The present application claims the benefit of Japanese Patent Application No. 2004-211818 filed on Jul. 20, 2004 and Japanese Patent Application No. 2005-7456 filed on Jan. 14, 2005, the disclosures of which are incorporated herein by reference.
1. Technical Field of the Invention
The present invention relates generally to an improved sealing of a ceramic heater designed to be built in a gas sensor which may work to measure the concentration of a given component of exhaust emissions from an automotive engine.
2. Background Art
The gas sensor 60 has installed therein a ceramic heater 9 for heating a sensor element 65 up to a desired activation temperature. The ceramic heater 9, as illustrated in
Referring back to
However, in recent years, the temperature of exhaust gas of automotive engines has been increased in order to meet tightened legal requirements of emission control, thus resulting in increased thermal loads on the sealant 631 of the ceramic heater 9, which gives rise to a degrease in degree of air-tightness between the housing 65 and the sensor element 65. This causes the exhaust gasses to leak into the air chamber 620 so that corrosion-causing substances, such as nitrogen oxides, contained in the exhaust gasses reach the terminals 931 of the ceramic heater 9. Additionally, moisture contained in the exhaust gasses may be adhered to the ceramic heater 9 or condensed during stop of the engine, thereby resulting in corrosion of the joints 913 of the terminals 931 and the leads 941 and, in the worst case, disconnections therebetween.
It is therefore a principal object of the invention to avoid the disadvantages of the prior art.
It is another object of the invention to provide an improved sealing structure of a ceramic heater designed to ensure the durability thereof.
According to one aspect of the invention, there is provided a ceramic heater which may be used in heating a sensor element of a gas sensor to a desired activation temperature. The ceramic heater comprises: (a) a ceramic body; (b) a pair of electrical conductors formed on the ceramic body, each of the conductors is equipped with a terminal; (c) leads joined to the terminals of the conductors for supplying electrical power to the conductors; and (d) a seal covering joints between the leads and the terminals of the conductors hermetically. Use of the seal avoids direct contact with the joints of the leads and the terminals with corrosion-causing substances or moisture contained in gassed to be measured by the gas sensor and also avoids the formation of electrolytes resulting from adhesion of corrosion-causing matters to the joints during production of the ceramic heater. This avoids the corrosion of the joints and, in the worst case, physical separation of the leads from the terminals.
In the preferred mode of the invention, the seal covers a whole of the terminals of the conductors to enhance the avoidance of corrosion of the joints.
The seal may be made of glass in order to offer the resistance to high temperatures in a case where the gas sensor is high in an operating temperature thereof or used in high temperature environments. The glass may be either crystallized or uncrystallized. The seal may alternatively be made of resin in a case where the gas sensor is lower in the operating temperature.
The seal has preferably a coefficient of thermal expansion within a range of ±15×10−7/° C. and more preferably of ±10×10−7/° C. of that of the heater body in order to reduce a difference in thermal expansion between the heater body and the seal during usage of the ceramic heater to avoid cracks in the seal.
For example, when the heater body is made of alumina (Al2O3) and has a coefficient of thermal expansion of 60×10−7/° C., the seal preferably has a coefficient of thermal expansion of 45-75×10−7/° C. and more preferably 50-70×10−7/° C. Alternatively, when the heater body is made of silicon nitride (Si3N4) and has a coefficient of thermal expansion of 25×10−7/° C., the seal preferably has a coefficient of thermal expansion of 10-40×10−7/° C. and more preferably 15-35×10−7/° C.
The seal may have a glass transition temperature of 400° C. or more and a welding temperature of 900° C. or less, thereby ensuring the durability thereof and air- and liquid-tight sealing of the joints of the terminals and the leads without any adverse impact thereon. Specifically, a maximum operating temperature of the gas sensor is usually 400° C. Therefore, as long as the glass transition temperature of the seal 5 is 400° C. or more, it will keep the seal solid during usage of the gas sensor. When the welding temperature of the seal is more than 900° C., it may cause the joints between the terminals and the leads to be fused and also result in a decrease in joint strength between the terminals and the heater body.
The seal has preferably a coefficient of thermal expansion within a range of ±15×10−7/° C. and more preferably ±10×10−7/° C. of that of the leads, thereby reducing a difference in thermal expansion between the leads and the seal during usage of the gas sensor to avoid cracks in the seal.
The leads may be made of one of 42 alloy and kovar. In this case, the coefficient of thermal expansion of the leads may be approximated to that of the seal in order to reduce a difference in thermal expansion between the leads and the seal during usage of the ceramic heater to minimize cracks in an interface of the seal with the leads.
The ceramic heater may further include a holder which retains therein the seal to keep a configuration thereof in a desired shape. The holder may be made of alumina or mullite.
The present invention will be understood more fully from the detailed description given hereinbelow and from the accompanying drawings of the preferred embodiments of the invention, which, however, should not be taken to limit the invention to the specific embodiments but are for the purpose of explanation and understanding only.
In the drawings:
Referring to the drawings, wherein like reference numbers refer to like parts in several views, particularly to
The ceramic heater 1 is essentially made up of a bar-shaped ceramic heater body 2 and a pair of heater conductors 3 equipped with terminals 31 attached to an end portion of the heater body 2. To the terminals 31, leads 41 are connected through joints 13 for supplying electrical power to the heater conductors 3. The joints 13 are covered with a glass seal 5.
The glass seal 5, as can be seen from FIGS. 1 to 3, covers the whole of the terminals 31. The glass seal 5 has a coefficient of thermal expansion lying in a range of ±15×10−7/° C. and preferably ±10×10−7° C. of that of the heater body 2. For example, when the heater body 2 is made of alumina (Al2O3) and has a coefficient of thermal expansion of 60×10−7/° C., the glass seal 5 preferably has a coefficient of thermal expansion of 45-75×10−7/° C. and more preferably 50-70×10−7/° C. Alternatively, when the heater body 2 is made of silicon nitride (Si3N4) and has a coefficient of thermal expansion of 25×10−7/° C., the glass seal 5 preferably has a coefficient of thermal expansion of 10-40×10−7/° C. and more preferably 15-35×10−7/° C.
The glass seal 5 has a glass transition temperature of 400° C. or more and a welding temperature of 900° C. or less.
Each of the leads 41 is, as clearly illustrated in
The heater body 2 is of a substantially cylindrical shape and made up of a ceramic core bar 21 and a ceramic sheet 22 wrapped round the periphery of the core bar 21. The ceramic sheet 22 has formed therein the heater conductors 3 each of which, as shown in
The terminals 31 are diametrically opposed to each other on an end portion 12 of the circumference of the heater body 2. The leads 41 are, as described above, joined to the terminals 31 through the brazing metals 11, respectively. The glass seal 5 is formed around the whole of the circumference of the end portion 12 to surround the joints 13 of the terminals 13 and the leads 41 hermetically.
The sealing of the joints 13 with the glass seal 5 is achieved by applying a glass paste over the joints 13 or putting a prebaked glass in a mold and welding it to the joints 13 at, for example, 750° C. within a tunnel furnace or a batch furnace. The sealing may alternatively be made by placing the end portion 12 of the ceramic heater 1 on which the joints 13 are formed within a mold, leading a sealing material into the mold, cooling the mold to solidify to the sealing material, and removing the end portion 12 from the mold.
The ceramic heater 1, as described above, may be built in a gas sensor such as the one illustrated in
The gas sensor 6 of
The protective cover assembly 61 has defined therein a gas chamber 610 into which gases such as exhaust emissions from an automotive engine are admitted. The gas sensor element 65 is exposed to the gas chamber 610 and works to produce a signal as a function of concentration of oxygen contained in the gasses. The air cover 62 has defined therein an air chamber 620 into which the atmospheric air is admitted. The air chamber 620 leads to inside the gas sensor element 65.
A powder seal 631 and an insulator 632 are disposed between an inner wall of the housing 68 and an outer wall of the gas sensor element 65 to form a hermetical seal therebetween. A ring gasket 634 is disposed on the end of the insulator 632. The annular end of the housing 68 is crimped inwardly to urge the ring gasket 634 into constant abutment with the insulator 632 to enhance the degree of sealing between the housing 68 and the gas sensor element 65.
The gas sensor element 65 consists of a bottomed hollow cylindrical solid electrolyte body 69 and an inner and an outer electrode (not shown) affixed to an inner and an outer surface of the solid electrolyte body 69. The ceramic heater 1 is disposed inside the solid electrolyte body 69.
Terminals 671 and 672 are affixed to the gas sensor element 65 and electrically lead to the inner and outer electrodes. The terminals 671 and 672 are also jointed to external leads 603 and 604.
The leads 41 of the ceramic heater 1 are connected to external leads 601 (only one is shown for the brevity of illustration), respectively.
The ceramic heater 1 is, as described above, covered hermetically at the joints 13 of the terminals 31 and the leads 41 with the glass seal 5, thus avoiding directly contact of the joints 13 with moisture or substances contained in the exhaust emissions of the engine which give rise to corrosion of the joints 13.
The operation of the gas sensor 6 where it is installed in an exhaust pipe of an automotive engine will be described below.
The fresh air enters inside the air cover 62 through a water-repellent filter 622.
Upon start of the engine, the gas sensor 6 starts to measure the concentration of oxygen contained in exhaust gasses from the engine. The exhaust gasses enters the protective cover assembly 61. The part of the exhaust gasses may leak through the powder seal 631 and the insulator 632 and reach the joints 13 of the terminals 31 and the leads 41 of the ceramic heater 1. The joints 13 are, however, covered completely by the glass seal 5, thus avoiding direct contact thereof with the exhaust gasses which can give rise to the corrosion of the joints 13.
The glass seal 5 also serves to avoid any defects of the ceramic heater 1 arising from corrosion-causing chemicals adhered to the joints 13 during production of the ceramic heater 1. For example, in the plating treatment the ceramic heater 1 usually undergoes during production processes, chlorine may stick to and stay on the joints 13. If the water is mixed with the chlorine, it will produce electrolyte, which may result in corrosion of the joints 13. In the worst case, it cause the leads 41 to be separated from the terminals 31. The glass seal 5 serves to avoid such a problem and ensures the durability of the ceramic heater 1.
The glass seal 5, as described above, covers the whole of the terminals 31, thus enhancing the avoidance of corrosion of the joints 13 to improve the durability of the ceramic heater 1.
The glass seal 5 offers the resistance to high temperatures in the nature of material thereof, thus ensuring the joint strength of the terminals 31 and the leads 41 in high-temperature environments.
The glass seal 5, as described above, has a coefficient of thermal expansion lying in a range of ±15×10−7/° C. of that of the heater body 2, thereby reducing a difference in thermal expansion between the heater body 2 and the seal 5 during usage of the ceramic heater 1 to minimize cracks in the seal 5.
The glass seal 5 has a glass transition temperature of 400° C. or more and a welding temperature of 900° C. or less, thereby ensuring the durability thereof and air- and liquid-tight sealing of the joints 13 of the terminals 31 and the leads 41 without any adverse impact thereon. Specifically, the melting point of the brazing metals 11 is approximately 950 to 970° C. Thus, as long as the welding temperature of the seal 5 is 900° C. or less, the brazing metals 11 will not be fused during welding of the seal 5 to the heater body 2. A maximum operating temperature of the gas sensor 6 is usually 400° C. Therefore, as long as the glass transition temperature of the seal 5 is 400° C. or more, it will keep the seal 5 solid during usage of the gas sensor 6.
Specifically, the holder 51 is, as clearly illustrated in
The ceramic heater 1 of the third embodiment will be described below.
The ceramic heater 1 has the leads 41 made of 42 alloy or kovar. The 42 alloy is an alloy of Ni and Fe and has a coefficient of thermal expansion of 45 to 65×10−7/° C. The kovar is an alloy of Ni, CO, and Fe and has a coefficient of thermal expansion of 45 to 65×10−7/° C.
The heater body 2 is made of alumina. The seal 5 is made of glass. Other arrangements are identical with those in the first embodiment.
The coefficient of thermal expansion of the glass seal 5 is within a range of ±15×10−7/° C. of that of the leads 41 and may also be selected to be within a range of ±10×10−7/° C. closer to that of the leads 41. Specifically, in a case where the coefficient of thermal expansion of the heater body 2 made of alumina is, as described above, 60×10−7/° C., the glass seal 5 preferably has a coefficient of thermal expansion of 45-75×10−7/° C. and more preferably of 50-70×10−7/° C. In this case, the coefficient of thermal expansion of the leads 41 may be approximated to that of the glass seal 5 by making the leads 41 of 42 alloy in order to reduce a difference in thermal expansion between the leads 41 and the glass seal 5 during usage of the ceramic heater 1 to minimize cracks in the interface of the seal 5 with the leads 41.
In a case where the ceramic heater 1 is built in a gas sensor to be used at a lower operating temperature of 300 to 350° C., the joints 13 of the terminals 31 and the leads 41 may alternatively be covered with resin such as polyimide resin instead of the glass seal 5.
The seal 5 needs not necessarily cover the whole of the terminals 31 of the heater conductors 3 and may cover at least the joints 13 between the terminals 31 and the leads 41. In the first embodiment, the seal 5 may cover at least the joint interface 111 between the brazing metals 11 and the leads 41.
While the present invention has been disclosed in terms of the preferred embodiments in order to facilitate better understanding thereof, it should be appreciated that the invention can be embodied in various ways without departing from the principle of the invention. Therefore, the invention should be understood to include all possible embodiments and modifications to the shown embodiments which can be embodied without departing from the principle of the invention as set forth in the appended claims.
Number | Date | Country | Kind |
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2004-211818 | Jul 2004 | JP | national |
2005-007456 | Jan 2005 | JP | national |