JP6567700B2 - Temperature sensor element - Google Patents

Description

  The present invention relates to a temperature sensor element used for temperature measurement at a high temperature.

  A platinum temperature sensor for high temperature measurement is attached to a high temperature region such as an automobile engine room. As a platinum temperature sensor, there is known a platinum temperature sensor formed by covering a resistance pattern of a platinum thin film provided on a ceramic substrate with a protective film made of ceramics (see Patent Documents 1 and 2). Since platinum is chemically stable, it does not easily change its characteristics even at high temperatures, and is a sensor suitable for high temperature applications.

A ceramic substrate used for a platinum temperature sensor is obtained by firing an inorganic material serving as a ceramic material at a high temperature of 1000 ° C. or higher to increase the density, thereby forming a dense sintered body. In order to stabilize firing and promote densification of ceramics to increase production efficiency, firing is performed in a state where a sintering aid such as SiO ₂ is added to an inorganic material of the ceramic material (for example, Patent Documents). 3).

Japanese Patent No. 5976186 JP 2005-241568 A JP 2003-277132 A

  However, at a high temperature at which firing is performed, the platinum of the resistance pattern becomes highly reactive, so that the sintering aid of the ceramic substrate reacts with platinum. Thereby, TCR (Temperature Coefficient of Resistance, temperature coefficient of resistance) of platinum changes, and there is a problem that resistance value drift is caused.

  This invention is made | formed in view of this point, and makes it one of the objectives to provide the temperature sensor element which can maintain a high measurement precision by the reaction of a resistance pattern and a sintering aid being prevented.

A temperature sensor element according to an aspect of the present invention includes an alumina sintered body and a resistance pattern disposed inside the alumina sintered body, wherein a main component of the resistance pattern is platinum, The alumina sintered body contains 99.70% by mass or more of alumina and does not contain a sintering aid. The alumina sintered body includes a first sintered layer, a second sintered layer, The resistance pattern is disposed between the first sintered layer and the second sintered layer, and the first sintered layer has the resistance on the main surface. A substrate on which a pattern is formed is formed, and the second sintered layer forms a protective layer laminated on the main surface of the substrate so as to protect the resistance pattern, and the second sintered layer Are a trap layer formed so as to cover the resistance pattern, and an overcoat formed so as to cover the trap layer. It has a coating layer, the average particle diameter of the alumina particles constituting the overcoat layer may be greater than the average particle diameter of the alumina particles constituting the trap layer.

  According to this structure, the alumina of the alumina sintered body has a high purity and does not contain a sintering aid. For this reason, at the time of baking alumina, the sintering aid does not react with platinum of the resistance pattern, and impurities contained in alumina are prevented from reacting with platinum of the resistance pattern. Thereby, platinum TCR is maintained and resistance value drift is suppressed, so that high measurement accuracy is maintained. In addition, since the alumina sintered body has better heat resistance than the glass sintered body and the generation of cracks in the alumina sintered body at high temperatures is suppressed, the resistance pattern should be arranged in the alumina sintered body. Thus, it is possible to prevent the platinum from being deteriorated by being exposed to a high temperature atmosphere.

A temperature sensor element according to an aspect of the present invention includes an alumina sintered body and a resistance pattern disposed inside the alumina sintered body, wherein a main component of the resistance pattern is platinum, The alumina sintered body contains 99.70% by mass or more of alumina and does not contain a sintering aid. The alumina sintered body includes a first sintered layer, a second sintered layer, The resistance pattern is disposed between the first sintered layer and the second sintered layer, and the first sintered layer has the resistance on the main surface. A substrate on which a pattern is formed is formed, and the second sintered layer forms a protective layer laminated on the main surface of the substrate so as to protect the resistance pattern, and the second sintered layer Are a trap layer formed so as to cover the resistance pattern, and an overcoat formed so as to cover the trap layer. A coating layer, and the trap layer has a first trap layer formed so as to cover the resistance pattern, and a second trap layer stacked on the first trap layer. The first trap layer contains platinum at a lower content than the second trap layer.

  In the temperature sensor element of one embodiment of the present invention, at least one of the first sintered layer and the second sintered layer has a plurality of different average particles having an average particle diameter of 0.1 to 10.0 μm. It is preferable to be composed of alumina particles having a diameter. As a result, the alumina sintered body is composed of a plurality of types of alumina particles having different average particle diameters, thereby densifying the alumina sintered body and preventing cracks in the alumina sintered body during firing. Therefore, it is prevented that platinum is deteriorated by high-temperature air.

  In the temperature sensor element of one embodiment of the present invention, the alumina particles are preferably composed of alumina particles having an average particle size of at least three kinds. Thereby, the alumina sintered body is effectively densified, and cracks of the alumina sintered body during firing are effectively prevented.

  In the temperature sensor element of one embodiment of the present invention, it is preferable that alumina contained in at least one of the first sintered layer and the second sintered layer is 99.99% by mass or more. This effectively prevents the impurities contained in the alumina from reacting with the resistance pattern platinum.

  In the temperature sensor element of one aspect of the present invention, the first sintered layer forms a substrate on which the resistance pattern is formed on a main surface, and the second sintered layer has the resistance pattern. It is preferable to form a protective layer laminated on the main surface of the substrate so as to protect it. Thereby, the resistance pattern is disposed in the alumina sintered body with a simple configuration.

  In the temperature sensor element of one embodiment of the present invention, the second sintered layer includes a trap layer formed so as to cover the resistance pattern, an overcoat layer formed so as to cover the trap layer, It is preferable to have. Thereby, since the resistance pattern is effectively sealed by the two protective layers, platinum is effectively prevented from being exposed to high-temperature air.

  In the temperature sensor element of one embodiment of the present invention, it is preferable that the average particle diameter of the alumina particles constituting the overcoat layer is larger than the average particle diameter of the alumina particles constituting the trap layer. Thereby, the alumina sintered body is effectively densified by increasing the average particle diameter of the alumina particles in the direction away from the resistance pattern.

  In the temperature sensor element of one embodiment of the present invention, the trap layer preferably contains 2% by volume to 30% by volume of platinum. As a result, when the trap layer covering the resistance pattern contains platinum, and the reactivity of the resistance pattern platinum becomes high under high temperature use, the trap layer platinum becomes oxygen in the atmosphere or alumina-based firing. Reacts with impurities in the body. Thereby, since the reaction of the resistance pattern is suppressed and the deterioration of platinum is prevented, the drift of the resistance value is suppressed.

  In the temperature sensor element of one embodiment of the present invention, the trap layer includes a first trap layer formed so as to cover the resistance pattern, and a second trap layer stacked on the first trap layer. The first trap layer preferably contains platinum at a lower content than the second trap layer. Thereby, conduction can be suppressed by the first trap layer having a low platinum content. Therefore, by interposing the first trap layer between the resistance pattern and the second trap layer, the first trap layer has a high platinum content while suppressing a decrease in the resistance value of the resistance pattern. Resistance trapping can be suppressed by effectively suppressing the reaction of the resistance pattern with the two trap layers.

  In the temperature sensor element of one embodiment of the present invention, the first trap layer contains 0% by volume to 10% by volume of platinum, and the second trap layer contains 2% by volume to 30% by volume of platinum. It is preferable to contain below. Thereby, the reaction of the resistance pattern can be more effectively suppressed in the second trap layer while effectively suppressing the decrease in the resistance value of the resistance pattern in the first trap layer.

In the temperature sensor element of one embodiment of the present invention, it is preferable that no cracks are formed in the alumina sintered body.
The temperature sensor element of one embodiment of the present invention includes a substrate made of an alumina sintered body containing 99.70% by mass or more of alumina and no sintering aid, and a platinum film formed on the main surface of the substrate And a protective layer made of an alumina sintered body that is formed on the main surface so as to protect the resistance pattern, contains 99.70% by mass or more of alumina, and does not contain a sintering aid. The protective layer includes a trap layer that covers the entire surface of the resistance pattern, and an overcoat layer that covers the surface of the trap layer, and the peripheral portions of the trap layer and the overcoat layer are Each of which is in close contact with the main surface, the trap layer contains platinum at a position away from the resistance pattern, and the overcoat layer has an average particle diameter of alumina particles larger than that of the trap layer. Wherein the listening voids is small.
The temperature sensor element of one embodiment of the present invention is a temperature sensor element formed by firing a laminate having a plurality of green sheets and a plurality of resistance patterns disposed between the green sheets, The alumina sintered body obtained by firing the green sheet contains 99.70% by mass or more of alumina, does not contain a sintering aid, the resistance pattern is made of a platinum film, and the alumina sintered body The average particle diameter of the alumina particles contained in is increased from the inner layer toward the upper layer and the lower layer.

  According to the present invention, a high measurement accuracy can be maintained by preventing a reaction between the resistance pattern and the sintering aid.

It is a top view of the temperature sensor element which concerns on a 1st form. It is sectional drawing which follows the AA line of FIG. It is sectional drawing which follows the BB line of FIG. It is a figure which shows the other example of the temperature sensor element which concerns on 1st Embodiment. It is a figure which shows the other example of the temperature sensor element which concerns on 1st Embodiment. It is explanatory drawing of the manufacturing process of the temperature sensor element which concerns on 1st Embodiment. It is sectional drawing of the temperature sensor element which concerns on 2nd Embodiment. It is explanatory drawing of the manufacturing process of the temperature sensor element which concerns on 2nd Embodiment. It is sectional drawing of the temperature sensor element which concerns on 3rd Embodiment. The result of the electricity test of the temperature sensor element which concerns on an Example is shown. It is a figure which shows the temperature sensor element whose alumina of the alumina-type sintered compact which concerns on an Example is 99.99 mass%. It is a figure which shows the alumina particle which comprises the protective layer containing 99.99 mass% alumina which concerns on an Example. It is the figure which observed the temperature sensor element from the upper part.

In general, in the manufacturing process of a ceramic substrate used for a platinum temperature sensor, an inorganic material as a material of the ceramic substrate is fired at a high temperature of 1000 ° C. or more to form a dense sintered body. By obtaining a dense sintered body, the generation of cracks is prevented and the exposure of platinum to high temperatures is suppressed. At this time, in order to lower the firing temperature and promote densification of the ceramic, firing is performed in a state where a sintering aid such as SiO ₂ , MgO, CaO is added to the inorganic material of the ceramic material.

  However, under the high temperature at which firing is performed, the platinum of the resistance pattern becomes highly reactive, so that platinum reacts with a sintering aid and impurities such as Si contained in the ceramic substrate. Further, PtSi produced by the reaction of the sintering aid and impurities Si and platinum contained in the ceramic substrate has a problem of volatilizing at a temperature lower than that of platinum. As a result, there is a problem that the TCR of the platinum of the resistance pattern is changed and the drift of the resistance value is caused. In the sensor element described in Patent Document 3, the content of the inorganic substance that is the material of the ceramic substrate is specified, but a sintering aid is used, and the reaction between platinum and the sintering aid is suppressed. I could not.

  On the other hand, if the sintering aid is not added to the ceramic material, the ceramic will not be densified, the sintered density will not be increased, and there will be more voids in the ceramic, or cracks will occur in the ceramic substrate during firing. There is. As a result, the platinum of the resistance pattern is exposed to high temperature air and deteriorates.

  In the temperature sensor element, when glass is used as the material for the ceramic substrate, the heat resistance of the glass is inferior to that of the ceramic substrate made of alumina. As a result, there is a problem that the resistance increases and the platinum reacts with the resistance pattern. Further, when the ceramic substrate is sealed using glass, the glass is broken during high temperature measurement, and the resistance pattern is exposed to high temperature air.

  Therefore, in the present embodiment, the ceramic substrate uses high-purity alumina and does not contain a sintering aid, so that the sintering aid and impurities such as Si may react with the resistance pattern platinum. Is prevented. Thereby, the drift of the resistance value of the resistance pattern is suppressed. Moreover, since it is formed of high-purity alumina, it has better heat resistance than that formed of glass, and the generation of cracks in the ceramic substrate at high temperatures is suppressed. In addition, since the ceramic substrate is composed of a plurality of types of alumina particles having different average particle diameters, the ceramic substrate is densified, and cracking of the ceramic substrate during firing is prevented.

  Hereinafter, a temperature sensor element according to a first embodiment will be described with reference to the accompanying drawings. FIG. 1 is a plan view of a temperature sensor element according to the first embodiment. 2 is a cross-sectional view taken along line AA in FIG. 3 is a cross-sectional view taken along line BB in FIG.

  As shown in FIGS. 1 to 3, the temperature sensor element 10 is formed by disposing a resistance pattern 18 inside an alumina sintered body 11 having a rectangular shape in plan view. The resistance pattern 18 has a meander shape in the horizontal direction, and a plurality of linear portions 18a extending in the longitudinal direction of the temperature sensor element 10 are arranged in parallel in the short direction at predetermined intervals, and adjacent linear portions 18a. The ends are connected by a folded portion 18b. A pair of electrodes 16 are formed at both ends of the resistance pattern 18, and lead wires (not shown) are joined to the pair of electrodes 16.

  The pair of electrodes 16 is formed by baking an electrode paste containing platinum. The resistance pattern 18 is a thin film resistance film containing platinum as a main component.

The alumina sintered body 11 contains 99.70% by mass or more of alumina (Al ₂ O ₃ ). The alumina sintered body 11 can be obtained by firing alumina particles having a purity of 99.90-99.99%. As a material of the sintered body covering the resistance pattern 18, a good sealing function, oxidation, volatilization, decomposition, etc. due to high temperature can be suppressed, it is difficult to be reduced, hardly reacts with platinum, and the linear expansion coefficient is close to the resistance pattern 18. From the viewpoint of migration resistance and the like, it is preferable to use alumina particles. However, other particles than the alumina particles may be used as long as they have these characteristics. For example, magnesia may be used.

Moreover, the alumina sintered body 11 does not contain a sintering aid. Examples of the sintering aid include SiO ₂ , CaO, MgO, TiO ₂ , B ₂ O _{3 and the} like. Sintering aids and impurities described below react with the platinum of the resistance pattern 18 that has become highly reactive at high temperatures, causing a drift in resistance.

  The alumina sintered body 11 may contain a small amount of impurities. Impurities are impurities contained in the alumina powder as a material, and even a high-purity alumina particle contains a small amount of impurities. Examples of the impurities include Si, Na, B, Ca, Mg, and the like. In particular, Na and Si react with the resistance pattern to cause resistance value drift. The content of impurities in the alumina sintered body 11 is preferably less than 0.3% by mass, and more preferably less than 0.01% by mass.

  Since the alumina-based sintered body 11 does not contain a sintering aid and contains high-purity alumina, the sintering aid does not react with the platinum of the resistance pattern 18 during firing of alumina. Impurities contained in the particles are prevented from reacting with platinum of the resistance pattern 18 and resistance value drift is suppressed, so that high measurement accuracy of the temperature sensor element 10 is maintained. In addition, the alumina sintered body 11 has better heat resistance than the glass sintered body, and the generation of cracks in the alumina sintered body 11 at a high temperature during firing or measurement is suppressed. For this reason, by arranging the resistance pattern 18 in the alumina sintered body 11, the platinum of the resistance pattern 18 is prevented from being exposed to a high-temperature atmosphere.

  As described above, the alumina sintered body 11 contains 99.70% by mass or more of alumina, and if it does not contain a sintering aid, as shown in FIG. The second sintered layer 24 may be provided, and the resistance pattern 18 may be disposed between the first sintered layer 21 and the second sintered layer 24. FIG. 4 is a diagram illustrating another example of the temperature sensor element according to the first embodiment.

  At least one of the first sintered layer 21 and the second sintered layer 24 is configured by using a plurality of types of alumina particles having different average particle sizes within the range of 0.1 to 10.0 μm. ing. Here, the average particle diameter of the alumina particles of the alumina sintered body 11 means that 10-100 particles are observed on the screen of the photograph taken by observing the cross section of the alumina sintered body 11 with a scanning electron microscope. The maximum diameter is measured, and the cumulative value of the maximum diameter is divided by the number of particles. Thus, when the alumina sintered body 11 is composed of a plurality of types of alumina particles having different average particle diameters, voids between the particles are reduced, the alumina sintered body 11 is densified, and is fired. Generation of cracks in the alumina sintered body 11 is prevented. For this reason, the platinum of the resistance pattern 18 is prevented from being deteriorated by high-temperature air during firing.

  The alumina particles constituting at least one of the first sintered layer 21 and the second sintered layer 24 are preferably composed of alumina particles having at least three types of average particle diameters. Thereby, the alumina sintered body 11 is effectively densified, and cracks of the alumina sintered body 11 during firing are effectively prevented.

  In at least one of the first sintered layer 21 and the second sintered layer 24, the contained alumina is preferably 99.99% by mass or more. This effectively prevents the impurities contained in the alumina particles from reacting with the platinum of the resistance pattern 18.

  If the above conditions are satisfied, the first sintered layer 21 and the second sintered layer 24 may be formed of a green sheet.

  Hereinafter, the temperature sensor element 10 formed by disposing the resistance pattern 18 between the first sintered layer 21 and the second sintered layer 24 will be described in detail. FIG. 5 is a diagram illustrating another example of the temperature sensor element according to the first embodiment. The upper diagram in FIG. 5 is a diagram of the temperature sensor element 10 observed with a scanning electron microscope, and the lower diagram corresponds to a cross-sectional view taken along the line AA in FIG.

  As shown in FIG. 5, the first sintered layer 21 forms a substrate having a resistance pattern 18 formed on the main surface, and the second sintered layer 24 forms a substrate so as to protect the resistance pattern 18. The protective layer 24 laminated on the main surface of 21 may be formed. Thereby, the resistance pattern 18 can be disposed in the alumina sintered body 11 with a simple configuration.

  Further, as shown in FIG. 5A, the protective layer 24 may include a trap layer 22 formed so as to cover the resistance pattern 18 and an overcoat layer 23 formed so as to cover the trap layer 22. Good. The overcoat layer 23 covers the entire trap layer 22, and its peripheral edge is in close contact with the main surface of the substrate 21. From the upper diagram of FIG. 5A, it can be seen that the platinum portion of the resistance pattern 18 is observed in white. Since the resistance pattern 18 is effectively sealed by covering the resistance pattern 18 with the two protective layers 24, the platinum of the resistance pattern 18 is prevented from being exposed to high-temperature air. For this reason, the drift of the resistance value of the resistance pattern 18 is suppressed.

  The average particle diameter of the alumina particles constituting the overcoat layer 23 is preferably larger than the average particle diameter of the alumina particles constituting the trap layer 22. In the protective layer 24, the alumina sintered body 11 is effectively densified by increasing the average particle diameter of the alumina particles in the direction away from the resistance pattern 18.

  As shown in FIG. 5B, the trap layer 32 may be formed to contain platinum. From the upper diagram of FIG. 5B, it can be seen that platinum contained in the trap layer 32 is observed as white spots around the resistance pattern 18 observed in white. Since the trap layer 32 covering the resistance pattern 18 contains platinum, even when the platinum of the resistance pattern 18 becomes highly reactive at the time of firing or use of the temperature sensor element 10 at a high temperature, the trap layer 32 is trapped. The platinum in the layer 32 reacts with oxygen in the atmosphere and impurities in the alumina sintered body 11. Thereby, since the reaction of platinum of the resistance pattern 18 is suppressed, deterioration of the resistance pattern 18 is prevented, and resistance value drift is effectively suppressed.

  The trap layer 32 preferably contains 2% by volume to 30% by volume of platinum. If platinum of the trap layer 32 is 2% by volume or more, the trap layer 32 can effectively exhibit the function of suppressing the reaction of the platinum of the resistance pattern 18. If it is 30 volume% or less, it can prevent that the platinum of the trap layer 32 conduct | electrically_connects, and can prevent that the resistance value of the resistance pattern 18 falls.

  As shown in FIG. 5C, the trap layer 42 is formed of a first trap layer 42a formed so as to cover the resistance pattern 18 and a second trap layer 42b stacked on the first trap layer 42a. May be. The platinum content of the first trap layer 42a is lower than the platinum content of the second trap layer 42b. 5C, platinum contained in the second trap layer 42b stacked on the first trap layer 42a is observed as white dots above the resistance pattern 18 observed in white. I understand that.

  In this way, by interposing the first trap layer 42a having a low platinum content between the resistance pattern 18 and the second trap layer 42b, conduction due to platinum contained in the trap layer 42 can be suppressed. it can. As a result, while suppressing a decrease in the resistance value of the resistance pattern 18, platinum in the second trap layer 42 b having a high platinum content is reacted with oxygen in the atmosphere or impurities in the alumina-based sintered body 11. Can be effectively suppressed. Thereby, the drift of the resistance value of the resistance pattern 18 is effectively suppressed.

  The first trap layer 42a preferably contains 0% by volume to 10% by volume of platinum, and the second trap layer 42b preferably contains 2% by volume to 30% by volume of platinum. As a result, while the first trap layer 42a having a relatively low platinum content effectively suppresses a decrease in the resistance value of the resistance pattern 18, the second trap layer 42b having a relatively high platinum content has a resistance. The reaction between the pattern 18 and oxygen and impurities can be more effectively suppressed.

  Next, a manufacturing process of the temperature sensor element 10 configured as described above will be described. FIG. 6 is an explanatory diagram of the manufacturing process of the temperature sensor element according to the first embodiment.

  First, a ceramic substrate 21 (see FIG. 5C) formed from high-purity alumina is prepared. The ceramic substrate 21 preferably contains 99.70% by mass or more of alumina, and more preferably 99.99% by mass or more.

  Next, the resistance pattern 18 is formed. Platinum is vapor-deposited on the surface of the ceramic substrate 21 and stabilized by heat treatment. Then, by patterning the platinum film by photolithography and etching, a meander-shaped resistance pattern 18 (see FIG. 1) is formed in each chip region of the ceramic substrate 21.

  Next, the electrode 16 (see FIG. 3) is formed. An electrode paste containing platinum is screen-printed on the surface of the ceramic substrate 21 so as to cover both ends of the resistance pattern 18. Then, this is dried and fired at about 1400 ° C., thereby forming a pair of electrodes 16 connected to both ends of the resistance pattern 18. Then, the resistance value of the resistance pattern 18 is adjusted.

  Next, the material of the protective layer 24 (see FIG. 5C) is weighed. Specifically, alumina particles are mixed with an appropriate amount of an organic binder, an organic solvent, and the like to produce an alumina paste. By screen printing the alumina paste, the first trap layer 42a, the second trap layer 42b, and the overcoat layer 23 (see FIG. 4C) are formed.

  The alumina paste used for forming the first trap layer 42a is alumina paste A, the alumina paste used for the second trap layer 42b is alumina paste B, and the alumina paste used for the overcoat layer 23 is alumina paste C. The alumina particles used in the alumina paste A-C are preferably prepared from alumina particles having a purity of 99.90-99.99%. Thereby, the alumina contained in the alumina sintered body 11 obtained by firing can be preferably 99.70% by mass or more, more preferably 99.90% by mass or more. In addition, since the content of impurities can be made very low, it is possible to prevent the impurities and the resistance pattern 18 from reacting during firing of the alumina particles.

  The alumina particles are preferably alumina particles having a plurality of different average particle sizes of 0.1 to 10.0 μm, and more preferably at least three types of alumina particles having an average particle size. Thereby, the alumina sintered body 11 obtained by firing the alumina particles can be densified, and cracking of the alumina sintered body 11 during firing is prevented.

  No sintering aid is added to the alumina paste A-C. This prevents the sintering aid from reacting with the platinum of the resistance pattern 18 during the firing of the alumina particles, and the resistance value drift of the resistance pattern 18 is suppressed.

  The alumina paste A preferably contains 0% to 30% by volume of platinum, more preferably 0% to 10% by volume. For example, the alumina paste A is mixed so that it becomes 98 volume% alumina particles and 2 volume% platinum. The alumina paste A preferably contains platinum at a lower content than the alumina paste B described later. Thereby, the 1st trap layer 42a with a low platinum content rate can be formed between the resistance pattern 18 and the 2nd trap layer 42b. For this reason, in the temperature sensor element 10, while the first trap layer 42 a suppresses a decrease in the resistance value of the resistance pattern 18, the second trap layer 42 b having a high platinum content has a resistance to impurities and oxygen. The reaction can be effectively suppressed.

  The alumina paste B preferably contains 2% by volume to 30% by volume of platinum. For example, the alumina paste B is mixed so as to be 90 volume% alumina particles and 10 volume% platinum. The alumina paste B preferably contains platinum at a higher content than the alumina paste A.

  The alumina paste C preferably contains alumina particles having an average particle size larger than that of the alumina pastes B and C. Thereby, the average particle diameter of the alumina particles of the overcoat layer 23 covering the trap layer 42 can be made larger than the average particle diameter of the alumina particles of the trap layer 42 close to the resistance pattern 18. Effective densification can be achieved.

  Next, the first trap layer 42a (see FIG. 5C) is formed. Alumina paste A is screen-printed on the surface of the ceramic substrate 21 so as to cover part of the resistance pattern 18 and the pair of electrodes 16. And this is dried and baked at 800-1500 degreeC. Thereby, a first trap layer 42a covering the resistance pattern 18 is formed. The first trap layer 42 a is in close contact with the surface of the ceramic substrate 21 exposed around the resistance pattern 18 while covering the resistance pattern 18.

  Next, the second trap layer 42b is formed. Alumina paste B is screen-printed on the first trap layer 42a. And this is dried and baked at 1400-1700 degreeC. Thus, the second trap layer 42b is stacked on the first trap layer 42a. The peripheral edge portion of the second trap layer 42b may be in close contact with the surface of the ceramic substrate 21 exposed outside the first trap layer 42a. The trap layer 42 is formed by the first trap layer 42a and the second trap layer 42b.

  Next, the overcoat layer 23 is formed. Alumina paste C is screen-printed on the second trap layer 42b. And this is dried and baked at 1400-1700 degreeC. Thereby, the overcoat layer 23 is formed so as to cover the trap layer 42. The peripheral portion of the overcoat layer 23 is in close contact with the surface of the ceramic substrate 21 exposed outside the trap layer 42. As a result, a protective layer 24 having a laminated structure including an inner trap layer 42 containing alumina as a main component and containing platinum and an outer overcoat layer 23 containing alumina as a main component and not containing platinum is formed.

  Next, it cuts and divides | segments, The ceramic substrate 21 is separated into pieces, The chip | tip of the magnitude | size equivalent to the board | substrate 21 shown to FIG. 5C is produced. The temperature sensor element 10 is obtained by welding a lead wire to a pair of electrodes 16 formed on each chip, covering the welded portion with a reinforcing film such as potting glass, and firing.

  By producing the temperature sensor element 10 in this manner, the alumina sintered body 11 surrounding the resistance pattern 18 preferably contains 99.70% by mass or more, more preferably 99.99% by mass or more of alumina. In addition, the alumina sintered body 11 can be formed. This prevents the sintering aid from reacting with the platinum of the resistance pattern 18 and prevents impurities from reacting with the resistance pattern 18, so that the drift of the resistance value of the resistance pattern 18 is suppressed, and the temperature sensor element 10 is Even when used continuously at high temperatures, high measurement accuracy is maintained.

  Next, the temperature sensor element 70 according to the second embodiment will be described. In the second embodiment, the first sintered layer 21 and the second sintered layer 24 are formed of a green sheet. The difference from the first embodiment will be mainly described. FIG. 7 is a cross-sectional view of a temperature sensor element according to the second embodiment. FIG. 7 corresponds to a cross-sectional view taken along line BB in FIG.

  As shown in FIG. 7, the temperature sensor element 70 according to the second embodiment is formed by stacking a plurality of stacked bodies in which a resistance pattern 78 is disposed between green sheets 61-67. Yes. The green sheets 61-67 are in close contact with each other to form an alumina sintered body, and the inner green sheets 62, 63, 64, 65, 66 are disposed between the upper and lower green sheets 61, 67. ing. The laminated resistance patterns 78 are connected by a through conductor 79 that penetrates the alumina sintered body 11 (see FIG. 1).

  An electrode 76 is formed on the upper end or lower end of the laminated resistance pattern 78 via a through conductor 79, and a lead wire is bonded to the electrode 76. The electrode 76 and the resistance pattern 78 are sealed with a sintered body 75. The sealing of the resistance pattern 78 is preferably performed with an alumina sintered body from the viewpoint of heat resistance, but may be performed with a glass sintered body as long as the heat resistance can be maintained.

  By forming the alumina sintered body 11 surrounding the resistance pattern 78 with the green sheets 61-67, the alumina sintered body 11 is effectively sintered, and the resistance pattern 78 is effectively sealed. This effectively prevents the platinum of the resistance pattern 78 from being exposed to a high temperature atmosphere.

  The green sheets 61-67 used for the alumina sintered body 11 are formed by forming a mixture of alumina particles together with an organic binder and an organic solvent into a sheet shape and firing the sheet. Among the laminated green sheets 61-67, the average particle diameter of the alumina particles constituting the upper and lower green sheets 61, 67 is the same as that of the alumina particles constituting the inner green sheets 62, 63, 64, 65, 66. It is preferably larger than the average particle size. The alumina sintered body is effectively densified by increasing the average particle diameter of the alumina particles from the inner green sheets 62, 63, 64, 65, 66 to the upper and lower green sheets 61, 67. It will be in the state.

  Next, the manufacturing process of the temperature sensor element 70 configured as described above will be described. FIG. 8 is an explanatory diagram of the manufacturing process of the temperature sensor element according to the second embodiment.

  First, the green sheet material is weighed. Then, alumina particles and an appropriate amount of an organic binder, an organic solvent, a plasticizer, a dispersant, and the like are mixed to prepare a slurry. As will be described later, the slurry is dried to obtain green sheets 61-67 (see FIG. 7).

  The alumina particles are preferably prepared from alumina particles having a purity of 99.90-99.99%. Thereby, the alumina contained in the alumina sintered body 11 (see FIG. 1) obtained by firing can be preferably 99.70% by mass or more, more preferably 99.90% by mass or more.

  The alumina particles are preferably alumina particles having a plurality of different average particle sizes of 0.1 to 10.0 μm, and more preferably at least three types of alumina particles having an average particle size. Thereby, the alumina sintered body 11 obtained by firing the alumina particles can be densified. Also, no sintering aid is added to the slurry.

  The average particle diameter of the alumina particles in the slurry used for the upper and lower green sheets 61 and 67 is larger than the average particle diameter of the alumina particles in the slurry used for the inner green sheets 62, 63, 64, 65 and 66. Larger is preferred. Thus, the average particle diameter of the alumina particles can be increased from the inner green sheets 62, 63, 64, 65, 66 toward the upper and lower green sheets 61, 67. Effective densification can be achieved.

  Next, green sheets 61-67 are formed. The green sheet is obtained by forming the slurry into a sheet and drying it.

  Next, the green sheet is cut and drilled. The green sheets 61-67 are cut to a predetermined size. Further, the green sheet is punched to form a through hole at a predetermined position of the green sheet.

  Next, the resistance pattern 78 is formed by printing. The resistance pattern 78 is formed by screen-printing and drying a conductive paste mainly composed of platinum at predetermined positions of the green sheets 61-67.

  Next, the green sheets 61-67 are overlaid. Then, the through-hole 79 is formed by filling the through-hole with a conductive paste by screen printing and drying.

  Next, the green sheets 61-67 laminated as described above are pressed. First, after the inner green sheets 62, 63, 64, 65, 66 are overlapped, they are integrated by thermocompression bonding, and the lower green sheet 61, the fired inner green sheets 62, 63, 64, 65, 66, After superposing the upper green sheets 67, they are integrated by thermocompression bonding. And it calcinates at 1400-1700 ° C.

  Next, the electrode 76 is formed. An electrode paste containing platinum is screen-printed on the resistance pattern 78 formed on the upper or lower green sheets 61, 67 of the superimposed green sheets 61-67. Then, this is dried, removed from the binder, and baked at about 1400 ° C., thereby forming the electrode 76 connected to the resistance pattern 78. Adjust the resistance value while measuring the resistance value.

  Next, the green sheets 61-67 are separated into pieces. The green sheets 61-67 are divided along the dividing grooves to produce chips, the lead wires are welded to the electrodes 76 formed on each chip, the resistance value adjustment and the welded portion are covered with a reinforcing film and fired. Thus, the temperature sensor element 70 is obtained. The sealing of the resistance pattern 78 is preferably performed with an alumina sintered body 75 from the viewpoint of heat resistance, but may be performed with a glass sintered body as long as the heat resistance can be maintained.

  By producing the temperature sensor element 70 in this manner, the alumina sintered body 11 surrounding the resistance pattern 78 preferably contains 99.70% by mass or more, more preferably 99.99% by mass or more of alumina. The alumina sintered body 11 can be formed. This prevents the sintering aid from reacting with the platinum of the resistance pattern 78 and prevents impurities from reacting with the resistance pattern 78, thereby suppressing the drift of the resistance value of the resistance pattern 78.

  Next, a temperature sensor element 80 according to a third embodiment will be described. In the third embodiment, a protective plate 82 is placed on a resistance pattern 88 formed on a substrate 81. The difference from the first embodiment will be mainly described. FIG. 9 is a cross-sectional view of a temperature sensor element according to the third embodiment. FIG. 9 corresponds to a cross-sectional view taken along line BB in FIG.

  As shown in FIG. 9, in the temperature sensor element 80 according to the third embodiment, the first sintered layer 21 forms a substrate 81 having a resistance pattern 88 formed on the main surface, The sintered layer 24 may form a protection 82 placed on the resistance pattern 88. An electrode 86 is formed on the main surface of the substrate 81, and the electrode 86 and the resistance pattern 88 are connected by a wiring 89. The resistance pattern 88 and the protective plate 82 are sealed with a sintered body 83.

  The sealing of the resistance pattern 88 is preferably performed with an alumina sintered body from the viewpoint of heat resistance, but may be performed with a glass sintered body as long as the heat resistance can be maintained. Since the alumina sintered body has better heat resistance than the glass sintered body and the generation of cracks in the alumina sintered body at high temperatures is suppressed, the resistance pattern 88 is disposed in the alumina sintered body. The platinum of the resistance pattern 88 is prevented from being deteriorated by being exposed to a high-temperature atmosphere.

  Hereinafter, the present embodiment will be described more specifically using examples and comparative examples. This embodiment is not limited at all by the following examples.

  The resistance pattern 18 formed on the ceramic substrate 21 was covered with the protective layer 24, and the temperature sensor element 10 was produced (refer FIG. 5A).

[Ceramics substrate]
A ceramic substrate 21 containing 99.99% by mass or more of alumina was prepared.

[Production of alumina paste]
An alumina paste (1) used for forming the trap layer 22 and an alumina paste (2) used for forming the overcoat layer 23 were prepared. Each alumina paste contains alumina particles having a purity of 99.90-99.99%, and the protective layer 24 (alumina sintered body) obtained by firing contains 93.97% by mass, 94.90 of alumina. Mass%, 98.50 mass%, 98.10 mass%, 99.00 mass%, 99.20 mass%, 99.50 mass%, 99.70 mass%, 99.90 mass%, 99.95 mass% The alumina particles were adjusted so as to contain 99.99% by mass. Further, in each alumina paste, alumina particles having three kinds of average particle diameters within a range of 0.1 to 10.0 μm were mixed together with appropriate amounts of an organic binder and an organic solvent. As the alumina paste (2), alumina particles having an average particle size larger than that of the alumina paste (1) were used. Further, each alumina paste having a purity of 99.50% by mass or more adjusted the content of impurities in the alumina particles and did not add a sintering aid. In the alumina paste of less than 99.20 mass%, the purity was adjusted by adding sintering aids of MgO, SiO ₂ and CaO.

[Fabrication of temperature sensor element]
A platinum film was formed on the surface of the ceramic substrate 21 by sputtering deposition and patterned to form a meander-shaped resistance pattern 18 (see FIGS. 1 and 5A). Then, a pair of electrodes 16 was formed at both ends of the resistance pattern 18. Next, the alumina paste (1) was screen-printed so as to cover the resistance pattern 18 and the pair of electrodes 16, and this was fired to form the trap layer 22. Then, an alumina paste (2) was screen-printed on the trap layer 22 and baked to form an overcoat layer 23. Next, the ceramic substrate 21 was separated into pieces, and lead wires were welded to the pair of electrodes 16 to obtain the temperature sensor element 10.

[Energization test]
The produced alumina sintered body of the protective layer 24 is 93.97 mass%, 94.90 mass%, 98.50 mass%, 98.10 mass%, 99.00 mass%, 99.20 mass% of alumina. %, 99.50% by mass, 99.70% by mass, 99.90% by mass, 99.95% by mass, and 99.99% by mass were used to conduct an energization test. The temperature sensor element 10 was energized, and the resistance value of the resistance pattern 18 was measured in a state where the temperature reached 1100 ° C. and was stable. Using this resistance value as a starting point, the rate of change of the resistance value with time from this resistance value was calculated. The results are shown in FIG. FIG. 10 shows a result of an energization test of the temperature sensor element according to the example.

  The target value is that the change rate of the resistance value of the resistance pattern 18 after 250 hours is less than 2%. The change rate of the resistance value after 62 hours, which is a quarter of the target time, is less than 2% in the temperature sensor element 10 in which the alumina of the protective layer 24 is 99.70% by mass or more. Further, the change rate of the resistance value after 62 hours was less than 0.5% in the temperature sensor element 10 in which the alumina of the protective layer was 99.99% by mass.

  From this result, it was found that the alumina contained in the alumina sintered body of the temperature sensor element 10 is preferably 99.70% by mass or more, and more preferably 99.99% by mass or more. If the alumina of the alumina sintered body is high in purity and does not contain a sintering aid, impurities are prevented from reacting with platinum of the resistance pattern 18 during firing of the alumina particles, and the resistance value of the resistance pattern 18 is reduced. It is possible that the drift was suppressed.

  The result of having observed the cross section of the temperature sensor element 10 whose alumina of the protective layer 24 is 99.99 mass% with the scanning electron microscope is shown in FIG. FIG. 11 is a view showing a temperature sensor element in which the alumina of the alumina sintered body according to the example is 99.99 mass%. As shown in FIG. 11, it was found that the resistance pattern 18 formed on the surface of the ceramic substrate 21 was covered with the trap layer 22, and the overcoat layer 23 was laminated on the trap layer 22. The overcoat layer 23 formed by firing alumina particles having a relatively large average particle diameter has less voids and is densely formed than the trap layer 22 formed by firing alumina particles having a relatively small average particle diameter. I found out.

  FIG. 12 shows a result of magnifying the protective layer 24 of FIG. 11 and observing the alumina particles constituting the protective layer 24 with a scanning electron microscope. FIG. 12 is a diagram illustrating alumina particles constituting a protective layer containing 99.99 mass% alumina according to an example. The right figure and the left figure of FIG. 12 each show another position of the protective layer 24, and alumina particles having an average particle diameter of about 2-3 μm are circled. As shown in FIG. 12, it was observed that the protective layer 24 contained alumina particles having an average particle diameter of about 2-3 μm and alumina particles having an average particle diameter smaller than these alumina particles in the periphery. . It was found that the protective layer 24 was densified by being composed of a plurality of types of alumina particles having different average particle diameters.

  The result of observing the surface of the protective layer 24 is shown in FIG. FIG. 13 is a view of the temperature sensor element observed from above. FIG. 13A shows a temperature sensor element 10 formed from a protective layer 24 containing 99.99% by mass of alumina, and FIG. 13B shows a temperature sensor element formed from a protective layer containing 99.50% by mass of alumina. Show. The dyeing solution was dropped on the protective layer 24 containing 99.99% by mass of alumina and the protective layer containing 99.50% by mass of alumina, and the surface state was observed. As shown in FIG. 13, cracks did not occur on the surface of the protective layer 24 containing 99.99% by mass of alumina, but a plurality of cracks were formed on the surface of the protective layer containing 99.50% by mass of alumina. Had occurred.

  As described above, according to the temperature sensor element 10 of the present embodiment, the alumina of the alumina-based sintered body 11 has a high purity and does not contain a sintering aid. For this reason, the sintering aid does not react with platinum of the resistance pattern 18 during firing of alumina, and impurities contained in the alumina are prevented from reacting with platinum of the resistance pattern 18. Thereby, TCR of platinum is maintained, and resistance value drift of the resistance pattern 18 is suppressed, so that high measurement accuracy is maintained. In addition, the alumina sintered body 11 has better heat resistance than the glass sintered body, and the generation of cracks in the alumina sintered body 11 at high temperatures is suppressed, so that the resistance pattern 18 is contained in the alumina sintered body 11. By disposing, platinum is prevented from being exposed to high temperature air and being deteriorated.

  In the above embodiment, the resistance pattern 18 has a configuration in which a plurality of linear portions extending in the longitudinal direction of the temperature sensor element 10 are arranged in parallel in the short direction at a predetermined interval. In this case, a plurality of linear portions 18a extending in the short direction of the temperature sensor element 10 may be arranged in parallel in the longitudinal direction at a predetermined interval. In addition, the pair of electrodes 16 are arranged at both ends in the lateral direction, but may be arranged at both ends in the longitudinal direction.

  Moreover, although each embodiment of the present invention has been described, as another embodiment of the present invention, the above embodiments may be combined in whole or in part.

  The embodiments of the present invention are not limited to the above-described embodiments, and various changes, substitutions, and modifications may be made without departing from the spirit of the technical idea of the present invention. Furthermore, if the technical idea of the present invention can be realized in another way by technological advancement or another derived technique, the method may be used. Accordingly, the claims cover all embodiments that can be included within the scope of the technical idea of the present invention.

  In the present embodiment, the configuration in which the present invention is applied to a temperature sensor element has been described. However, the present invention can also be applied to other devices in which a resistance pattern made of platinum is sealed with a sintered body.

  As described above, the present invention has the effect of maintaining high measurement accuracy by preventing the reaction between the resistance pattern and the sintering aid, and in particular, a temperature sensor element used for temperature measurement at a high temperature. Useful for.

10 Temperature Sensor Element 11 Alumina Sintered Body 18 Resistance Pattern

Claims (10)

An alumina sintered body, and a resistance pattern disposed inside the alumina sintered body,
The main component of the resistance pattern is platinum,
The alumina sintered body contains 99.70% by mass or more of alumina, does not contain a sintering aid ,
The alumina sintered body includes a first sintered layer and a second sintered layer, and the resistance pattern is arranged between the first sintered layer and the second sintered layer. Is formed,
The first sintered layer forms a substrate having the resistance pattern formed on a main surface, and the second sintered layer is laminated on the main surface of the substrate so as to protect the resistance pattern. Formed protective layer,
The second sintered layer has a trap layer formed so as to cover the resistance pattern, and an overcoat layer formed so as to cover the trap layer,
The temperature sensor element , wherein an average particle diameter of the alumina particles constituting the overcoat layer is larger than an average particle diameter of the alumina particles constituting the trap layer . The temperature sensor element according to claim 1 , wherein the trap layer contains platinum in an amount of 2% by volume to 30% by volume. An alumina sintered body, and a resistance pattern disposed inside the alumina sintered body,
The main component of the resistance pattern is platinum,
The alumina sintered body contains 99.70% by mass or more of alumina, does not contain a sintering aid,
The alumina sintered body includes a first sintered layer and a second sintered layer, and the resistance pattern is arranged between the first sintered layer and the second sintered layer. Is formed,
The first sintered layer forms a substrate having the resistance pattern formed on a main surface, and the second sintered layer is laminated on the main surface of the substrate so as to protect the resistance pattern. Formed protective layer,
The second sintered layer has a trap layer formed so as to cover the resistance pattern, and an overcoat layer formed so as to cover the trap layer,
The trap layer has a first trap layer formed so as to cover the resistance pattern, and a second trap layer stacked on the first trap layer,
The temperature sensor element, wherein the first trap layer contains platinum at a lower content than the second trap layer. Said first trap layer is platinum containing 10% by volume or less 0% by volume or more, the second trap layer to claim 3, characterized in that it contains platinum than 30 vol% 2 vol% The temperature sensor element described. At least one of the first sintered layer and the second sintered layer is composed of alumina particles having a plurality of different average particle diameters having an average particle diameter of 0.1 to 10.0 μm. The temperature sensor element according to any one of claims 1 to 4 . The temperature sensor element according to claim 5 , wherein the alumina particles are composed of alumina particles having an average particle diameter of at least three kinds. The alumina contained in at least one of the first sintered layer and the second sintered layer is 99.99% by mass or more, according to any one of claims 1 to 6. The temperature sensor element described. The temperature sensor element according to any one of claims 1 to 7 , wherein no crack is formed in the alumina sintered body. A substrate made of an alumina sintered body containing 99.70% by mass or more of alumina and containing no sintering aid;
A resistance pattern made of a platinum film formed on the main surface of the substrate;
A protective layer made of an alumina sintered body that is formed on the main surface so as to protect the resistance pattern, contains 99.70% by mass or more of alumina, and does not contain a sintering aid;
The protective layer has a trap layer covering the entire surface of the resistance pattern, and an overcoat layer covering the surface of the trap layer,
The trap layer and the periphery of the overcoat layer are in close contact with the main surface, respectively.
The trap layer contains platinum at a position away from the resistance pattern,
The temperature sensor element, wherein the overcoat layer has a larger average particle diameter of alumina particles and fewer voids than the trap layer. A temperature sensor element formed by firing a laminate having a plurality of green sheets and a plurality of resistance patterns disposed between the green sheets,
The alumina sintered body obtained by firing a green sheet of alumina contains more than 99.70 mass%, not containing sintering aid,
The resistance pattern is made of a platinum film,
The average particle size of the alumina particles contained in the alumina sintered body, the temperature sensor element, characterized in that it increases from the inner layer as it goes to the upper and lower layers.