材料を直径5mmの大きさに切断した。その後、図2に示す作用電極製造装置5
0により、まず電極化部50aにおいて切断した複合材料301の裏面に電気配線302をはんだにより接続した。電気配線として絶縁樹脂被覆銅線を用いた。
The composite material was cut into a diameter of 5 mm. Thereafter, the working electrode manufacturing apparatus 5 shown in FIG.
0, first, the electrical wiring 302 was connected to the back surface of the composite material 301 cut at the electrodeized portion 50a by solder. An insulating resin-coated copper wire was used as the electrical wiring.
次に、樹脂包埋部50bにおいて、複合電極の表面だけが直径5mmの円状に露出するよ
うに、接着剤303を用いて絶縁性樹脂300に埋め込んだ。絶縁性樹脂としてフッ素系樹脂を用いた。
Next, in the resin embedding part 50b, it was embedded in the insulating resin 300 using the adhesive 303 so that only the surface of the composite electrode was exposed in a circular shape having a diameter of 5 mm. A fluorine resin was used as the insulating resin.
次に、機械研磨部50cにおいて、電極表面を耐水研磨紙,ダイヤモンドペーストおよびアルミナ粒子を用いて順次機械研磨加工され、鏡面に仕上げた。 Next, in the mechanical polishing portion 50c, the electrode surface was sequentially mechanically polished using water-resistant abrasive paper, diamond paste and alumina particles to finish a mirror surface.
次に、ステンレス製のシャフト304をフッ素系樹脂にねじ込み、シャフト304と電気配線302とを接続した。最後に、電解研磨部50dにおいて、0.2mol/L水酸化カリウム水溶液中で−1.2〜1.0V vs Ag|AgClの電位間で電位走査速度0.1V/sで10000回電位走査が繰り返され、図3に示す作用極2を得た。尚、図4は図3
のA−A′における断面模式図である。
Next, the stainless steel shaft 304 was screwed into the fluorine resin, and the shaft 304 and the electric wiring 302 were connected. Finally, in the electropolishing unit 50d, in the 0.2 mol / L potassium hydroxide aqueous solution, the potential scanning is performed 10,000 times at a potential scanning speed of 0.1 V / s between potentials of -1.2 to 1.0 V vs. Ag | AgCl. Repeatedly, the working electrode 2 shown in FIG. 3 was obtained. 4 is the same as FIG.
It is a cross-sectional schematic diagram in AA '.
本実施例で作製した作用極2の電極表面のX線回折測定を実施した。X線源としてCuKαを用い、出力40kV,20mAとし、電極表面上の異なる3点を測定した。白金表面における(111)面,(200)面,(220)面,(311)面の回折ピークの積分値(I)を算出して、各方位の配向率((%)=I(hkl)/ΣI(hkl)×100)を求めた。尚、各ピーク積分値の算出の際には、(111)面は37°≦2θ≦42°、(200)面は44°≦2θ≦49°、(220)面は65°≦2θ≦70°、(311)面は78°≦2θ≦83°(θは回折角度)の範囲で行った。測定の結果、図5に示すように、面指数(220)が優先的に配向しており、配向率95%であることがわかった。 X-ray diffraction measurement of the electrode surface of the working electrode 2 produced in this example was performed. Using CuKα as the X-ray source, the output was 40 kV, 20 mA, and three different points on the electrode surface were measured. The integral value (I) of diffraction peaks of the (111) plane, (200) plane, (220) plane, and (311) plane on the platinum surface is calculated, and the orientation ratio ((%) = I (hkl) in each direction. / ΣI (hkl) × 100). When calculating each peak integral value, the (111) plane is 37 ° ≦ 2θ ≦ 42 °, the (200) plane is 44 ° ≦ 2θ ≦ 49 °, and the (220) plane is 65 ° ≦ 2θ ≦ 70. The (311) plane was performed in the range of 78 ° ≦ 2θ ≦ 83 ° (θ is the diffraction angle). As a result of the measurement, as shown in FIG. 5, it was found that the plane index (220) was preferentially oriented and the orientation rate was 95%.
図6は、本発明の一実施形態で採用している、金属酸化物分散型白金電極の効果を説明する図である。同一濃度のTSH(甲状腺刺激ホルモン)を分析対象として繰り返し測定を行った。図6の横軸は試験回数を示し、縦軸は各実測値を基準値で除した値で示した。
尚、基準値は既定濃度のTSH含有溶液を測定したときの出力値、実測値は実施例、比較例で用いた溶液それぞれを測定したときの測定値である。変動幅は分析60000回目と1回目の値の差と定義する。図6において、丸印を結ぶ線は本願実施例の場合であり、三角印を結ぶ線は、本発明とは異なる比較例の場合である。
FIG. 6 is a diagram for explaining the effect of the metal oxide dispersed platinum electrode employed in one embodiment of the present invention. The same concentration of TSH (thyroid stimulating hormone) was repeatedly measured for analysis. The horizontal axis in FIG. 6 indicates the number of tests, and the vertical axis indicates the value obtained by dividing each measured value by the reference value.
The reference value is an output value when a TSH-containing solution having a predetermined concentration is measured, and the actual measurement value is a measured value when each of the solutions used in Examples and Comparative Examples is measured. The fluctuation range is defined as the difference between the values of the 60000th analysis and the 1st analysis. In FIG. 6, the line connecting the circle marks is the case of the present embodiment, and the line connecting the triangle marks is the case of the comparative example different from the present invention.
図3の電極および図1の電気化学的分析装置を用いて、測定溶液として、血清中のTSHを免疫学的に分析し、洗浄液として、例えば水酸化カリウム水溶液を各測定の終了毎に電気化学セルに導入する方法で測定を行った。 Using the electrode of FIG. 3 and the electrochemical analyzer of FIG. 1, TSH in serum is immunologically analyzed as a measurement solution, and, for example, a potassium hydroxide aqueous solution is electrochemically used as a washing solution at the end of each measurement. Measurement was performed by the method introduced into the cell.
図6に示すように、比較例の電極を用いた場合の変動幅は10.3%であった。比較例の電極は、熱間圧延加工,再結晶化処理を施した白金電極であり、白金表面を実施例1と同様に、機械研磨処理,電解処理を行った電極である。詳細は後述する比較例にて説明する。それに対して、本実施例の電極を用いた場合、変動幅が4.2%まで低減した。 As shown in FIG. 6, the fluctuation range when the electrode of the comparative example was used was 10.3%. The electrode of the comparative example is a platinum electrode that has been hot-rolled and recrystallized, and the platinum surface is an electrode that has been subjected to mechanical polishing and electrolytic treatment in the same manner as in Example 1. Details will be described in a comparative example described later. On the other hand, when the electrode of this example was used, the fluctuation range was reduced to 4.2%.
本実施例の電極は、金属酸化物として酸化ジルコニウムを分散した白金電極である。本電極におけるジルコニウム含有量は金属換算で0.2%であり、圧延加工および機械研磨において生じた、表面変質層が除去され、面方位(220)に配向率80%以上で優先配向している。本電極を作用極として用いた分析装置においては、電極表面内におけるエッチング速度差が小さいため、面内で不均一な溶解を抑制し、かつ、分析を繰り返しても最表面に露出する結晶の配向性の変化が小さく、表面状態の変動を抑制することが可能になり、電気化学応答が長期間にわたり変動が少なく、安定した測定結果が得られるという効果が認められた。 The electrode of this example is a platinum electrode in which zirconium oxide is dispersed as a metal oxide. Zirconium content in this electrode is 0.2% in terms of metal, the surface altered layer generated in rolling and mechanical polishing is removed, and the orientation is preferentially oriented in the plane orientation (220) at an orientation rate of 80% or more. . In the analyzer using this electrode as a working electrode, since the etching rate difference in the electrode surface is small, non-uniform dissolution is suppressed in the surface, and the orientation of crystals exposed on the outermost surface even after repeated analysis It was confirmed that the change in the property was small, the fluctuation of the surface state could be suppressed, the electrochemical response was little changed over a long period of time, and a stable measurement result was obtained.
実施例1では、複合材料をフッ素樹脂に埋め込んだ電極としたが、金属酸化物分散型複合材料を電極として用い、その電極がデータ安定性に効果を示すものである。そのため、形態については特に限定されない。例えば、図7(図8は図7の側面図)に示すような樹脂に埋め込まない板状の形態でも同様の効果が得られることを確認した。 In Example 1, an electrode in which a composite material is embedded in a fluororesin is used. However, a metal oxide dispersed composite material is used as an electrode, and the electrode exhibits an effect on data stability. Therefore, the form is not particularly limited. For example, it was confirmed that the same effect can be obtained even in a plate-like form not embedded in the resin as shown in FIG. 7 (FIG. 8 is a side view of FIG. 7).
次に、本発明の実施例2について説明する。この実施例2の電極およびそれを用いた電気化学的分析装置は、電極を製造する際、電解研磨処理中にサイクリックボルタンメトリにより表面状態を診断しながら、電極表面の変質層を除去した点を除き、実施例1と同様である。サイクリックボルタンメトリは、電解液として窒素置換したpH6.86の燐酸緩衝液を用い、作用極を作用極2、対極を白金ワイヤ、参照極をAg|AgClとし、電位走査範囲−0.6〜1.1V,走査速度0.1V/sの条件で実施した。測定結果を図9に示す。サイクリックボルタンメトリ結果より得られた複数の水素吸脱着の電流ピークの
うち、−0.37〜−0.31Vに見られるピークをaとし、−0.31〜−0.2Vに見られるピークをbとし、それらのピーク面積,面積比b/aを計算する。面積比が80%以下となるまで電解処理を行い、作用極2を得た。
Next, a second embodiment of the present invention will be described. In the electrode of Example 2 and the electrochemical analysis apparatus using the electrode, the altered layer on the electrode surface was removed while diagnosing the surface state by cyclic voltammetry during the electrolytic polishing process when the electrode was manufactured. Except for this point, the second embodiment is the same as the first embodiment. Cyclic voltammetry uses a pH 6.86 phosphate buffer solution substituted with nitrogen as the electrolyte, the working electrode is the working electrode 2, the counter electrode is platinum wire, the reference electrode is Ag | AgCl, and the potential scanning range is -0.6. It was carried out under conditions of ˜1.1 V and a scanning speed of 0.1 V / s. The measurement results are shown in FIG. Among a plurality of hydrogen adsorption / desorption current peaks obtained from the cyclic voltammetry results, a peak at −0.37 to −0.31 V is defined as a, and −0.31 to −0.2 V is observed. The peak is b, and the peak area and area ratio b / a are calculated. Electrolytic treatment was performed until the area ratio became 80% or less, and working electrode 2 was obtained.
本発明の実施例2による作用極を用いた電気化学的分析装置により実施例1と同様に繰り返し分析した結果、変動幅は3.8%と良好な結果が得られた。電極をX線回折解析した結果、配向率96%で(220)方位に優先配向していることがわかった。本電極を作用極として用いた分析装置においては、電極表面内におけるエッチング速度差が小さいため、面内で不均一な溶解を抑制し、かつ、分析を繰り返しても最表面に露出する結晶の配向性の変化が小さく、表面状態の変動を抑制することが可能になり、電気化学応答が長期間にわたり変動が少なく、安定した測定結果が得られるという効果が認められた。 As a result of repeated analysis in the same manner as in Example 1 by the electrochemical analyzer using the working electrode according to Example 2 of the present invention, a favorable range of 3.8% was obtained. As a result of X-ray diffraction analysis of the electrode, it was found that the orientation was 96% and the preferred orientation was in the (220) direction. In the analyzer using this electrode as a working electrode, since the etching rate difference in the electrode surface is small, non-uniform dissolution is suppressed in the surface, and the orientation of crystals exposed on the outermost surface even after repeated analysis It was confirmed that the change in the property was small, the fluctuation of the surface state could be suppressed, the electrochemical response was little changed over a long period of time, and a stable measurement result was obtained.
本発明の実施例2では、ピークa,bを表面変質層除去度合いの判断基準として用いたが、−0.48〜−0.37Vに見られるピークcとピークbからb/cを計算し、判断基準としてb/cが35%以下とした場合においても同様の効果が得られることが確認できた。 In Example 2 of the present invention, peaks a and b were used as criteria for determining the degree of removal of the surface altered layer, but b / c was calculated from peak c and peak b seen at -0.48 to -0.37 V. It was confirmed that the same effect was obtained even when b / c was set to 35% or less as a criterion.
図10,図11を用いて、本発明の一実施形態による電気化学的分析装置について説明する。本発明の一実施形態による電気化学的分析装置の構成を図10に示す。図10の電気化学的分析装置に用いるフローセルの分解構成図を図11に示す。 An electrochemical analyzer according to an embodiment of the present invention will be described with reference to FIGS. FIG. 10 shows the configuration of an electrochemical analyzer according to an embodiment of the present invention. FIG. 11 shows an exploded configuration diagram of a flow cell used in the electrochemical analyzer of FIG.
図10において、図1に示した電気化学セル1がフローセル20に置き換わっている点以外は、図1に示した例と図10に示した例とは同等となっている。 In FIG. 10, the example shown in FIG. 1 and the example shown in FIG. 10 are the same except that the electrochemical cell 1 shown in FIG.
図11において、電気化学セルとしてのフローセル20は、(a)に示す2枚の電気絶縁性基板30,32と、シール部材31を(b)のように積層して形成した。絶縁性基板30としてポリエーテルエーテルケトンを用いた。絶縁性基板30の一方の面には、作用極34が固定されている。ここで、作用極2に用いる電極材料として、白金中に酸化ジルコニウムを分散させた複合材料を用いた。前記複合材料は、以下に示す製法に従って作製した。粒径約0.5μmの白金粉末と炭酸カルシウムとを混合した懸濁液をボールミル処理し、その懸濁液を1100℃で高温熱処理し、その高温熱処理により得られる塊を水に投入した後、硝酸処理を行った。得られた白金粉末2kgを、純水4Lに投入し、白金懸濁液を作製した。その白金懸濁液に硝酸ジルコニウム溶液9gを混合し、常温で約3分間撹拌した後、アンモニア水溶液2.0gを加えてpH7.5に調整し、混合液から濾過回収することにより、水酸化ジルコニウム担持白金粉末を得た。回収した水酸化ジルコニウム担持白金を、洗浄処理後、120℃大気雰囲気中で乾燥処理を行った。続いて、この水酸化ジルコニウム担持白金を開口径300μmのふるいを通過させた。この水酸化ジルコニウム担持白金を容器に充填し、100MPaで冷間圧成形して成形体を得た。この成形体は、1200℃の大気雰囲気中にて、1時間の焼結処理を施し、続いてエアハンマによる鍛造加工をすることで酸化ジルコニウムが分散した白金インゴットを得た。このインゴットを圧下率90%となるように冷間圧延処理を行った。続いて、1400℃,1hrの再結晶加熱処理を行うことにより、板厚150μmの複合材料を製造した。得られた複合材料には酸化ジルコニウムが金属換算で約0.1%含まれていた。尚、複合材料中に含有するジルコニウム濃度は、材料を王水で溶解後、誘導結合プラズマ試料分析法(ICP−MS)により分析した。 In FIG. 11, a flow cell 20 as an electrochemical cell is formed by laminating two electrically insulating substrates 30 and 32 shown in (a) and a seal member 31 as shown in (b). Polyether ether ketone was used as the insulating substrate 30. A working electrode 34 is fixed to one surface of the insulating substrate 30. Here, as an electrode material used for the working electrode 2, a composite material in which zirconium oxide was dispersed in platinum was used. The composite material was produced according to the manufacturing method shown below. A suspension obtained by mixing platinum powder having a particle size of about 0.5 μm and calcium carbonate is ball milled, the suspension is subjected to high-temperature heat treatment at 1100 ° C., and a lump obtained by the high-temperature heat treatment is poured into water. Nitric acid treatment was performed. 2 kg of the obtained platinum powder was put into 4 L of pure water to prepare a platinum suspension. The platinum suspension was mixed with 9 g of a zirconium nitrate solution, stirred for about 3 minutes at room temperature, adjusted to pH 7.5 by adding 2.0 g of an aqueous ammonia solution, and recovered by filtration from the mixed solution. A supported platinum powder was obtained. The recovered zirconium hydroxide-supported platinum was washed and then dried in an air atmosphere at 120 ° C. Subsequently, the zirconium hydroxide-supported platinum was passed through a sieve having an opening diameter of 300 μm. The zirconium hydroxide-supported platinum was filled in a container and cold-pressed at 100 MPa to obtain a molded body. This molded body was subjected to a sintering treatment for 1 hour in an air atmosphere at 1200 ° C., and then forged by an air hammer to obtain a platinum ingot in which zirconium oxide was dispersed. The ingot was cold-rolled so that the reduction rate was 90%. Subsequently, a recrystallization heat treatment at 1400 ° C. for 1 hr was performed to produce a composite material having a plate thickness of 150 μm. The obtained composite material contained about 0.1% of zirconium oxide in terms of metal. The concentration of zirconium contained in the composite material was analyzed by inductively coupled plasma sample analysis (ICP-MS) after the material was dissolved in aqua regia.
作用極34が固定化された絶縁性基板30は図16に示す製造フローに従って作製した。 The insulating substrate 30 on which the working electrode 34 was fixed was manufactured according to the manufacturing flow shown in FIG.
電極化部50aにて、上記した複合材料に絶縁性樹脂被覆アルミ配線39をはんだにより接続することにより、作用極34を得た。次に、樹脂包埋部50bにおいて、絶縁性基板30の表面に予め設けられた凹部に埋め込み、接着剤により固着した。その後、機械研磨部50cにおいて、絶縁性基板30と電極との表面段差が無くなるまで耐水研磨紙,ダイヤモンドペースト,アルミナにより順次機械研磨し、鏡面にした。その後、電解研磨部50dにおいて0.2mol/L水酸化カリウム水溶液中で−1.2V/0.5秒,3.0V/1.5秒の矩形パルス状の電位印加を10000回繰り返した。尚、得られた作用極34
の表面Ra(算術平均粗さ)は約0.6μmであった。最後に、セル組立部50eにおいてシール部材31および絶縁性基板32を積層することにより、電気化学セル20を形成した。
The working electrode 34 was obtained by connecting the insulating resin-coated aluminum wiring 39 to the above-described composite material by soldering at the electrode-forming portion 50a. Next, in the resin embedding part 50b, the resin embedding part 50b was embedded in a recess provided in advance on the surface of the insulating substrate 30, and fixed by an adhesive. Thereafter, in the mechanical polishing portion 50c, mechanical polishing was sequentially performed with water-resistant polishing paper, diamond paste, and alumina until the surface difference between the insulating substrate 30 and the electrode disappeared to give a mirror surface. Thereafter, in the electropolishing section 50d, the application of a rectangular pulsed potential of −1.2 V / 0.5 seconds and 3.0 V / 1.5 seconds in a 0.2 mol / L potassium hydroxide aqueous solution was repeated 10,000 times. The obtained working electrode 34 was obtained.
The surface Ra (arithmetic mean roughness) of this was about 0.6 μm. Finally, the electrochemical cell 20 was formed by laminating the sealing member 31 and the insulating substrate 32 in the cell assembly 50e.
絶縁性基板32は、透明なアクリル材によって形成した。絶縁性基板32の一方の面に、対極35を固定した。対極35は、白金を電極の形状に加工した後、1000℃にて、1時間焼鈍処理を施したものを用いた。絶縁性基板32の表面には、凹部が形成されており、この凹部に焼鈍処理を施した対極35を埋め込み、固着した後、対極35の表面を鏡面研磨した。尚、対極35の形状は、板状に限られるものではなく、櫛歯状,メッシュ状,棒状でもよい。また、電極材料は、白金に限るものでなく、他の白金族金属でもよい。
対極35は、作用極と同様に、機械研磨処理後、電解研磨処理を施した白金を用いてもよい。
The insulating substrate 32 was made of a transparent acrylic material. A counter electrode 35 was fixed to one surface of the insulating substrate 32. As the counter electrode 35, platinum was processed into an electrode shape and then annealed at 1000 ° C. for 1 hour. A concave portion is formed on the surface of the insulating substrate 32, and a counter electrode 35 subjected to annealing treatment is embedded and fixed in the concave portion, and then the surface of the counter electrode 35 is mirror-polished. The shape of the counter electrode 35 is not limited to a plate shape, and may be a comb shape, a mesh shape, or a rod shape. Further, the electrode material is not limited to platinum but may be other platinum group metals.
Similarly to the working electrode, the counter electrode 35 may be platinum that has been subjected to electrolytic polishing after mechanical polishing.
対極35も作用極34と同様、絶縁性基板32に埋め込まれる前に電気配線40とはんだにより接続している。そして、電気配線39,40は、絶縁性基板30,32に開けられた穴に通してある。 Similarly to the working electrode 34, the counter electrode 35 is connected to the electric wiring 40 by solder before being embedded in the insulating substrate 32. The electric wirings 39 and 40 are passed through holes formed in the insulating substrates 30 and 32.
シール部材31は、フッ素系樹脂製であり、中央に開口部36を設けた。絶縁性基板30には配管37,38と連結するための溶液注入口37a,溶液排出口38aが設けられており、これら2つの孔は開口部36の内周に位置するよう配置され、開口部36部分に溶液の出し入れが可能となる。作用極34と対極35は、シール部材31の開口部36を介して対向している。 The seal member 31 is made of a fluororesin and has an opening 36 at the center. The insulating substrate 30 is provided with a solution injection port 37a and a solution discharge port 38a for connection to the pipes 37 and 38, and these two holes are arranged so as to be located on the inner periphery of the opening 36. The solution can be taken in and out of 36 parts. The working electrode 34 and the counter electrode 35 face each other through the opening 36 of the seal member 31.
絶縁性基板30,32およびシール部材31の4隅にはねじ穴33が配置され、それぞれに、ネジを通し、絶縁性基板30とシール部材31と絶縁性基板32とを固定圧着して、フローセル20を形成した。 Screw holes 33 are arranged at the four corners of the insulating substrates 30 and 32 and the sealing member 31, and a screw is passed through each of the insulating substrates 30 and 32, and the insulating substrate 30, the sealing member 31, and the insulating substrate 32 are fixed and pressure bonded to each other. 20 was formed.
絶縁性基板30において、作用極が配設される面と反対側の面には、フッ素樹脂製の配管37,38を固定接続した。配管37は、フローセル20に測定溶液などを導入する機構に接続され、配管38は、測定済みの溶液を排出するための流路として用いる。また、参照極(図示せず)は、配管38、すなわち溶液の排出側配管部に配置し、作用極に電位印加する際の基準電極として利用した。 In the insulating substrate 30, fluororesin pipes 37 and 38 are fixedly connected to the surface opposite to the surface on which the working electrode is disposed. The pipe 37 is connected to a mechanism for introducing a measurement solution or the like into the flow cell 20, and the pipe 38 is used as a flow path for discharging the measured solution. A reference electrode (not shown) was disposed in the pipe 38, that is, the solution discharge side pipe section, and was used as a reference electrode when applying a potential to the working electrode.
本発明のフローセルは図11に示した実施形態に特に限定されない。以下その他のフローセルの例について説明する。 The flow cell of the present invention is not particularly limited to the embodiment shown in FIG. Examples of other flow cells will be described below.
図12において、フローセル60は、(a)に示す各部材、すなわち2枚の電気絶縁性基板70,72と、シール部材71が(b)のように積層されて形成される。絶縁性基板70の一方の面には、作用極74が固定されている。絶縁性基板72の一方の面には、対極75が固定されている。 In FIG. 12, the flow cell 60 is formed by laminating each member shown in (a), that is, two electrically insulating substrates 70 and 72 and a seal member 71 as shown in (b). A working electrode 74 is fixed to one surface of the insulating substrate 70. A counter electrode 75 is fixed to one surface of the insulating substrate 72.
作用極74,対極75は、それぞれ絶縁性基板70,72に埋め込まれる前に電気配線79,80とはんだ付けにより接続されており、電気配線79,80は、絶縁性基板70,72に開けられた穴に通してある。 The working electrode 74 and the counter electrode 75 are connected to the electric wirings 79 and 80 by soldering before being embedded in the insulating substrates 70 and 72, respectively. The electric wirings 79 and 80 are opened on the insulating substrates 70 and 72. Through the hole.
シール部材71中央には開口部76を有している。絶縁性基板72には配管77,78と連結するための溶液注入口77a,溶液排出口78aが設けられており、これら2つの孔は開口部76の内部に位置するよう配置され、開口部76部分に溶液の出し入れが可能となる。作用極74と対極75は、シール部材71の開口部76を介して対向している。 An opening 76 is provided at the center of the seal member 71. The insulating substrate 72 is provided with a solution injection port 77a and a solution discharge port 78a for connecting to the pipes 77 and 78. These two holes are arranged so as to be located inside the opening 76, and the opening 76 is provided. The solution can be taken in and out of the part. The working electrode 74 and the counter electrode 75 are opposed to each other through the opening 76 of the seal member 71.
絶縁性基板70,72およびシール部材71の4隅にはねじ穴73が配置され、それぞれに、ネジを通し、絶縁性基板70とシール部材71と絶縁性基板72とを固定圧着して、フローセル60を形成する。 Screw holes 73 are arranged at the four corners of the insulating substrates 70 and 72 and the seal member 71, and screws are passed through them, and the insulating substrate 70, the seal member 71, and the insulating substrate 72 are fixed and crimped to each other, and the flow cell. 60 is formed.
絶縁性基板72において、対極75が配設される面と反対側の面には、フッ素樹脂製の配管77,78が固定接続されている。配管77は、フローセル60に測定溶液などを導入する機構に接続され、配管78は、測定済みの溶液を排出するための流路として用いる。また、参照極(図示せず)は、配管78、すなわち溶液の排出側配管部に配置され、作用極に電位印加する際の基準電極として利用する。 In the insulating substrate 72, fluororesin pipes 77 and 78 are fixedly connected to the surface opposite to the surface on which the counter electrode 75 is disposed. The pipe 77 is connected to a mechanism for introducing a measurement solution or the like into the flow cell 60, and the pipe 78 is used as a flow path for discharging the measured solution. A reference electrode (not shown) is disposed in the pipe 78, that is, the solution discharge side pipe section, and is used as a reference electrode when applying a potential to the working electrode.
図13において、フローセル90は、(a)に示す各部材、すなわち2枚の電気絶縁性基板100,102と、シール部材101が(b)のように積層されて形成される。絶縁性基板100の一方の面には作用極104が固定されている。絶縁性基板102の一方の面には対極105が固定されている。 In FIG. 13, a flow cell 90 is formed by laminating each member shown in (a), that is, two electrically insulating substrates 100 and 102 and a seal member 101 as shown in (b). A working electrode 104 is fixed to one surface of the insulating substrate 100. A counter electrode 105 is fixed to one surface of the insulating substrate 102.
作用極104,対極105は、それぞれ絶縁性基板100,102に埋め込まれる前に電気配線109,110とはんだ付けにより接続されており、電気配線109,110は、絶縁性基板100,102に開けられた穴に通してある。 The working electrode 104 and the counter electrode 105 are connected to the electrical wirings 109 and 110 by soldering before being embedded in the insulating substrates 100 and 102, respectively. The electrical wirings 109 and 110 are opened on the insulating substrates 100 and 102. Through the hole.
シール部材101中央には開口部106を有している。開口部の形状はフローセル内に供給される各種溶液が滞留することなく、円滑に液置換が行われる形状であれば、特に限定されない。絶縁性基板100には配管107,108と連結するための溶液注入口107a,溶液排出口108aが設けられており、これら2つの孔は開口部106の内部に位置するよう配置され、開口部106部分に溶液の出し入れが可能となる。作用極104と対極105は、シール部材101の開口部106を介して対向している。 An opening 106 is provided at the center of the seal member 101. The shape of the opening is not particularly limited as long as various solutions supplied in the flow cell do not stay and can be smoothly replaced. The insulating substrate 100 is provided with a solution inlet 107 a and a solution outlet 108 a for connecting to the pipes 107 and 108, and these two holes are arranged so as to be located inside the opening 106. The solution can be taken in and out of the part. The working electrode 104 and the counter electrode 105 are opposed to each other through the opening 106 of the seal member 101.
絶縁性基板100,102およびシール部材101の4隅にはねじ穴103が配置され、それぞれに、ネジを通し、絶縁性基板100とシール部材101と絶縁性基板102とを固定圧着して、フローセル90を形成する。 Screw holes 103 are arranged at the four corners of the insulating substrates 100 and 102 and the seal member 101. A screw is passed through each of the insulating substrates 100 and 102, and the insulating substrate 100, the seal member 101, and the insulating substrate 102 are fixedly crimped to each other. 90 is formed.
絶縁性基板100において、側面には、フッ素樹脂製の配管107,108が固定接続されている。配管107は、フローセル90に測定溶液などを導入する機構に接続され、配管108は、測定済みの溶液を排出するための流路として用いる。また、参照極(図示せず)は、配管108、すなわち溶液の排出側配管部に配置され、作用極に電位印加する際の基準電極として利用する。 In the insulating substrate 100, fluororesin pipes 107 and 108 are fixedly connected to the side surfaces. The pipe 107 is connected to a mechanism for introducing a measurement solution or the like into the flow cell 90, and the pipe 108 is used as a flow path for discharging the measured solution. A reference electrode (not shown) is disposed in the pipe 108, that is, the solution discharge side pipe section, and is used as a reference electrode when a potential is applied to the working electrode.
図14において、フローセル120は、(a)に示す各部材、すなわち2枚の電気絶縁性基板130,132と、シール部材131が(b)のように積層されて形成される。絶縁性基板132の一方の面には、対極135が固定されている。絶縁性基板130の中央部には(c)に示すように作用極134を配置する凹部および作用極との接続を可能にする通電用ボルト141のネジ溝143が形成されている。作用極134を絶縁性基板130に接着剤を用いて固着した後、鏡面研磨を行う。その後、通電用プレート142を介して通電用ボルト141をネジ溝143に締め込む。通電用プレートは例えば金,錫やアルミニウムなど、軟らかく抵抗率の小さい金属であれば特に限定されない。通電用ボルト141は電気配線139と接続されており、作用極134との電気的接続を可能にしている。 14, the flow cell 120 is formed by laminating each member shown in (a), that is, two electrically insulating substrates 130 and 132 and a seal member 131 as shown in (b). A counter electrode 135 is fixed to one surface of the insulating substrate 132. In the central portion of the insulating substrate 130, as shown in (c), a recess in which the working electrode 134 is disposed and a thread groove 143 of the energizing bolt 141 that enables connection to the working electrode are formed. After the working electrode 134 is fixed to the insulating substrate 130 with an adhesive, mirror polishing is performed. Thereafter, the energizing bolt 141 is tightened into the thread groove 143 through the energizing plate 142. The energizing plate is not particularly limited as long as it is a soft metal having a low resistivity, such as gold, tin, or aluminum. The energizing bolt 141 is connected to the electrical wiring 139 and enables electrical connection to the working electrode 134.
対極135は絶縁性基板132に埋め込まれる前に電気配線140とはんだ付けにより接続されており、電気配線140は、絶縁性基板132に開けられた穴に通してある。 The counter electrode 135 is connected to the electric wiring 140 by soldering before being embedded in the insulating substrate 132, and the electric wiring 140 is passed through a hole formed in the insulating substrate 132.
シール部材131中央には開口部136を有している。絶縁性基板132には配管137,138と連結するため溶液注入口137a,溶液排出口138aが設けられており、これら2つの孔は開口部136の内部に位置するよう配置され、開口部136部分に溶液の出し入れが可能となる。作用極134と対極135は、シール部材131の開口部136を介して対向している。 An opening 136 is provided at the center of the seal member 131. The insulating substrate 132 is provided with a solution injection port 137a and a solution discharge port 138a for connection to the pipes 137 and 138. These two holes are arranged so as to be located inside the opening 136, and the opening 136 part The solution can be taken in and out. The working electrode 134 and the counter electrode 135 are opposed to each other through the opening 136 of the seal member 131.
絶縁性基板130,132およびシール部材131の4隅にはねじ穴133が配置され、それぞれに、ネジを通し、絶縁性基板130とシール部材131と絶縁性基板132とを固定圧着して、フローセル120を形成する。 Screw holes 133 are arranged at the four corners of the insulating substrates 130 and 132 and the seal member 131. A screw is passed through each of the insulating substrates 130 and 132, and the insulating substrate 130, the seal member 131, and the insulating substrate 132 are fixedly crimped to each other. 120 is formed.
絶縁性基板132において、側面には、フッ素樹脂製の配管137,138が固定接続されている。配管137は、フローセル120に測定溶液などを導入する機構に接続され、配管138は、測定済みの溶液を排出するための流路として用いる。また、参照極(図示せず)は、配管138、すなわち溶液の排出側配管部に配置され、作用極に電位印加する際の基準電極として利用する。 In the insulating substrate 132, fluororesin pipes 137 and 138 are fixedly connected to the side surfaces. The pipe 137 is connected to a mechanism for introducing a measurement solution or the like into the flow cell 120, and the pipe 138 is used as a flow path for discharging the measured solution. Further, a reference electrode (not shown) is disposed in the pipe 138, that is, the solution discharge side pipe section, and is used as a reference electrode when a potential is applied to the working electrode.
図15において、フローセル180は、絶縁性基板190,192で作用極194をO−リング191を介して積層することにより形成する。絶縁性基板190,192外周にはねじ穴193が配置され、それぞれにネジを通して締め込むことにより、フローセル180を形成する。 In FIG. 15, the flow cell 180 is formed by laminating a working electrode 194 with insulating substrates 190 and 192 through an O-ring 191. Screw holes 193 are disposed on the outer periphery of the insulating substrates 190 and 192, and the flow cell 180 is formed by tightening the screws through the holes.
絶縁性基板192中央部には対極200が埋め込まれており、フローセル内部に突出した構造となっている。また、絶縁性基板192には、フッ素樹脂製の配管197,198が固定接続されている。配管197は、フローセル180に測定溶液などを導入する機構に接続され、配管198は、測定済みの溶液を排出するための流路として用いる。また、参照極(図示せず)は、配管198、すなわち溶液の排出側配管部に配置され、作用極に電位印加する際の基準電極として利用する。 A counter electrode 200 is embedded in the central portion of the insulating substrate 192, and has a structure protruding into the flow cell. In addition, fluororesin pipes 197 and 198 are fixedly connected to the insulating substrate 192. The pipe 197 is connected to a mechanism for introducing a measurement solution or the like into the flow cell 180, and the pipe 198 is used as a flow path for discharging the measured solution. Further, a reference electrode (not shown) is disposed in the pipe 198, that is, the solution discharge side pipe section, and is used as a reference electrode when a potential is applied to the working electrode.
作用極194,対極195は、電気配線199,200とはんだ付けにより接続されている。 The working electrode 194 and the counter electrode 195 are connected to the electrical wirings 199 and 200 by soldering.
次に、図10,図11を用いて、本発明の実施例3の電気化学的分析装置の全体構成について説明する。図1と同様な構成の部分は、重複するので詳細な説明は省略する。 Next, the overall configuration of the electrochemical analyzer according to the third embodiment of the present invention will be described with reference to FIGS. Since the same components as those in FIG. 1 are duplicated, a detailed description thereof will be omitted.
測定溶液と緩衝液を溶液導入管13内にて混合し、フローセル20中に注入した。混合液がフローセル20に貯液している間に、電圧印加手段5により作用極34に所定の電位を印加し、被測定対象物の電気化学的測定を行った。フローセル20内の作用極における電気化学的反応により得られた信号を、電気配線7を介して信号処理のための測定手段6に伝達した。 The measurement solution and the buffer solution were mixed in the solution introduction tube 13 and injected into the flow cell 20. While the liquid mixture was stored in the flow cell 20, a predetermined potential was applied to the working electrode 34 by the voltage applying means 5, and the measurement object was subjected to electrochemical measurement. A signal obtained by an electrochemical reaction at the working electrode in the flow cell 20 was transmitted to the measuring means 6 for signal processing via the electric wiring 7.
尚、透明な絶縁性樹脂32上部に検出器を配置することにより電気化学反応により生じる変化を光学的に測定することも可能である。 Note that a change caused by an electrochemical reaction can be optically measured by disposing a detector on the transparent insulating resin 32.
フローセル20にて測定の終了した測定溶液を溶液排出機構15によって吸引し、溶液排出管14を通って廃液容器16に廃棄した。 The measurement solution for which measurement was completed in the flow cell 20 was sucked by the solution discharge mechanism 15 and discarded into the waste liquid container 16 through the solution discharge pipe 14.
本実施例3で用いた作用極34は白金に酸化ジルコニウムを分散した複合材料に電気配線を施した電極である。電極表面のX線回折測定を実施した結果、面指数(220)が優先的に配向しており、配向率85%であることがわかった。 The working electrode 34 used in Example 3 is an electrode obtained by applying electrical wiring to a composite material in which zirconium oxide is dispersed in platinum. As a result of X-ray diffraction measurement of the electrode surface, it was found that the plane index (220) was preferentially oriented and the orientation rate was 85%.
図11のフローセルおよび図10の電気化学的分析装置を用いて、測定溶液として血清中のTSHを直径3μmの磁性粒子表面に吸着させた複合体を分析し、洗浄液として、例えば水酸化カリウム水溶液を各測定の終了毎にフローセルに導入する方法で測定を行った。実施例1と同様に、分析1回目と60000回目との変動幅を求めると、5.0%であった。本電極を作用極として用いたフローセルおよび分析装置においては、電極表面内におけるエッチング速度差が小さいため、面内で不均一な溶解を抑制し、かつ、分析を繰り返しても最表面に露出する結晶の配向性の変化が小さく、表面状態の変動を抑制することが可能になり、電気化学応答が長期間にわたり変動が少なく、安定した測定結果が得られるという効果が認められた。また、分析液,洗浄液の液置換を安定して実施することが可能となり、電気化学応答が長期間にわたり変動が少なく、安定した測定結果が得られるという効果が認められた。さらに、表面に生成したピットが電極表面の磁性粒子を安定化させることにより、安定した測定結果が得られるという効果が認められた。 Using the flow cell of FIG. 11 and the electrochemical analyzer of FIG. 10, a complex in which TSH in serum is adsorbed on the surface of magnetic particles having a diameter of 3 μm is analyzed as a measurement solution, and, for example, an aqueous potassium hydroxide solution is used as a washing solution. Measurement was carried out by a method introduced into the flow cell at the end of each measurement. In the same manner as in Example 1, the fluctuation range between the first analysis and the 60,000th analysis was 5.0%. In flow cells and analyzers that use this electrode as a working electrode, the etching rate difference in the electrode surface is small, so that non-uniform dissolution in the surface is suppressed, and the crystal that is exposed on the outermost surface even after repeated analysis. The change in the orientation of the film was small, it was possible to suppress fluctuations in the surface state, and the electrochemical response was less fluctuated over a long period of time, and an effect that a stable measurement result was obtained was recognized. In addition, it was possible to stably perform the liquid replacement of the analysis solution and the cleaning solution, and the effect that the electrochemical response was less varied over a long period of time and a stable measurement result was obtained was confirmed. Furthermore, the effect that the stable measurement result was obtained by the pit produced | generated on the surface stabilizing the magnetic particle on the electrode surface was recognized.
本発明の実施例4について説明する。実施例4では既知濃度のグルコースを分析対象とし、実施例1の電極表面上に酵素を固定化したことおよび白金中に分散させる金属酸化物を酸化ニオブとしたことを除き、実施例1と同様に繰り返し測定を行った。白金中に分散した金属酸化物の含有量は金属換算で0.06%であった。 Embodiment 4 of the present invention will be described. Example 4 is the same as Example 1 except that glucose of a known concentration is analyzed, the enzyme is immobilized on the electrode surface of Example 1, and the metal oxide dispersed in platinum is niobium oxide. The measurement was repeated. The content of the metal oxide dispersed in platinum was 0.06% in terms of metal.
測定した結果、表1に示すように、分析1回目と60000回目との変動幅を求めると、4.0%であり、比較例2に比べて変動幅が小さくなっていることがわかった。これは、本電極を作用極として用いた分析装置においては、電極表面内におけるエッチング速度差が小さいため、面内で不均一な溶解を抑制し、かつ、分析を繰り返しても最表面に露出する結晶の配向性の変化が小さく、表面状態の変動を抑制することが可能になり、結果的に電極表面に修飾する酵素量を安定に制御することができ、また、分析液,洗浄液の液置換を安定して実施することが可能となり、電気化学応答が長期間にわたり変動が少なく、安定した測定結果が得られるという効果が認められた。 As a result of the measurement, as shown in Table 1, it was found that the fluctuation range between the first analysis and the 60000th analysis was 4.0%, which was smaller than that of Comparative Example 2. This is because, in an analyzer using this electrode as a working electrode, the difference in etching rate in the electrode surface is small, so that non-uniform dissolution in the surface is suppressed, and it is exposed to the outermost surface even after repeated analysis. The change in crystal orientation is small and fluctuations in the surface state can be suppressed. As a result, the amount of enzyme that modifies the electrode surface can be controlled stably, and the analysis solution and cleaning solution can be replaced. Thus, it was confirmed that the electrochemical response was less varied over a long period of time, and a stable measurement result was obtained.
本発明の実施例5について説明する。実施例5では既知濃度の尿素を分析対象としたことおよび白金中に分散させる金属酸化物を酸化タンタルとしたことを除き、実施例1の測定方法に準拠して繰り返し分析測定を行った。白金中に分散した金属酸化物の含有量は金属換算で0.08%であった。測定溶液容器8において、検体試料とウレアーゼ、次にβ−ニコチンアミドアデニンジヌクレオチド(NADH),フェリシアン化カリウム存在下でさらにグルタミン酸脱水素酵素を作用させることによりフェロシアン化カリウムを生成させた。測定溶液容器8からフェロシアン化カリウムを含む測定溶液、緩衝液溶液9から緩衝液を溶液導入管13内に導入して混合し、溶液注入機構12により電気化学セル1中に注入し、電気化学測定を行った。繰り返し測定を行った結果、表1に示すように、分析1回目と60000回目との変動幅を求めると、2.5%であり、比較例3に比べて変動幅が小さくなっていることがわかった。これは、本電極を作用極として用いた分析装置においては、電極表面内におけるエッチング速度差が小さいため、面内で不均一な溶解を抑制し、かつ、分析を繰り返しても最表面に露出する結晶の配向性の変化が小さく、表面状態の変動を抑制することが可能になり、また、分析液,洗浄液の液置換を安定して実施することが可能となり、電気化学応答が長期間にわたり変動が少なく、安定した測定結果が得られるという効果が認められた。 A fifth embodiment of the present invention will be described. In Example 5, analysis was repeatedly performed according to the measurement method of Example 1 except that urea of a known concentration was used as an analysis target and that the metal oxide dispersed in platinum was tantalum oxide. The content of the metal oxide dispersed in platinum was 0.08% in terms of metal. In the measurement solution container 8, potassium ferrocyanide was produced by further acting glutamate dehydrogenase in the presence of the specimen sample and urease, then β-nicotinamide adenine dinucleotide (NADH) and potassium ferricyanide. A measurement solution containing potassium ferrocyanide from the measurement solution container 8 and a buffer solution from the buffer solution 9 are introduced and mixed in the solution introduction tube 13 and injected into the electrochemical cell 1 by the solution injection mechanism 12 to perform electrochemical measurement. went. As a result of repeated measurement, as shown in Table 1, when the fluctuation range between the first analysis and the 60000th analysis is obtained, it is 2.5%, and the fluctuation range is smaller than that of Comparative Example 3. all right. This is because, in an analyzer using this electrode as a working electrode, the difference in etching rate in the electrode surface is small, so that non-uniform dissolution in the surface is suppressed, and it is exposed to the outermost surface even after repeated analysis. The change in crystal orientation is small, it is possible to suppress fluctuations in the surface state, and it is possible to stably perform liquid replacement of analysis liquid and cleaning liquid, and the electrochemical response fluctuates over a long period of time. There was little effect, and the effect that a stable measurement result was obtained was recognized.
本発明の実施例6について説明する。実施例6では既知濃度のコレステロールを分析対象としたこと、母材金属を白金−2%金合金としたことおよび母材中に分散させる金属酸化物を酸化ジルコニウムとしたことを除き、実施例5の測定方法に準拠して繰り返し分析測定を行った。母材中に分散した金属酸化物の含有量は金属換算で0.1%であった。測定溶液容器8において、検体試料とコレステロールオキシダーゼを作用させることにより過酸化水素を生成した。測定溶液容器8から過酸化水素を含む測定溶液、緩衝液溶液9から緩衝液を溶液導入管13内に導入して混合し、溶液注入機構12により電気化学セル1中に注入し、電気化学測定を行った。繰り返し測定を行った結果、表1に示すように、分析1回目と60000回目との変動幅を求めると、5.0%であり、比較例4に比べて変動幅が小さくなっていることがわかった。これは、本電極を作用極として用いた分析装置においては、電極表面内におけるエッチング速度差が小さいため、面内で不均一な溶解を抑制し、かつ、分析を繰り返しても最表面に露出する結晶の配向性の変化が小さく、表面状態の変動を抑制することが可能になり、また、分析液,洗浄液の液置換を安定して実施することが可能となり、電気化学応答が長期間にわたり変動が少なく、安定した測定結果が得られるという効果が認められた。 A sixth embodiment of the present invention will be described. In Example 6, Example 5 except that a known concentration of cholesterol was the object of analysis, the base metal was a platinum-2% gold alloy, and the metal oxide dispersed in the base was zirconium oxide. Analytical measurement was repeatedly performed according to the measurement method. The content of the metal oxide dispersed in the base material was 0.1% in terms of metal. In the measurement solution container 8, hydrogen peroxide was generated by allowing a sample sample and cholesterol oxidase to act. A measurement solution containing hydrogen peroxide from the measurement solution container 8 and a buffer solution from the buffer solution 9 are introduced into the solution introduction tube 13 and mixed, and injected into the electrochemical cell 1 by the solution injection mechanism 12 to perform electrochemical measurement. Went. As a result of the repeated measurement, as shown in Table 1, when the fluctuation range between the first analysis and the 60000th analysis is obtained, it is 5.0%, and the fluctuation range is smaller than that of Comparative Example 4. all right. This is because, in an analyzer using this electrode as a working electrode, the difference in etching rate in the electrode surface is small, so that non-uniform dissolution in the surface is suppressed, and it is exposed to the outermost surface even after repeated analysis. The change in crystal orientation is small, it is possible to suppress fluctuations in the surface state, and it is possible to stably perform liquid replacement of analysis liquid and cleaning liquid, and the electrochemical response fluctuates over a long period of time. There was little effect, and the effect that a stable measurement result was obtained was recognized.
本発明の実施例7について説明する。実施例7では既知濃度の尿酸を分析対象としたこと、母材金属を白金−1%ロジウム合金としたことおよび母材中に分散させる金属酸化物を酸化ジルコニウムとしたことを除き、実施例5の測定方法に準拠して繰り返し分析測定を行った。母材中に分散した金属酸化物の含有量は金属換算で0.15%であった。測定溶液容器8において、検体試料とウリカーゼを作用させることにより過酸化水素を生成した。測定溶液容器8から過酸化水素を含む測定溶液、緩衝液溶液9から緩衝液を溶液導入管13内に導入して混合し、溶液注入機構12により電気化学セル1中に注入し、電気化学測定を行った。繰り返し測定を行った結果、表1に示すように、分析1回目と60000回目との変動幅を求めると、5.3%であり、比較例5に比べて変動幅が小さくなっていることがわかった。これは、本電極を作用極として用いた分析装置においては、電極表面内におけるエッチング速度差が小さいため、面内で不均一な溶解を抑制し、かつ、分析を繰り返しても最表面に露出する結晶の配向性の変化が小さく、表面状態の変動を抑制することが可能になり、また、分析液,洗浄液の液置換を安定して実施することが可能となり、電気化学応答が長期間にわたり変動が少なく、安定した測定結果が得られるという効果が認められた。 A seventh embodiment of the present invention will be described. In Example 7, Example 5 was used except that uric acid at a known concentration was analyzed, the base metal was a platinum-1% rhodium alloy, and the metal oxide dispersed in the base was zirconium oxide. Analytical measurement was repeatedly performed according to the measurement method. The content of the metal oxide dispersed in the base material was 0.15% in terms of metal. In the measurement solution container 8, hydrogen peroxide was generated by allowing the specimen sample and uricase to act. A measurement solution containing hydrogen peroxide from the measurement solution container 8 and a buffer solution from the buffer solution 9 are introduced into the solution introduction tube 13 and mixed, and injected into the electrochemical cell 1 by the solution injection mechanism 12 to perform electrochemical measurement. Went. As a result of repeated measurement, as shown in Table 1, when the fluctuation range between the first analysis and the 60000th analysis is obtained, it is 5.3%, and the fluctuation range is smaller than that of Comparative Example 5. all right. This is because, in an analyzer using this electrode as a working electrode, the difference in etching rate in the electrode surface is small, so that non-uniform dissolution in the surface is suppressed, and it is exposed to the outermost surface even after repeated analysis. The change in crystal orientation is small, it is possible to suppress fluctuations in the surface state, and it is possible to stably perform liquid replacement of analysis liquid and cleaning liquid, and the electrochemical response fluctuates over a long period of time. There was little effect, and the effect that a stable measurement result was obtained was recognized.
本発明の実施例8について説明する。実施例8では既知濃度のクレアチニンを分析対象としたこと、母材中に分散させる金属酸化物を酸化ジルコニウムとしたことを除き、実施例5の測定方法に準拠して繰り返し分析測定を行った。母材中に分散した金属酸化物の含有量は金属換算で0.9%であった。尚、母材中に分散した金属酸化物の含有量が1%を上回る電極を試作したが、電極形状を調整する際加工性が悪化したため、本実施例では1%以下となるように電極を調整した。測定溶液容器8において、検体試料とクレアチニナーゼ,ザルコシンオキシターゼを順次作用させることにより過酸化水素を生成した。測定溶液容器8から過酸化水素を含む測定溶液、緩衝液溶液9から緩衝液を溶液導入管13内に導入して混合し、溶液注入機構12により電気化学セル1中に注入し、電気化学測定を行った。繰り返し測定を行った結果、表1に示すように、分析1回目と60000回目との変動幅を求めると、7.7%であり、比較例6に比べて変動幅が小さくなっていることがわかった。これは、本電極を作用極として用いた分析装置においては、電極表面内におけるエッチング速度差が小さいため、面内で不均一な溶解を抑制し、かつ、分析を繰り返しても最表面に露出する結晶の配向性の変化が小さく、表面状態の変動を抑制することが可能になり、また、分析液,洗浄液の液置換を安定して実施することが可能となり、電気化学応答が長期間にわたり変動が少なく、安定した測定結果が得られるという効果が認められた。 Embodiment 8 of the present invention will be described. In Example 8, repeated analysis measurement was performed according to the measurement method of Example 5 except that a known concentration of creatinine was an analysis target and the metal oxide dispersed in the base material was zirconium oxide. The content of the metal oxide dispersed in the base material was 0.9% in terms of metal. Although an electrode in which the content of the metal oxide dispersed in the base material exceeds 1% was prototyped, the workability deteriorated when adjusting the electrode shape, so in this example the electrode was adjusted to 1% or less. It was adjusted. In the measurement solution container 8, hydrogen peroxide was generated by sequentially causing the specimen sample, creatininase, and sarcosine oxidase to act. A measurement solution containing hydrogen peroxide from the measurement solution container 8 and a buffer solution from the buffer solution 9 are introduced into the solution introduction tube 13 and mixed, and injected into the electrochemical cell 1 by the solution injection mechanism 12 to perform electrochemical measurement. Went. As a result of the repeated measurement, as shown in Table 1, when the fluctuation range between the first analysis and the 60000th analysis is obtained, it is 7.7%, and the fluctuation range is smaller than that of Comparative Example 6. all right. This is because, in an analyzer using this electrode as a working electrode, the difference in etching rate in the electrode surface is small, so that non-uniform dissolution in the surface is suppressed, and it is exposed to the outermost surface even after repeated analysis. The change in crystal orientation is small, it is possible to suppress fluctuations in the surface state, and it is possible to stably perform liquid replacement of analysis liquid and cleaning liquid, and the electrochemical response fluctuates over a long period of time. There was little effect, and the effect that a stable measurement result was obtained was recognized.
本発明の実施例9について説明する。実施例9では母材中に分散した金属酸化物の含有量が金属換算で0.004%であることを除き、実施例8の測定方法に準拠して繰り返し分析測定を行った。繰り返し測定を行った結果、表1に示すように、分析1回目と60000回目との変動幅を求めると、12.3%であり、比較例7に比べてわずかに変動幅が小さくなり効果は見られたものの、大差ないことがわかった。これは、本電極を作用極として用いた分析装置においては、母材中の金属酸化物の含有量が小さすぎ、母材の結晶組織の微細化がさほど進行していなかったこと、結晶配向率が実施例8に比べて小さいことに起因すると考えられる。 A ninth embodiment of the present invention will be described. In Example 9, repeated analysis measurement was performed according to the measurement method of Example 8 except that the content of the metal oxide dispersed in the base material was 0.004% in terms of metal. As a result of the repeated measurement, as shown in Table 1, when the fluctuation range between the first analysis and the 60000th analysis is obtained, it is 12.3%, and the fluctuation range is slightly smaller than that of Comparative Example 7, and the effect is Although it was seen, it turned out that there was not much difference. This is because, in the analyzer using this electrode as a working electrode, the content of the metal oxide in the base material was too small, and the crystal structure of the base material was not refined so much. Is considered to be caused by the fact that it is smaller than that of Example 8.
本発明の実施例10について説明する。実施例10では既知濃度の脂肪酸を分析対象としたことを除き、実施例3の測定方法に準拠して繰り返し分析測定を行った。すなわち、測定溶液容器8において、検体試料とアシルCoAオキシダーゼを作用させることにより過酸化水素を生成した。測定溶液容器8から過酸化水素を含む測定溶液、緩衝液溶器9から緩衝液を溶液導入管13内に導入して混合し、溶液吸引機構15によりフローセル20中に注入し、電気化学測定を行った。繰り返し測定を行った結果、表1に示すように、分析1回目と60000回目との変動幅を求めると、5.1%であり、比較例8に比べて変動幅が小さくなっていることがわかった。これは、本電極を作用極として用いた分析装置においては、電極表面内におけるエッチング速度差が小さいため、面内で不均一な溶解を抑制し、かつ、分析を繰り返しても最表面に露出する結晶の配向性の変化が小さく、表面状態の変動を抑制することが可能になり、また、分析液,洗浄液の液置換を安定して実施することが可能となり、電気化学応答が長期間にわたり変動が少なく、安定した測定結果が得られるという効果が認められた。 A tenth embodiment of the present invention will be described. In Example 10, repeated analysis measurement was performed according to the measurement method of Example 3 except that fatty acids having a known concentration were analyzed. That is, in the measurement solution container 8, hydrogen peroxide was generated by allowing the sample sample and acyl CoA oxidase to act. A measurement solution containing hydrogen peroxide from the measurement solution container 8 and a buffer solution from the buffer solution dissolver 9 are introduced and mixed in the solution introduction tube 13 and injected into the flow cell 20 by the solution suction mechanism 15 to perform electrochemical measurement. went. As a result of repeated measurement, as shown in Table 1, when the fluctuation range between the first analysis and the 60000th analysis is obtained, it is 5.1%, and the fluctuation range is smaller than that of Comparative Example 8. all right. This is because, in an analyzer using this electrode as a working electrode, the difference in etching rate in the electrode surface is small, so that non-uniform dissolution in the surface is suppressed, and it is exposed to the outermost surface even after repeated analysis. The change in crystal orientation is small, it is possible to suppress fluctuations in the surface state, and it is possible to stably perform liquid replacement of analysis liquid and cleaning liquid, and the electrochemical response fluctuates over a long period of time. There was little effect, and the effect that a stable measurement result was obtained was recognized.
本発明の実施例11について説明する。実施例11では既知濃度のビリルビンを分析対象としたことを除き、実施例3の測定方法に準拠して繰り返し分析測定を行った。すなわち、測定溶液容器8において、検体試料とフェリシアン化カリウム存在下でビリルビンオキシダーゼを作用させることによりフェロシアン化カリウムを生成した。測定溶液容器8からフェロシアン化カリウムを含む測定溶液、緩衝液溶液9から緩衝液を溶液導入管13内に導入して混合し、溶液吸引機構15によりフローセル20中に注入し、電気化学測定を行った。繰り返し測定を行った結果、表1に示すように、分析1回目と60000回目との変動幅を求めると、5.3%であり、比較例9に比べて変動幅が小さくなっていることがわかった。これは、本電極を作用極として用いた分析装置においては、電極表面内におけるエッチング速度差が小さいため、面内で不均一な溶解を抑制し、かつ、分析を繰り返しても最表面に露出する結晶の配向性の変化が小さく、表面状態の変動を抑制することが可能になり、また、分析液,洗浄液の液置換を安定して実施することが可能となり、電気化学応答が長期間にわたり変動が少なく、安定した測定結果が得られるという効果が認められた。 Example 11 of the present invention will be described. In Example 11, repeated analysis measurement was performed according to the measurement method of Example 3 except that bilirubin having a known concentration was used as an analysis target. That is, potassium ferrocyanide was produced in the measurement solution container 8 by allowing bilirubin oxidase to act in the presence of the specimen sample and potassium ferricyanide. A measurement solution containing potassium ferrocyanide from the measurement solution container 8 and a buffer solution from the buffer solution 9 were introduced and mixed in the solution introduction tube 13 and injected into the flow cell 20 by the solution suction mechanism 15 to perform electrochemical measurement. . As a result of repeated measurement, as shown in Table 1, when the fluctuation range between the first analysis and the 60000th analysis is obtained, it is 5.3%, and the fluctuation range is smaller than that of Comparative Example 9. all right. This is because, in an analyzer using this electrode as a working electrode, the difference in etching rate in the electrode surface is small, so that non-uniform dissolution in the surface is suppressed, and it is exposed to the outermost surface even after repeated analysis. The change in crystal orientation is small, it is possible to suppress fluctuations in the surface state, and it is possible to stably perform liquid replacement of analysis liquid and cleaning liquid, and the electrochemical response fluctuates over a long period of time. There was little effect, and the effect that a stable measurement result was obtained was recognized.
実施例12は、金属基体をチタンとし、その表面に白金めっきを施し、酸化ジルコニウムを塗布,焼成した膜を形成した電極を作製した。以下に詳細な作製方法を説明する。10mm×10mm,板厚0.5mmのチタンを脱脂洗浄した後、5%フッ酸水溶液で2分間処理
した。水洗後、ジニトロジアミノ白金含有硫酸水溶液中で15mA/cm2で1分間めっきを行った。次に、大気中400℃で1時間加熱処理した。次に、塩化白金酸(白金金属換算で10g/L)のブタノール溶液と塩化ジルコニウム(ジルコニウム金属換算で1g/Lのエタノール溶液を等量混合し、塗布液を調製した後、この塗布液を用いて1cm2あたり3μL秤量し、それを白金めっきを施したチタン基体に塗布した。その後、室温で30分間真空乾燥させ、さらに大気中500℃で10分間焼成した。この工程を50回繰り返すことにより、酸化ジルコニウム分散型白金電極を得た。この電極の金属酸化物含有率は9.7%であった。また、電極表面をX線回折測定した結果、優先配向率は47%であった。前記電極を作用極として用いて、実施例1と同様に図1の電気化学的分析装置を用いて、測定溶液として、血清中のTSHを免疫学的に分析し、洗浄液として、例えば水酸化カリウム水溶液を各測定の終了毎に電気化学セルに導入する方法で測定を行った。測定した結果、表1に示すように、分析1回目と60000回目との変動幅を求めると、8.7%であった。
In Example 12, an electrode was produced in which a metal substrate was made of titanium, the surface thereof was subjected to platinum plating, and zirconium oxide was applied and baked to form a film. A detailed manufacturing method will be described below. After degreasing and cleaning titanium having a thickness of 10 mm × 10 mm and a thickness of 0.5 mm, it was treated with a 5% aqueous hydrofluoric acid solution for 2 minutes. After washing with water, plating was performed at 15 mA / cm 2 for 1 minute in a dinitrodiaminoplatinum-containing sulfuric acid aqueous solution. Next, it heat-processed in air | atmosphere at 400 degreeC for 1 hour. Next, a butanol solution of chloroplatinic acid (10 g / L in terms of platinum metal) and zirconium chloride (1 g / L ethanol solution in terms of zirconium metal) are mixed in equal amounts to prepare a coating solution, and then this coating solution is used. Weighed 3 μL per cm 2 and applied it to a platinum-plated titanium substrate, followed by vacuum drying at room temperature for 30 minutes and further firing in the atmosphere at 500 ° C. for 10 minutes. As a result of X-ray diffraction measurement of the electrode surface, the preferred orientation ratio was 47%. Using the electrode as a working electrode, the electrochemical analyzer of FIG. 1 as in Example 1 was used to immunologically analyze TSH in serum as a measurement solution, and as a washing solution, for example, hydroxide hydroxide. The measurement was performed by introducing an aqueous solution of lithium into the electrochemical cell at the end of each measurement, and as a result of the measurement, as shown in Table 1, when the fluctuation range between the first analysis and the 60000th analysis was obtained, 8.7 %Met.
実施例13は、酸化ジルコニウムの代わりに酸化ニオブとしたことを除き、実施例12と同様に繰り返し分析測定を行った。測定した結果、表1に示すように、分析1回目と60000回目との変動幅を求めると、9.4%であった。 In Example 13, repeated analysis measurement was performed in the same manner as in Example 12 except that niobium oxide was used instead of zirconium oxide. As a result of the measurement, as shown in Table 1, the fluctuation range between the first analysis and the 60,000th analysis was 9.4%.
実施例14は、酸化ジルコニウムの代わりに酸化タンタルとしたことを除き、実施例12と同様に繰り返し分析測定を行った。測定した結果、表1に示すように、分析1回目と60000回目との変動幅を求めると、9.2%であった。 In Example 14, analytical measurement was repeatedly performed in the same manner as in Example 12 except that tantalum oxide was used instead of zirconium oxide. As a result of the measurement, as shown in Table 1, the fluctuation range between the first analysis and the 60,000th analysis was 9.2%.
実施例12から14の電極を用いた場合、比較例1と比較して変動幅の低減に効果があったものの、その効果は実施例1に比べて小さいものであった。これは、実施例12から14の電極は、塗布,焼成により作製した電極であり、母材中に含まれる金属酸化物の濃度が実施例1に比べて大きいこと、および結晶配向率が小さいことに起因していることが考えられる。つまり、分析繰り返し、すなわち表面エッチングの進行に伴い、電極表面内におけるエッチング速度差が大きく、特定の面が優先的に溶解していくことにより、電極面内において局所的に大きい段差が発生したことに起因すると考える。加えて、塗布,焼成により作製した酸化ジルコニウム分散型白金電極のため、実施例1の圧延電極に比べて膜強度が低く、表面エッチングに伴い電極材が脱落する現象も認められた。さらに、金属酸化物濃度が大きいため、電気化学反応に影響を及ぼしたことも考え得る。結果的に、電極表面状態の変動が大きくなること、分析液,洗浄液の液置換が安定に実施できなくなり、長期間で見た場合において電気化学応答の変動が大きくなったと考えられる。 When the electrodes of Examples 12 to 14 were used, there was an effect in reducing the fluctuation range as compared with Comparative Example 1, but the effect was smaller than in Example 1. This is because the electrodes of Examples 12 to 14 are electrodes prepared by coating and baking, and the concentration of the metal oxide contained in the base material is higher than that of Example 1 and the crystal orientation ratio is small. It may be caused by In other words, with repeated analysis, that is, with the progress of surface etching, the difference in etching rate in the electrode surface is large, and a specific step preferentially dissolves, resulting in a locally large step in the electrode surface. I think that is due to. In addition, since the zirconium oxide-dispersed platinum electrode was produced by coating and firing, the film strength was lower than that of the rolled electrode of Example 1, and the phenomenon that the electrode material dropped off during surface etching was also observed. Furthermore, since the metal oxide concentration is large, it may be considered that the electrochemical reaction was affected. As a result, it is considered that the fluctuation of the electrode surface state becomes large, the liquid replacement of the analysis liquid and the cleaning liquid cannot be performed stably, and the fluctuation of the electrochemical response becomes large when viewed over a long period of time.
〔比較例1〕
比較例の電極4は、白金を圧延により板状にした電極である。1時間800度に加熱するとともに、板厚が0.1mmとなるように、100MPaで熱間圧延加工した。冷却後、実施例1と同様に、フッ素系樹脂に埋め込み、白金表面を耐水研磨紙,ダイヤモンドペースト,アルミナを用いて順次機械研磨し、引き続き電解研磨を施し、作用極とした。
[Comparative Example 1]
The electrode 4 of the comparative example is an electrode obtained by rolling platinum into a plate shape. While heating at 800 ° C. for 1 hour, hot rolling was performed at 100 MPa so that the plate thickness was 0.1 mm. After cooling, as in Example 1, it was embedded in a fluororesin, and the platinum surface was sequentially mechanically polished using water-resistant abrasive paper, diamond paste, and alumina, followed by electrolytic polishing to obtain a working electrode.
この作用極を用いて、実施例1と同様に図1の電気化学的分析装置に用いて、測定溶液として、血清中のTSHを免疫学的に分析し、洗浄液として、例えば水酸化カリウム水溶液を各測定の終了毎に電解セルに導入する方法で測定を行った。 Using this working electrode, as in Example 1, it was used in the electrochemical analyzer of FIG. 1 to immunologically analyze TSH in serum as a measurement solution, and for example, a potassium hydroxide aqueous solution as a washing solution. The measurement was carried out by introducing it into the electrolytic cell at the end of each measurement.
その結果、図6に示すように、比較例の電極を用いた場合の変動幅は10.3%であった。比較例の電極をX線回折で解析したところ、図5に示すように、(220)および(111)に優先配向していることがわかったが、最大強度を示した(220)方位の配向率は54%であった。また、比較例1の電極の板厚方向断面の結晶組織を観察したところ、粒径の大きい粗大結晶組織を有することがわかった。このような電極を用いた場合、分析繰り返し、すなわち表面エッチングの進行に伴い、電極表面内におけるエッチング速度差が大きく、特定の面が優先的に溶解していくことにより、電極面内において局所的に大きい段差が発生したことに起因すると考える。また、最表面に露出する各結晶方位の配向率が分析繰り返しに伴って変動する。結果的に、表面状態の変動が大きくなること、分析液,洗浄液の液置換が安定に実施できなくなり、長期間で見た場合において電気化学応答の変動が大きくなったと考えられる。 As a result, as shown in FIG. 6, the fluctuation range when the electrode of the comparative example was used was 10.3%. When the electrode of the comparative example was analyzed by X-ray diffraction, it was found that (220) and (111) were preferentially oriented as shown in FIG. The rate was 54%. Moreover, when the crystal structure of the cross section in the plate thickness direction of the electrode of Comparative Example 1 was observed, it was found that it had a coarse crystal structure with a large particle size. When such an electrode is used, repeated analysis, that is, with the progress of surface etching, there is a large difference in the etching rate within the electrode surface, and a specific surface is preferentially dissolved, so that local in the electrode surface. This is considered to be due to the occurrence of a large step in the area. In addition, the orientation rate of each crystal orientation exposed on the outermost surface varies with repeated analysis. As a result, it is considered that the fluctuation of the surface state becomes large, the liquid replacement of the analysis liquid and the cleaning liquid cannot be performed stably, and the fluctuation of the electrochemical response becomes large when viewed over a long period of time.
〔比較例2〕
比較例2は、比較例1の白金電極を作用極として用い、実施例4と同様にグルコースを分析対象として繰り返し測定を行った。測定した結果、表1に示すように、分析1回目と60000回目との変動幅を求めると、4.2%であった。
[Comparative Example 2]
In Comparative Example 2, the platinum electrode of Comparative Example 1 was used as a working electrode, and glucose was repeatedly measured in the same manner as in Example 4 using glucose as an analysis target. As a result of the measurement, as shown in Table 1, the fluctuation range between the first analysis and the 60000th analysis was 4.2%.
〔比較例3〕
比較例3は、比較例1の白金電極を作用極として用い、実施例5と同様に尿素を分析対象として繰り返し測定を行った。測定した結果、表1に示すように、分析1回目と60000回目との変動幅を求めると、3.7%であった。
[Comparative Example 3]
In Comparative Example 3, the platinum electrode of Comparative Example 1 was used as a working electrode, and urea was analyzed repeatedly as in Example 5 in the same manner as in Example 5. As a result of the measurement, as shown in Table 1, the fluctuation range between the first analysis and the 60,000th analysis was 3.7%.
〔比較例4〕
比較例4は、比較例1の白金電極を作用極として用い、実施例6と同様にコレステロールを分析対象として繰り返し測定を行った。測定した結果、表1に示すように、分析1回目と60000回目との変動幅を求めると、7.3%であった。
[Comparative Example 4]
In Comparative Example 4, the platinum electrode of Comparative Example 1 was used as a working electrode, and the measurement was repeated using cholesterol as an analysis target in the same manner as in Example 6. As a result of the measurement, as shown in Table 1, the fluctuation range between the first analysis and the 60000th analysis was 7.3%.
〔比較例5〕
比較例5は、比較例1の白金電極を作用極として用い、実施例7と同様に尿酸を分析対象として繰り返し測定を行った。測定した結果、表1に示すように、分析1回目と60000回目との変動幅を求めると、8.8%であった。
[Comparative Example 5]
In Comparative Example 5, the platinum electrode of Comparative Example 1 was used as a working electrode, and measurement was repeated using uric acid as an analysis target in the same manner as in Example 7. As a result of the measurement, as shown in Table 1, the fluctuation width between the first analysis and the 60,000th analysis was 8.8%.
〔比較例6〕
比較例6は、比較例1の白金電極を作用極として用い、実施例8と同様にクレアチニンを分析対象として繰り返し測定を行った。測定した結果、表1に示すように、分析1回目と60000回目との変動幅を求めると、11.2%であった。
[Comparative Example 6]
In Comparative Example 6, the platinum electrode of Comparative Example 1 was used as a working electrode, and measurement was repeated using creatinine as an analysis target in the same manner as in Example 8. As a result of the measurement, as shown in Table 1, the fluctuation range between the first analysis and the 60000th analysis was found to be 11.2%.
〔比較例7〕
比較例7は、比較例1の白金電極を作用極として用い、実施例9と同様にクレアチニンを分析対象として繰り返し測定を行った。測定した結果、表1に示すように、分析1回目と60000万回との変動幅を求めると、12.6%であった。
[Comparative Example 7]
In Comparative Example 7, the platinum electrode of Comparative Example 1 was used as a working electrode, and measurement was repeated using creatinine as an analysis target in the same manner as in Example 9. As a result of the measurement, as shown in Table 1, when the fluctuation range between the first analysis and 600,000,000 times was obtained, it was 12.6%.
〔比較例8〕
比較例8は、比較例1の白金電極を作用極として用い、実施例10と同様に脂肪酸を分析対象として繰り返し測定を行った。測定した結果、表1に示すように、分析1回目と60000回目との変動幅を求めると、7.2%であった。
[Comparative Example 8]
In Comparative Example 8, the platinum electrode of Comparative Example 1 was used as a working electrode, and the measurement was repeated using fatty acid as an analysis target in the same manner as in Example 10. As a result of the measurement, as shown in Table 1, the fluctuation range between the first analysis and the 60,000th analysis was 7.2%.
〔比較例9〕
比較例9は、比較例1の白金電極を作用極として用い、実施例11と同様にビリルビンを分析対象として繰り返し測定を行った。測定した結果、表1に示すように、分析1回目と60000回目との変動幅を求めると、6.6%であった。
[Comparative Example 9]
In Comparative Example 9, the platinum electrode of Comparative Example 1 was used as a working electrode, and the measurement was repeated using bilirubin as an analysis target in the same manner as in Example 11. As a result of the measurement, as shown in Table 1, the fluctuation range between the first analysis and the 60,000th analysis was 6.6%.
比較例2から9の白金電極を用いた場合、分析繰り返し、すなわち表面エッチングの進行に伴い、電極表面内におけるエッチング速度差が大きく、特定の面が優先的に溶解していくことにより、電極面内において局所的に大きい段差が発生したことに起因すると考える。結果的に、表面状態の変動が大きくなること、分析液,洗浄液の液置換が安定に実施できなくなり、長期間で見た場合において電気化学応答の変動が大きくなったと考えられる。 When the platinum electrodes of Comparative Examples 2 to 9 are used, the analysis surface repeats, that is, with the progress of the surface etching, the etching rate difference in the electrode surface is large, and the specific surface is preferentially dissolved. This is considered to be due to the occurrence of a large step in the area. As a result, it is considered that the fluctuation of the surface state becomes large, the liquid replacement of the analysis liquid and the cleaning liquid cannot be performed stably, and the fluctuation of the electrochemical response becomes large when viewed over a long period of time.
尚、上述した本発明の実施例は、本発明の電極を電気化学的分析装置の作用極に適用した場合の例であるが、作用極のみならず、対極にも本発明を適用することができる。対極にも本発明を適用すれば、さらに分析データの高精度化を図ることができる。 In addition, although the Example of this invention mentioned above is an example at the time of applying the electrode of this invention to the working electrode of an electrochemical analyzer, it can apply this invention not only to a working electrode but to a counter electrode. it can. If the present invention is also applied to the counter electrode, the analysis data can be made more accurate.
1 電気化学セル
2,34,74,104,134,194 作用極
3,35,75,105,135,195 対極
4 参照極
5 電位印加手段
6 測定手段
7,39,40,79,80,109,110,139,140,199,200,302 電気配線
8 測定溶液容器
9 緩衝液容器
10 洗浄液容器
11 溶液分注機構
12 溶液注入機構
13 溶液導入管
14 溶液排出管
15 溶液排出(吸引)機構
16 廃液容器
20,60,90,120,180 フローセル
30,32,70,72,100,102,130,132,190,192 絶縁性基板
31,71,101,131 シール部材
33,73,103,133,193 ねじ穴
36,76,106,136,196 開口部
37,38,77,78,107,108,137,138,197,198 配管
37a,77a,107a,137a 溶液注入口
38a,78a,108a,138a 溶液排出口
50 電極製造装置
50a 電極化部
50b 樹脂包埋部
50c 機械研磨部
50d 電解研磨部
50e セル組立部
141 通電用ボルト
142 通電用プレート
143 ネジ溝
191 Oリング
300 絶縁性樹脂
301 複合材料
303 接着剤
304 シャフト
1 Electrochemical cell 2, 34, 74, 104, 134, 194 Working electrode 3, 35, 75, 105, 135, 195 Counter electrode 4 Reference electrode 5 Potential applying means 6 Measuring means 7, 39, 40, 79, 80, 109 , 110, 139, 140, 199, 200, 302 Electrical wiring 8 Measurement solution container 9 Buffer solution container 10 Washing solution container 11 Solution dispensing mechanism 12 Solution injection mechanism 13 Solution introduction tube 14 Solution discharge tube 15 Solution discharge (suction) mechanism 16 Waste liquid containers 20, 60, 90, 120, 180 Flow cells 30, 32, 70, 72, 100, 102, 130, 132, 190, 192 Insulating substrates 31, 71, 101, 131 Seal members 33, 73, 103, 133 , 193 Screw holes 36, 76, 106, 136, 196 Openings 37, 38, 77, 78, 107, 108, 137, 138, 97, 198 Piping 37a, 77a, 107a, 137a Solution inlet 38a, 78a, 108a, 138a Solution outlet 50 Electrode manufacturing apparatus 50a Electrode forming part 50b Resin embedding part 50c Mechanical polishing part 50d Electropolishing part 50e Cell assembly part 141 Energizing bolt 142 Energizing plate 143 Screw groove 191 O-ring 300 Insulating resin 301 Composite material 303 Adhesive 304 Shaft
Claims (13)
白金または白金合金を母材として前記母材中に、ジルコニウム,タンタル,ニオブからなる群より選ばれる金属の酸化物が分散して含有される複合材料を用いることを特徴とする電気化学測定用電極。 In an electrode for electrochemical measurement used in an electrochemical analyzer for measuring an electrochemical response of a chemical component contained in a liquid sample,
Electrode for electrochemical measurement, characterized by using a composite material containing platinum or a platinum alloy as a base material in which a metal oxide selected from the group consisting of zirconium, tantalum and niobium is dispersed. .
前記金属酸化物の含有比率が0.005〜1重量%であることを特徴とする電気化学測定用電極。 The electrode for electrochemical measurement according to claim 1,
An electrode for electrochemical measurement, wherein the content ratio of the metal oxide is 0.005 to 1% by weight.
前記電極表面のX線回折測定より得られる結晶方位の配向率(%)を、I(hkl)/ΣI(hkl)×100(但し、I(hkl)は各面の回折強度積分値であり、
ΣI(hkl)は(hkl)の回折強度積分値の総和)とすると、
得られる複数の結晶方位の内の一つの結晶方位の配向率が80%以上であることを特徴とする電気化学測定用電極。 The electrode for electrochemical measurements according to claim 2,
The orientation ratio (%) of crystal orientation obtained from the X-ray diffraction measurement of the electrode surface is I (hkl) / ΣI (hkl) × 100 (where I (hkl) is the integrated value of diffraction intensity of each surface,
ΣI (hkl) is the sum of the integrated values of diffraction intensity of (hkl))
An electrode for electrochemical measurement, wherein an orientation ratio of one crystal orientation out of a plurality of crystal orientations obtained is 80% or more.
電極表面の一部を除き、電極材料を絶縁樹脂に包埋してなることを特徴とする電気化学測定用電極。 In the electrode for electrochemical measurements according to any one of claims 1 to 3,
An electrode for electrochemical measurement, wherein an electrode material is embedded in an insulating resin except for a part of the electrode surface.
作用極,対極,参照極が内部に配置される電気化学セルであって、
前記作用極が請求項1〜4のいずれかに記載の電極であることを特徴とする電気化学セル。 In an electrochemical cell that measures the electrochemical response of chemical components contained in a liquid sample,
An electrochemical cell in which a working electrode, a counter electrode, and a reference electrode are disposed,
The said working electrode is an electrode in any one of Claims 1-4, The electrochemical cell characterized by the above-mentioned.
液体試料を前記セル内部へ注入する注入口およびセル外部へ排出する排出口をセルに配置したフローセルであることを特徴とする電気化学セル。 The electrochemical cell according to claim 5, wherein
An electrochemical cell, characterized by being a flow cell in which an inlet for injecting a liquid sample into the cell and an outlet for discharging it out of the cell are arranged in the cell.
作用極,対極,参照極が内部に配置される電気化学セルと、
前記電気化学セル内へ測定溶液,緩衝溶液および洗浄溶液を注入する溶液注入手段と、
前記作用極,対極,参照極に電位を印加する電位印加手段と、
前記作用極,対極,参照極に接続され、前記測定溶液の電気化学的特性を測定する測定手段とを備え、
前記作用極が請求項1〜4のいずれかに記載の電極であることを特徴とする電気化学的分析装置。 In electrochemical analyzers,
An electrochemical cell in which a working electrode, a counter electrode, and a reference electrode are disposed;
Solution injection means for injecting a measurement solution, a buffer solution and a washing solution into the electrochemical cell;
A potential applying means for applying a potential to the working electrode, the counter electrode, and the reference electrode;
A measuring means connected to the working electrode, the counter electrode, and the reference electrode and measuring the electrochemical properties of the measuring solution;
The electrochemical analysis apparatus, wherein the working electrode is an electrode according to any one of claims 1 to 4.
(a)白金または白金合金を母材として前記母材中に、ジルコニウム,タンタル,ニオブからなる群より選ばれる金属の酸化物が分散して含有される複合材料を用いて電極化する工程、
(b)前記電極表面の一部を除いて電極を絶縁樹脂中に包埋する工程、
(c)前記樹脂に包埋された電極の表面を機械研磨する工程、
(d)前記電極表面を電解研磨し、表面変質層を除去する工程
からなることを特徴とする電気化学測定用電極の製造方法。 In a method for producing an electrode for electrochemical measurement used in an electrochemical analyzer for measuring an electrochemical response of a chemical component contained in a liquid sample,
(A) using platinum or a platinum alloy as a base material to form an electrode using a composite material in which a metal oxide selected from the group consisting of zirconium, tantalum, and niobium is dispersed and contained in the base material;
(B) a step of embedding the electrode in an insulating resin except for a part of the electrode surface;
(C) mechanically polishing the surface of the electrode embedded in the resin;
(D) A method for producing an electrode for electrochemical measurement, comprising a step of electropolishing the surface of the electrode and removing a surface alteration layer.
前記電解研磨は、電解液中で電位を水素発生領域から酸素発生領域の電位間で複数回繰り返し印加する工程であることを特徴とする電気化学測定用電極の製造方法。 In the manufacturing method of the electrode for electrochemical measurements according to claim 8,
The method of manufacturing an electrode for electrochemical measurement, wherein the electropolishing is a step of repeatedly applying a potential multiple times between a hydrogen generation region and an oxygen generation region in an electrolytic solution.
表面変質層を除去した後、サイクリックボルタンメトリにより得られる複数の水素吸脱着ピークのうち少なくとも2つのピークの面積比から電極表面状態を診断し、
所定ピーク比となるまで電解研磨を繰り返すことを特徴とする電気化学測定用電極の製造方法。 In the manufacturing method of the electrode for electrochemical measurements according to claim 8 or 9,
After removing the surface alteration layer, the electrode surface state is diagnosed from the area ratio of at least two of the plurality of hydrogen adsorption / desorption peaks obtained by cyclic voltammetry,
A method for producing an electrode for electrochemical measurement, characterized by repeating electropolishing until a predetermined peak ratio is obtained.
(a)白金または白金合金を母材として前記母材中に、ジルコニウム,タンタル,ニオブからなる群より選ばれる金属の酸化物が分散して含有される複合材料を用いて電極化する工程、
(b)予め溶液注入口および排出口を形成した絶縁性基板に、前記電極を接着剤により埋め込む工程
(c)前記絶縁性基板に包埋された電極の表面を機械研磨する工程、
(d)前記電極表面を電解研磨し、表面変質層を除去する工程、
(e)前記研磨を施した電極が包埋した絶縁性基板、開口部を有するシール部材、別の絶縁性基板を積層一体化し、対極,参照極を付設する工程からなることを特徴とする電気化学セルの製造方法。 In a method for producing an electrochemical cell used in an electrochemical analyzer for measuring an electrochemical response of a chemical component contained in a liquid sample,
(A) using platinum or a platinum alloy as a base material to form an electrode using a composite material in which a metal oxide selected from the group consisting of zirconium, tantalum, and niobium is dispersed and contained in the base material;
(B) a step of embedding the electrode with an adhesive in an insulating substrate in which a solution injection port and a discharge port are formed in advance; (c) a step of mechanically polishing the surface of the electrode embedded in the insulating substrate;
(D) a step of electropolishing the surface of the electrode to remove the surface-modified layer;
(E) An electric substrate comprising: an insulating substrate in which the polished electrode is embedded; a sealing member having an opening; and another insulating substrate are laminated and integrated, and a counter electrode and a reference electrode are provided. Chemical cell manufacturing method.
いる電気化学測定用電極の製造装置において、
(a)白金または白金合金を母材として前記母材中に、ジルコニウム,タンタル,ニオブからなる群より選ばれる金属の酸化物が分散して含有される複合材料を用いる電極化部、
(b)前記電極表面の一部を除いて電極を絶縁樹脂中に包埋する樹脂包埋部、
(c)前記樹脂に包埋された電極の表面を機械研磨する機械研磨部、
(d)前記電極表面を電解研磨し、表面変質層を除去する電解研磨部
を備えることを特徴とする電気化学測定用電極の製造装置。 In an apparatus for manufacturing an electrode for electrochemical measurement used in an electrochemical analyzer for measuring an electrochemical response of a chemical component contained in a liquid sample,
(A) an electrode forming section using a composite material in which a metal oxide selected from the group consisting of zirconium, tantalum and niobium is dispersed and contained in the base material using platinum or a platinum alloy as a base material;
(B) a resin embedding part for embedding the electrode in an insulating resin except for a part of the electrode surface;
(C) a mechanical polishing unit that mechanically polishes the surface of the electrode embedded in the resin;
(D) An apparatus for producing an electrode for electrochemical measurement, comprising an electropolishing unit for electrolytically polishing the surface of the electrode and removing a surface alteration layer.
(a)白金または白金合金を母材として前記母材中に、ジルコニウム,タンタル,ニオブからなる群より選ばれる金属の酸化物が分散して含有される複合材料を用いる電極化部、
(b)予め溶液注入口および排出口を形成した絶縁性基板に、前記電極を接着剤により埋め込む樹脂包埋部、
(c)前記絶縁性基板に包埋された電極の表面を機械研磨する機械研磨部、
(d)前記電極表面を電解研磨し、表面変質層を除去する電解研磨部、
(e)前記研磨を施した電極が包埋した絶縁性基板、開口部を有するシール部材、別の絶縁性基板を積層一体化し、対極,参照極を付設するセル組立部からなることを特徴とする電気化学セルの製造装置。 In an electrochemical cell manufacturing apparatus used in an electrochemical analyzer for measuring an electrochemical response of a chemical component contained in a liquid sample,
(A) an electrode forming section using a composite material in which a metal oxide selected from the group consisting of zirconium, tantalum and niobium is dispersed and contained in the base material using platinum or a platinum alloy as a base material;
(B) a resin embedding part for embedding the electrode with an adhesive in an insulating substrate in which a solution injection port and a discharge port are formed in advance;
(C) a mechanical polishing unit that mechanically polishes the surface of the electrode embedded in the insulating substrate;
(D) electropolishing the electrode surface to remove the surface alteration layer,
(E) An insulating substrate in which the polished electrode is embedded, a sealing member having an opening, and a cell assembly unit in which another insulating substrate is laminated and integrated, and a counter electrode and a reference electrode are provided. Electrochemical cell manufacturing equipment.
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