JP4700214B2 - Oxygen sensor element and manufacturing method thereof - Google Patents

Description

表１より、スピネルの組成に関して、マグネシアの比率が２８．３重量％以上の試料No.１，２では、応答時間が遅く、耐久試験による応答時間の劣化率も悪いことがわかる。
出発原料である溶射用の粉末に関しては、被毒防止の観点から大きさが約１０〜１００μmの造粒粒子で作製したセラミック保護層が、また溶射装置のアーク電流に関しては、５５０A以下で生成したセラミック保護層が優れていた。
以上の結果から、本発明のセラミック保護層は被毒に対して電極を保護する効果が著しく優れたものであることが容易に理解できる。
【００５０】
【発明の効果】
本発明によれば、測定電極の表面にマグネシア・アルミナ・スピネルからなる多孔質のセラミック保護層を形成するとともに、前記マグネシア・アルミナ・スピネルの組成を理論組成比よりアルミナリッチとすることにより、排気ガスからの被毒を確実に防止して、長時間にわたり安定した電極性能を維持できるというという効果がある。
【図面の簡単な説明】
【図１】本発明の一実施形態にかかるコップ型酸素センサ素子を示す断面図である。
【図２】 (ａ)は本発明の他の実施形態であるヒータ一体化酸素センサ素子を示す概略斜視図であり、（ｂ）はそのＡ−Ａ線断面図である。
【図３】図２に示すヒータ一体化酸素センサ素子の製造方法を示す説明図である。
【図４】 (ａ)は本発明にかかるヒータ一体化酸素センサ素子の他の例を示す断面図、（ｂ）はそのＸ −Ｘ線断面図である。
【符号の説明】
１…ヒータ一体化酸素センサ素子、２…円筒管、３…基準電極、４…測定電極、６…セラミック絶縁層、７…開口部、８…発熱抵抗体、１３…セラミック保護層、３４…セラミック保護層、３９…セラミック保護層[0001]
BACKGROUND OF THE INVENTION
The present invention relates to an oxygen sensor and a manufacturing method thereof, and more particularly to an oxygen sensor element for controlling a ratio of air and fuel in an internal combustion engine such as an automobile and a manufacturing method thereof.
[0002]
[Prior art]
Conventionally, for example, an oxygen sensor used as a gas sensor for an automobile uses an oxygen sensor in which a pair of reference electrodes made of platinum and a measurement electrode are provided on the inner and outer surfaces of a bottomed cylindrical ceramic tube having oxygen ion conductivity such as zirconia. It has been. In such an oxygen sensor element, it is necessary to heat the detection unit to an operating temperature of about 700 ° C. Therefore, a rod heater is provided inside the ceramic cylindrical tube to heat the detection unit to the operating temperature. Has been inserted.
[0003]
Since the outer electrode of the oxygen sensor element is exposed to high-temperature exhaust gas, the oxygen sensor element is subjected to poisoning in which the catalytic ability of the electrode is reduced due to, for example, P or S in the exhaust gas. To protect against such problems, a porous heat-resistant ceramic protective layer such as spinel is formed on the surface of the outer electrode by a method such as thermal spraying to extend the life of the oxygen sensor. .
[0004]
[Problems to be solved by the invention]
However, in recent years, the tendency to tighten exhaust gas regulations has increased, and there is an increasing demand for oxygen sensor elements that have a small gas sensor performance deterioration and that have high sensitivity to exhaust gas.
The present invention has been made to solve such a problem. An oxygen sensor element capable of reliably preventing poisoning from exhaust gas and maintaining stable electrode performance over a long period of time, and a method for manufacturing the oxygen sensor element are provided. The purpose is to provide.
[0005]
[Means for Solving the Problems]
As a result of intensive research to solve the above problems, the present inventors have provided a reference electrode and a measurement electrode on the inner and outer surfaces of a ceramic having oxygen ion conductivity, such as zirconia, and further, magnesia on the surface of the measurement electrode.・ By forming a porous ceramic protective layer made of alumina and spinel, and making the composition of the magnesia, alumina, and spinel richer in alumina than the theoretical composition ratio, it is possible to reliably prevent poisoning from the exhaust gas, The present inventors have found a new fact that stable electrode performance can be maintained for a long time, and have completed the present invention.
That is, the oxygen sensor element of the present invention is formed by forming a measurement electrode and a reference electrode at positions facing at least the inner and outer surfaces of a zirconia solid electrolyte substrate, and the surface of the measurement electrode is made of magnesia, alumina, and spinel. A porous ceramic protective layer is formed, and the composition of the magnesia / alumina / spinel is richer in alumina than the theoretical composition ratio.
[0006]
Originally, the theoretical composition of magnesia / alumina / spinel is 28.3% by weight of magnesia and 71.7% by weight of alumina, but in the present invention, the composition of magnesia / alumina / spinel, which is the ceramic protective layer of the electrode, is the theoretical composition ratio. By making it more alumina-rich, it is possible to lower the melting temperature of the ceramic powder when forming the ceramic protective layer by thermal spraying, as described below, and as a result, the damage of thermal spraying to the electrode, for example, electrode peeling and adhesion force , And microcracks on the surface of the solid electrolyte can be reduced.
[0007]
Further, another oxygen sensor element of the present invention is formed by forming a measurement electrode and a reference electrode at opposite positions on the inner and outer surfaces of a zirconia solid electrolyte substrate, and the surface of the measurement electrode is magnesia-alumina. A porous ceramic protective layer made of a composite oxide of spinel and magnesia is formed, and the composition of the magnesia / alumina / spinel is richer in alumina than the theoretical composition ratio.
By forming a porous ceramic protective layer composed of a composite oxide of magnesia, alumina, spinel and magnesia, the composition of the magnesia / alumina / spinel is richer than the theoretical composition ratio, and the ceramic protective layer, the measuring electrode, and The difference in thermal expansion coefficient with the zirconia solid electrolyte can be reduced, and as a result, the adhesion of the ceramic protective layer is improved. As a result, it is possible to prevent the ceramic protective layer from peeling or cracking due to the temperature cycle.
[0008]
In the present invention, as the magnesia / alumina / spinel composition, the ratio of magnesia / alumina is preferably 28-20% by weight of magnesia and 72-80% by weight of alumina. When the ratio of magnesia exceeds 28% by weight (when the ratio of alumina is less than 72% by weight), the melting temperature of the powder becomes high during spraying, and the damage to the electrode increases. On the other hand, when the proportion of magnesia is less than 20% by weight (when the proportion of alumina exceeds 80% by weight), the ceramic protective layer tends to become dense and gas responsiveness tends to be poor. As the ratio of magnesia and alumina, the ranges of 25 to 22% by weight of magnesia and 75 to 78% by weight of alumina are particularly excellent. At this time, the degree of supersaturation of alumina in the spinel can be easily obtained from the dependency of the lattice constant of the spinel crystal on the solid solution amount of alumina.
[0009]
In the present invention, it is desirable to use a granulated powder of magnesia / alumina / spinel having an average diameter of 10 to 100 μm as a material for forming the ceramic protective layer. By using a granulated powder of magnesia, alumina, and spinel with an average diameter of 10 to 100 μm, it is possible to reduce the magnitude of the arc current and at the same time lower the melting temperature, resulting in damage to the electrode. Can be reduced. When the size of the granulated particles increases, the arc current for melting the powder tends to increase, and the damage to the electrode increases. As the size of the granulated powder of magnesia / alumina / spinel, those having an average diameter of 10 to 60 μm are particularly preferable.
[0010]
In producing the oxygen sensor element of the present invention, a measurement electrode and a reference electrode are formed at positions facing at least the inner and outer surfaces of the zirconia solid electrolyte substrate, and then a ceramic protective layer is formed on the surface of the measurement electrode, and an arc current value is measured. Is formed by plasma spraying with 550 A or less, the damage to the electrode can be reduced. On the other hand, when the arc current of the plasma exceeds 550 A, the plasma temperature increases, and as a result, the temperature of the melt increases and the damage of the electrode increases. The plasma arc current is particularly preferably 530 A or less.
[0011]
DETAILED DESCRIPTION OF THE INVENTION
(Cup type oxygen sensor)
As an embodiment of the present invention, a so-called cup-type oxygen sensor element is shown in FIG. In this oxygen sensor element, a ceramic heater for heating a sensing portion is inserted into a cylindrical tube as a zirconia solid electrolyte substrate.
[0012]
The oxygen sensor element 31 shown in FIG. 1 has a reference that is brought into contact with a reference gas such as air as a first electrode on the inner surface of a cylindrical tube 32 made of a zirconia solid electrolyte having oxygen ion conductivity and sealed at the tip. An electrode 33 is deposited, and a measurement electrode 34 that is in contact with a measured gas such as exhaust gas is deposited as a second electrode at a position facing the reference electrode 33 across the cylindrical tube 32.
[0013]
Further, a porous ceramic protective layer 35 made of magnesia / alumina / spinel, which is richer in alumina than the theoretical composition ratio, is provided on the surface of the measuring electrode 34 in order to protect the electrode from poisonous substances of exhaust gas by plasma spraying. Is formed. The ceramic protective layer 35 has a porosity of 10 to 40%, and a thickness of 10 to 200 μm, particularly 100 to 150 μm, although it depends on the open porosity.
[0014]
Further, instead of the ceramic protective layer 35, a porous ceramic protective layer made of a composite oxide of magnesia-alumina-spinel and magnesia rich in the theoretical composition ratio may be formed.
In the cup-type oxygen sensor, a ceramic heater 36 made of an insulating ceramic made of alumina or silicon nitride for inserting the sensing portion up to around 700 ° C. is inserted.
[0015]
(Production method)
A method for manufacturing the cup-type oxygen sensor shown in FIG. 1 will be described. After adding an organic binder to the zirconia solid electrolyte powder to produce a cylindrical zirconia molded body sealed at one end by a hydraulic press or an extrusion molding method, after cutting into a predetermined shape, a temperature range of 1400 to 1700 ° C. Then, the solid electrolyte cylindrical tube 32 is obtained by firing in the air for 1 to 10 hours.
[0016]
Thereafter, the reference electrode 33 and the measurement electrode 34 are formed on the inner and outer surfaces of the solid electrolyte cylindrical tube 32 by electroless plating. In addition, as another method for forming the electrode, a slurry made of a solid electrolyte powder such as platinum powder and zirconia is used on the inner and outer surfaces of the cylindrical sintered body, and a standard made of platinum by a method such as slurry dip or curved surface printing. After forming the electrode 33 and the measurement electrode 34, it may be formed by sintering simultaneously with the cylindrical molded body.
[0017]
Next, plasma spraying is performed using a plasma gun to form the ceramic protective layer 35 on the surface of the measurement electrode 34. In this plasma gun, a high voltage is applied between the central electrode serving as the cathode and the nozzle serving as the anode to excite the working gas of argon or nitrogen flowing between the electrodes generated by the high-frequency ignition device. And
The gas that has become plasma undergoes volume expansion due to a rapid temperature rise, and is ejected as a flame gas fluid from the nozzle outlet. Thereafter, a granulated body made of magnesia / alumina / spinel powder is supplied into the flame gas fluid at a constant speed, melted and accelerated to continuously collide with the surface of the measuring electrode 4, and the ceramic protective layer 35 is formed. Form. At this time, the solid electrolyte cylindrical tube 32 needs to be rotated at a constant speed around the axis of the cylindrical tube 32 in order to maintain the thickness of the ceramic protective layer 35 to be formed and the uniformity of the fine structure. .
[0018]
In the present invention, in order to form the ceramic protective layer with alumina-rich magnesia-alumina-spinel, magnesia-alumina-spinel powder having a purity of 99.5% or more and an average particle diameter of 1 to 5 μm is used as a raw material. Is granulated to an average diameter of 10 to 100 μm. In addition, the raw material composition at this time is controlled so that the ratio of magnesia to alumina is in the range of 29 to 19% by weight of magnesia and 71 to 91% by weight of alumina. Then, this is subjected to a thermal spraying process with a low current of 550 A or less. If the current value at this time is higher than 550 A, it is difficult to obtain alumina-rich magnesia-alumina-spinel. Thus, an alumina-rich magnesia-alumina-spinel with 28 to 20% by weight of magnesia and 72 to 80% by weight of alumina is formed.
[0019]
Further, when the ceramic protective layer is made of a composite oxide of magnesia, alumina, spinel and magnesia, magnesia is easy to react with hygroscopicity or carbon dioxide gas, so magnesia needs to be a ratio of 28% by weight or less.
[0020]
In the present invention, the zirconia solid electrolyte used to form the cylindrical tube 32 is ZrO.₂Specifically, it is made of ceramics containing₂O_{Three ,}Yb₂O_Three, Sc₂O_Three, Sm₂O_Three, Nd₂O_Three, Dy₂O_ThreePartially stabilized ZrO containing 1 to 30 mol%, preferably 3 to 15 mol% of a rare earth oxide such as₂Or stabilized ZrO₂Is used. ZrO₂ZrO in which 1 to 20 atomic% of Zr was substituted with Ce₂By using, there is an effect that the electron conductivity is increased and the responsiveness is further improved.
[0021]
Furthermore, for the purpose of improving the sinterability, the above ZrO₂In contrast, Al₂O_ThreeAnd SiO₂However, if a large amount is added, the creep characteristics at high temperatures deteriorate, so Al₂O_ThreeAnd SiO₂The total amount of added is preferably 5% by weight or less, particularly 3% by weight or less. The content of Na in the solid electrolyte is preferably 200 ppm or less, particularly 100 ppm, from the viewpoint of preventing diffusion penetration from the solid electrolyte to the ceramic insulating layer 6.
[0022]
As for the platinum electrode, the reference electrode 3 and the measurement electrode 4 deposited on the inner surface and the outer surface of the cylindrical tube 32 are each made of one or more alloys selected from platinum group metals. From the viewpoint of gas responsiveness, platinum is most desirable. In addition, when an electrode is formed using platinum particles, the purpose of preventing metal grain growth in the electrode during sensor operation and the contact at the so-called three-phase interface between the metal particles, solid electrolyte, and gas related to responsiveness In order to increase the amount of zirconia, a zirconia solid electrolyte component is further added to the metal particles, and the total amount of the ceramic component contained in the metal particles and the added ceramic component is 1 to 50% by volume, particularly 100% by volume of the metal component You may mix in the said electrode in the ratio of 10-30 volume%.
[0023]
(Heater integrated oxygen sensor element)
The present invention is preferably applied to a heater-integrated oxygen sensor having at least a pair of electrodes and a platinum heater embedded in a ceramic insulating layer and having the above-described ceramic protective layer formed on the surface of the measurement electrode 4. In the heater integrated oxygen sensor in which the pair of sensing units and the heater are integrated, rapid temperature increase is possible and the sensing temperature is high, so that the gas responsiveness is superior to the conventional cup oxygen sensor.
[0024]
FIG. 2: is the schematic perspective view (a) which shows the heater integrated oxygen sensor element which concerns on other embodiment of this invention, and its AA sectional drawing (b). In FIG. 2A, the outermost ceramic protective layer 13 is omitted for convenience of explanation.
The oxygen sensor 1 of FIG. 2 is made of a ceramic zirconia solid electrolyte having oxygen ion conductivity, and is contacted with a reference gas such as air as a first electrode on the inner surface of a cylindrical tube 2 whose tip is sealed. The reference electrode 3 is attached and formed, and the measurement electrode 4 that is in contact with the measurement gas such as exhaust gas is attached and formed as a second electrode at a position facing the reference electrode 3 across the cylindrical tube 2. ing. The detection portion is formed by the reference electrode 3, the cylindrical tube 2 made of a zirconia solid electrolyte, and the measurement electrode 4.
[0025]
On the outer surface of the cylindrical tube 2 whose tip is sealed,₂O_ThreeA ceramic insulating layer 6 is deposited and formed, and an opening 7 is formed in the ceramic insulating layer 6 so that part or all of the measurement electrode 4 is exposed.
A heating resistor 8 made of Pt or the like for heating the detection unit is embedded in the ceramic insulating layer 6 around the opening 7. A ceramic heat insulating layer 9 made of zirconia or the like is laminated on the surface of the ceramic insulating layer 6 in order to further increase the heating efficiency by the heating resistor 8.
The reference electrode 3 formed on the inner surface of the cylindrical tube 2 is connected to the sensor terminal portion 11 a provided on the outer surface of the cylindrical tube 2 via the inner surface of the cylindrical tube 2 and the end surface on the opening side.
[0026]
The ceramic protective layer 13 according to the present invention is formed on the surface of the measurement electrode 4. The ceramic protective layer 13 is preferably formed around the cylindrical tube 2 in addition to the measurement electrode 4. The measurement electrode 4 is connected to the lead portion 10 formed on the surface of the ceramic heat insulating layer 9 via the end face of the opening 7 formed in the ceramic insulating layer 6 and the ceramic heat insulating layer 9. It is connected to a terminal portion 11b formed on the surface. In addition, the edge part which exists in the said end surface in the cylindrical tube 2 is C-chamfered, and the defect of the electrical connection which arises in an edge part is avoided.
[0027]
Further, the surface of the lead portion 10 formed on the surface of the ceramic heat insulating layer 9 is further provided with ZrO.₂A protective layer 12 made of or the like is formed. The protective layer 12 can protect the lead portion 10 from physical destruction such as scratching when the element is assembled or collision with a foreign object when the element is dropped. This protective layer 12 is the same ZrO as the solid electrolyte.₂It is preferable to prevent the generation of stress due to the difference in thermal expansion from the solid electrolyte.
[0028]
In addition, metal members 14 for connection to an external circuit are respectively brazed and fixed to the sensor terminal portions 11a and 11b by, for example, Au-Cu brazing. Thereby, the detection data generated in the detection unit is transmitted to the external circuit via the lead unit 10, the sensor terminal units 11a and 11b, and the metal member 14.
[0029]
On the other hand, the heating resistors 8 formed in the ceramic insulating layer 6 are uniformly and symmetrically arranged on both sides of the opening 7 as shown in FIG. Further, the heating resistor 8 includes a ceramic heat insulating layer formed by a lead portion 16 formed in the ceramic insulating layer 6 and a through conductor (not shown) formed through the ceramic insulating layer 6 and the ceramic heat insulating layer 9. The heater terminal portion 18 formed on the outer surface of the heater 9 is electrically connected. A metal member 19 for connecting to an external power source for heat generation is fixed on these heater terminal portions 18 with a brazing material, and by passing an electric current to the heat generation resistor 8 through these, the heat generation resistor 8 is heated, The detection unit composed of the measurement electrode 4, the cylindrical tube 2 and the reference electrode 3 is rapidly heated to a predetermined temperature.
[0030]
The lead portion 16 of the heating resistor 8 can be formed by a wide single line. However, by forming the lead portion 16 by two or more lines, the lead portion 16 is coupled to the upper and lower ceramic insulating layers 6 sandwiching the lead portion 16. And the strength of the element can be increased.
[0031]
Further, as the overall size of the oxygen sensor, it is possible to reduce the power consumption and enhance the sensing performance by forming the cylinder with a cylindrical body having an outer diameter of 3 to 6 mm, particularly 3 to 4 mm.
[0032]
(Production method)
Next, a method for producing a heater integrated oxygen sensor element according to the present invention will be described with reference to FIG.
[0033]
(1) First, a hollow cylindrical tube 20 having both ends opened as shown in FIG. This cylindrical tube 20 is a well-known method such as extrusion molding, isostatic pressing (rubber press) or press formation by adding a molding organic binder to a ceramic solid electrolyte powder having oxygen ion conductivity such as zirconia. It is produced by.
[0034]
(2) And, on the inner surface and the outer surface of the cylindrical tube 20 made of the solid electrolyte, patterns 21 and 22 to be the reference electrode and the measurement electrode, for example, using a conductive paste containing platinum, a slurry dip method, screen printing, It is formed by pad printing, roll transfer or the like. At this time, it is efficient that the reference electrode pattern 22 is printed on the inner surface of the cylindrical tube 20 by filling the conductive paste and then discharging and coating the entire inner surface.
[0035]
The platinum paste used at this time is selected from the group consisting of platinum powder having an average particle diameter of 0.5 to 4 μm and a purity of 99% or more, particularly 99.5% or more, or platinum and rhodium, palladium, ruthenium and gold. It is desirable to use one kind of alloy powder as a metal component and further include zirconia powder, but zirconia powder has a specific surface area of 30 m.²/ G or more, especially 60m²/ G or more ultrafine powder is desirable. Thus, by blending the ultrafine zirconia powder, the binding energy can be reduced, and as a result, gas responsiveness can be enhanced.
[0036]
Thereafter, a slurry in which a zirconia material is dispersed in a petroleum solvent as a tip sealing material is poured to a depth of about 3 mm from the end portion on the tip side of the cylindrical tube 20 and dried. The reason why the petroleum solvent is used is that the zirconia powder is easily dispersed and easily injected into the cylindrical tube 20 having a small inner diameter, and the slurry is quickly dried. At this time, the amount of the petroleum solvent is preferably a slurry containing 5 to 25% by weight of the petroleum solvent with respect to 100% by weight of the zirconia material. At this time, if 1 to 5% by weight of an acrylic binder is added to the slurry, the adhesive force between the tip sealing material and the inner wall of the cylindrical tube 20 increases. Thereafter, the tip of the cylindrical tube is processed into a predetermined shape such as an arc. In this way, the sensor element A is manufactured.
[0037]
(3) Next, a heater element B as shown in FIG. 3B is formed. First, a ceramic green sheet for forming a ceramic insulating layer having a thickness of 50 to 500 [mu] m, particularly 100 to 300 [mu] m is prepared using the slurry containing the above-mentioned zirconia powder. Then, a ceramic powder such as alumina, spinel, forsterite, zirconia, glass or the like is added to the surface of this green sheet, and an appropriate organic binder for molding is added to prepare a slurry. Using this slurry, a screen printing method, a pad After printing by a printing method, a roll transfer method, etc., a conductive paste containing a metal powder such as platinum is printed on the surface by a screen printing method, a pad printing method, a roll transfer method, etc., and the lead pattern of the present invention is included. A heating resistor pattern 24 is applied. Then, the insulating slurry is applied again. Thereafter, by forming the opening 25 by punching or the like, a heater element B made of an unfired laminated body of the zirconia layer 23 to be the ceramic heat retaining layer 9 and the ceramic insulating layer 26 in which the heating resistor 24 is embedded is obtained. It is done.
[0038]
(4) Next, as shown in FIG. 3 (c), the heater element B is wound around the surface of the cylindrical sensor element A to produce a cylindrical laminate. At this time, in order to wrap the heater element B around the sensor element A, an adhesive such as an acrylic resin or an organic solvent is interposed between the heater element B and the sensor element A, or a roller or the like. Can be bonded mechanically while applying pressure. At this time, the seam of the wound heater element B may be overlapped with each other at a predetermined interval in consideration of shrinkage during firing. Further, the winding position of the tip of the cylindrical tube and the heater element B is adjusted so as to be 0.5 to 2 mm after firing.
[0039]
(5) The sensor element body A and the heater element body B can be integrated by firing the cylindrical laminate at a temperature at which the respective constituent elements can be fired simultaneously. The firing is suitably performed, for example, in an inert atmosphere such as argon gas or in the air at 1300 to 1700 ° C. for about 1 to 10 hours.
[0040]
In addition, according to the present invention, in order to prevent generation of oxides or hydroxides on the surface of the platinum electrode by the above-described firing, the oxygen sensor may be exposed to a reducing gas during the firing. However, there may be a problem that the zirconia solid electrolyte is reduced or the tetragonal crystal in the solid electrolyte is transformed into a monoclinic crystal, resulting in a decrease in strength.
Therefore, according to the present invention, the platinum electrode is energized and self-heated with respect to the oxygen sensor after firing, and the oxygen partial pressure is 10 ° C. at a temperature of 400 ° C. or higher, particularly 600 ° C.^-Tengas atmosphere lower than atm, eg H₂/ N₂And CO / CO₂By exposing to the atmosphere for about 1 minute to 1 hour, the reaction product formed on the surface of the platinum electrode during firing can be removed.
[0041]
In the above manufacturing method, the reference electrode pattern 22 and the measurement electrode pattern 21 are applied when the cylindrical tube 20 is formed. However, these electrodes are formed by winding the heater element B around the surface of the cylindrical tube 20 having no electrode. After the cylindrical laminated body is manufactured, electrode paste is applied to the cylindrical laminated body by screen printing, pad printing, roll transfer method or dipping method in the inner surface of the cylindrical tube 20 and the opening 25 in the heater element B. It can be applied to the surface of the cylindrical tube 20 or can be formed by sputtering or plating.
[0042]
Furthermore, in order to form the ceramic protective layer 13 of FIG. 1, after firing, a powder such as alumina, spinel, zirconia is printed and applied by a sol-gel method, a slurry dip method, a printing method, or the like, and is baked. It can be formed by coating by sputtering or plasma spraying, or can be formed by firing at the same time after applying a slurry for forming the ceramic protective layer 13 in advance when producing a cylindrical laminate. In particular, it is preferable to form the ceramic protective layer 13 by plasma spraying in the same manner as the cup-type oxygen sensor element described above.
[0043]
(Other element structures)
The heater-integrated oxygen sensor element of the present invention is not limited to the structure shown in FIGS. 1 and 2, and can be applied to various oxygen sensor elements.
FIG. 4 shows (a) a schematic perspective view and (b) a cross-sectional view of an example of a so-called A / F sensor. In FIG. 4A, the outermost ceramic protective layer 39 is omitted for convenience of explanation.
[0044]
This heater-integrated air-fuel ratio sensor is provided with a solid electrolyte layer 42 having a diffusion hole 42a through a space 41 outside a cylindrical tube 40 made of a solid electrolyte and sealed at one end. A first electrode pair consisting of a reference electrode 43 and a measurement electrode 44 is formed on the inner and outer surfaces, and at the same time, a second electrode consisting of an inner electrode 45 and an outer electrode 46 is formed on the inner and outer surfaces of the solid electrolyte layer 42 formed through the space 41. A pair is formed. And it consists of the structure which has arrange | positioned the ceramic insulating layer 48 which embed | buried the heating resistor 37 around these detection parts.
[0045]
In the element having such a structure, the ceramic protective layer 39 made of magnesia / alumina / spinel according to the present invention is preferably formed on at least the outer electrode surface directly in contact with the exhaust gas. In FIG. 4B, the ceramic protective layer 39 is provided on the entire circumference including the outer electrode surface. The ceramic protective layer 39 can be formed by a plasma spraying method or the like as described above.
[0046]
In this air-fuel ratio sensor, a current is passed between the second electrodes 45 and 46, and oxygen gas is introduced into the space 41 while being detected by the first electrodes 43 and 44 so that the oxygen concentration in the space 41 becomes constant. The air-fuel ratio in the exhaust gas is measured by flowing in or discharging.
[0047]
In the present invention, the fabricated element is N containing 0.1% or more of hydrogen by a method such as self-energization.₂Alternatively, the gas responsiveness can be improved by exposing it to a reducing gas composed of Ar at a temperature of 300 ° C. or more for 1 minute to 10 hours. The treatment temperature is particularly preferably 10 minutes or more at 600 ° C. In addition, the activation treatment is preferably performed on the reference electrode in addition to the measurement electrode.
The embodiments of the present invention have been described above. However, the present invention is not limited to these structures, and may be an oxygen sensor having a pair of porous electrodes facing at least inside and outside made by simultaneous firing. Needless to say, any of them can be applied.
[0048]
【Example】
Hereinafter, the present invention will be described with reference to examples.
[0049]
Example 1
Commercially available 5 mol% Y with a purity of 99.8%₂O_ThreeA polyvinyl alcohol solution is added to the containing zirconia powder to prepare a clay, and after sintering by extrusion molding, a cylindrical molded body with one end sealed so as to have an outer diameter of about 5 mm and an inner diameter of 3 mm is prepared. Firing was performed in the atmosphere at 1500 ° C. for 2 hours to obtain a cylindrical sintered body. Thereafter, platinum electrodes were formed on the inner and outer surfaces of the cylindrical sintered body by electroless plating.
Thereafter, powders having a particle diameter of about 1 μm and a composition of magnesia / alumina / spinel powder, in which the ratio of magnesia / alumina is 30 to 16% by weight of magnesia and 70 to 84% by weight of alumina are granulated. Using a granulated powder having an average particle size of approximately 100 μm, a ceramic protective layer was formed on the surface of the platinum electrode under various thermal spraying conditions. Sample No. About 9-14, the granulated powder of 71 weight% of alumina and 29% of magnesia was used. At that time, the composition of the ceramic protective layer was determined from X-ray diffraction and a calibration curve related to the alumina content dependency of the lattice constant of spinel powders having different alumina contents. The presence or absence of magnesia was similarly determined from X-ray diffraction. The size of the granulated particles was determined by measuring the diameter of 10 particles from a scanning electron micrograph and taking the average value.
Evaluation of the electrode performance in which the ceramic protective layer was formed was implemented using the engine bench about the produced oxygen sensor element. For this durability test, a gasoline engine with a 4-cylinder 1.5 l EGI was used, and the exhaust gas temperature was kept constant at 500 ° C. for 1000 hours. At this time, the λ value of the engine was changed from 0.95 to 1.05 as a response time by an external signal, and the time until the sensor output reached 0.4 V was obtained before and after the durability test. The results are shown in Table 1. Here, t1 in the table is the initial value of the response time, t2 is the response time after 1000 hours of endurance, and the deterioration rate is the response time before and after the endurance test determined from the formula: (t2-t1) / t1 (%) Deterioration rate is shown.
[Table 1]

From Table 1, it can be seen that with respect to the spinel composition, Sample Nos. 1 and 2 having a magnesia ratio of 28.3% by weight or more have a slow response time and a poor deterioration rate of the response time by the durability test.
Regarding the powder for thermal spraying as the starting material, a ceramic protective layer made of granulated particles having a size of about 10 to 100 μm was produced from the viewpoint of prevention of poisoning, and the arc current of the thermal spraying device was generated at 550 A or less. The ceramic protective layer was excellent.
From the above results, it can be easily understood that the ceramic protective layer of the present invention is remarkably excellent in the effect of protecting the electrode against poisoning.
[0050]
【The invention's effect】
According to the present invention, a porous ceramic protective layer made of magnesia / alumina / spinel is formed on the surface of the measurement electrode, and the composition of the magnesia / alumina / spinel is made richer in alumina than the theoretical composition ratio. There is an effect that the poisoning from the gas is surely prevented and the stable electrode performance can be maintained for a long time.
[Brief description of the drawings]
FIG. 1 is a cross-sectional view showing a cup-type oxygen sensor element according to an embodiment of the present invention.
2A is a schematic perspective view showing a heater integrated oxygen sensor element according to another embodiment of the present invention, and FIG. 2B is a cross-sectional view taken along line AA in FIG.
3 is an explanatory view showing a method of manufacturing the heater integrated oxygen sensor element shown in FIG. 2. FIG.
4A is a cross-sectional view showing another example of the heater-integrated oxygen sensor element according to the present invention, and FIG. 4B is a cross-sectional view taken along the line XX.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 ... Heater integrated oxygen sensor element, 2 ... Cylindrical tube, 3 ... Reference electrode, 4 ... Measuring electrode, 6 ... Ceramic insulating layer, 7 ... Opening part, 8 ... Heat generating resistor, 13 ... Ceramic protective layer, 34 ... Ceramic Protective layer, 39 ... Ceramic protective layer

Claims (4)

An oxygen sensor in which a measurement electrode and a reference electrode are formed at positions facing at least inner and outer surfaces of a zirconia solid electrolyte substrate, and a porous ceramic protective layer made of magnesia, alumina, and spinel is formed on the surface of the measurement electrode. An oxygen sensor element characterized in that, as a composition of the magnesia / alumina / spinel, the ratio of magnesia to alumina is 28 to 20% by weight of magnesia and 72 to 80% by weight of alumina . An oxygen sensor in which a measurement electrode and a reference electrode are formed at positions opposite to each other at least on the inner and outer surfaces of a zirconia solid electrolyte substrate, the porous electrode comprising a composite oxide of magnesia, alumina, spinel and magnesia on the surface of the measurement electrode The oxygen is characterized in that the ceramic protective layer is formed and the composition of the magnesia-alumina-spinel is such that the ratio of magnesia to alumina is 28 to 20% by weight of magnesia and 72 to 80% by weight of alumina. Sensor element. The oxygen sensor element according to claim 1 or 2, wherein a granulated powder of magnesia-alumina-spinel having an average diameter of 10 to 100 µm is used as a material for forming the ceramic protective layer. 3. The method of manufacturing an oxygen sensor element according to claim 1, wherein a measurement electrode and a reference electrode are formed at positions facing at least the inner and outer surfaces of the zirconia solid electrolyte substrate, and then a ceramic protective layer is formed on the surface of the measurement electrode. Is formed by plasma spraying with an arc current value of 550 A or less.

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