The present invention relates to a heater used as, for example, a heater for ignition or flame sensing in a combustion type in-vehicle heating apparatus, a heater for ignition of various types of combustion appliances such as an oil fan heater, a heater for a glow plug of a diesel engine, a heater for various sensors such as an oxygen sensor, or a heater for heating of a measuring instrument, and a glow plug including the same.
As a heater, a heater described in, for example, Japanese Unexamined Patent Publication JP-A 2015-18625 (hereinafter, also referred to as “Patent Literature 1”) is known. The heater described in Patent Literature 1 includes a ceramic body and a heat generating resistor provided within the ceramic body. The heat generating resistor has two straight line sections and a folded section which connects the two straight line sections. In recent years, improvement of a rate of temperature rise has been demanded of a heater.
In a cross section of the heater described in Patent Literature 1 perpendicular to an axial direction of the two straight line sections, the two straight line sections each have a shape having a major axis and these major axes are in a parallel relationship. Furthermore, a centroid of the two straight line sections is located on a line dividing the ceramic body in half. Owing to this, heat generated from the two straight line sections is prone to be confined in an intermediate portion between the two straight line sections in the ceramic body. As a result, it has been difficult to improve a rate of temperature rise of a surface of the ceramic body that is to come in contact with an object to be heated.
A heater includes: a ceramic body having a rod-like shape; and a heat generating resistor embedded in the ceramic body, the heat generating resistor comprising a first straight line section, a second straight line section which is disposed alongside the first straight line section, and a folded section which connects the first straight line section and the second straight line section, in a cross section of the heater taken along a plane which passes through the first straight line section and which is perpendicular to an axial direction of the ceramic body, the first straight line section having a shape having a first major axis, the second straight line section having a shape having a second major axis, the second major axis being inclined with respect to the first major axis, a centroid of the first straight line section and the second straight line section being deviated from a centroid of the ceramic body to a side on which a distance between the first major axis and the second major axis is narrower.
As illustrated in
The ceramic body 2 in the heater 1 is, for example, a rod-like ceramic body having a longitudinal direction (an axial direction). The heat generating resistor 3 and the leads 4 are embedded in this ceramic body 2. Herein, the ceramic body 2 is formed of ceramics. This makes it possible to provide the heater 1 having high reliability at a time of rapid temperature rise. Examples of ceramics include electrically insulating ceramics such as oxide ceramics, nitride ceramics, and carbide ceramics. The ceramic body 2 may be formed of silicon nitride ceramics. Silicon nitride, which is a main component of silicon nitride ceramics, is excellent in strength, toughness, insulation, and heat resistance.
The ceramic body 2 formed of silicon nitride ceramics can be produced through, for example, the following method. Specifically, a sintering aid, A12O3, and SiO2 are mixed into silicon nitride serving as the main component to obtain a mixture. The mixture is molded into a predetermined shape to obtain a molded body. Subsequently, by subjecting the molded body to hot press firing at 1650 to 1780° C., the ceramic body 2 can be obtained. As the sintering aid, a rare-earth element oxide such as 3 to 12% by mass of Y2O3, Yb2O3, or Er2O3 can be used. As Al2O3, 0.5 to 3% by mass of Al2O3, for example, can be used. SiO2 can be mixed so that 1.5 to 5% by mass of SiO2 is contained in the ceramic body 2. A length of the ceramic body 2 is set to, for example, 20 to 50 mm, and a diameter of the ceramic body 2 is set to, for example, 3 to 5 mm.
It is noted that, when the ceramic body 2 formed of silicon nitride ceramics is used, MoSiO2, WSi2, or the like may be mixed and dispersed into silicon nitride. In this case, a coefficient of thermal expansion of silicon nitride ceramics which is a base material can be made closer to a coefficient of thermal expansion of the heat generating resistor 3. As a result, durability of the heater 1 can be improved.
The heat generating resistor 3 is disposed inside the ceramic body 2. The heat generating resistor 3 is disposed on a tip end side (one end side) of the ceramic body 2. The heat generating resistor 3 is a member which generates heat by carrying a current thereto. The heat generating resistor 3 comprises a first straight line section 31a and a second straight line section 31b which extend along the longitudinal direction of the ceramic body 2, and a folded section 32 which connects these straight line sections.
The first straight line section 31a and the second straight line section 31b are disposed alongside each other. “Being disposed alongside” used herein is not necessarily being parallel in a strict sense. Specifically, the first straight line section 31a and the second straight line section 31b may be located, for example, in such a manner that a distance between the first straight line section 31a and the second straight line section 31b is narrower as the first straight line section 31a and the second straight line section 31b are closer to the folded section 32.
As a material for forming the heat generating resistor 3, a material which contains a carbide, a nitride, a silicide, or the like of W, Mo, Ti, or the like can be used.
Moreover, when the ceramic body 2 is formed of silicon nitride ceramics, the heat generating resistor 3 may contain WC, which is an inorganic electrical conductor, as the main component, and a content of silicon nitride added to WC may be equal to or higher than 20% by mass. Since a conductor component which becomes the heat generating resistor 3 is higher in coefficient of thermal expansion than silicon nitride in the ceramic body 2 formed of, for example, silicon nitride ceramics, the heat generating resistor 3 is normally in a state in which a tensile stress is applied thereto. On the other hand, by adding silicon nitride into the heat generating resistor 3, it is possible to make the coefficient of thermal expansion of the heat generating resistor 3 closer to that of the ceramic body 2 and to alleviate the stress due to a difference in the coefficient of thermal expansion between the heat generating resistor 3 and the ceramic body 2 at a time of temperature rise and temperature drop of the heater 1.
Furthermore, when the content of silicon nitride contained in the heat generating resistor 3 is equal to or lower than 40% by mass, it is possible to reduce the variation in a resistance value of the heat generating resistor 3. Therefore, the content of silicon nitride contained in the heat generating resistor 3 may be 20 to 40% by mass. Moreover, 4 to 12% by mass of boron nitride can be added, as a similar additive, to the heat generating resistor 3 instead of silicon nitride. A total length of the heat generating resistor 3 can be set to 3 to 15 mm and a cross-sectional area thereof can be set to 0.15 to 0.8 mm2.
The leads 4 are members for electrically connecting the heat generating resistor 3 to an external power supply. The leads 4 are connected to the heat generating resistor 3 and drawn out to the surface of the ceramic body 2. Specifically, the leads 4 are joined to two end portions of the heat generating resistor 3. One of the leads 4 is connected, on one end side, to one end of the heat generating resistor 3 and is led out, on the other end side, from a side surface of the ceramic body 2 which is closer to a rear end of the ceramic body 2. The other lead 4 is connected, on one end side, to the other end of the heat generating resistor 3 and is led out, on the other end side, from a rear end portion of the ceramic body 2.
The leads 4 are formed of, for example, a similar material to that of the heat generating resistor 3. By making a cross-sectional area of the leads 4 larger than that of the heat generating resistor 3 and making a content of the material for forming the ceramic body 2 lower than that of the material for forming the heat generating resistor 3, a resistance value per unit length of the leads 4 is reduced. Furthermore, the leads 4 may contain WC, which is the inorganic electrical conductor, as a main component, and silicon nitride may be added to the main component so that a content of silicon nitride is equal to or higher than 15% by mass. This can make a coefficient of thermal expansion of the leads 4 closer to that of silicon nitride configuring the ceramic body 2.
Now, as illustrated in
Specifically, it is possible to easily increase a temperature on the side on which the distance between the first major axis X and the second major axis Y is narrower in the ceramic body 2. Furthermore, by deviating the centroid Gr of the first straight line section 31a and the second straight line section 31b from the centroid Gc of the ceramic body 2 to the side on which the distance between the first major axis X and the second major axis Y is narrower, it is possible to easily increase a temperature of a region located on the side on which the distance between the first major axis X and the second major axis Y is narrower on the surface of the ceramic body 2. These results indicate that a temperature of a surface of the heater 1 can be rapidly increased.
A cross-sectional shape of each of the first straight line section 31a and the second straight line section 31b can be set to, for example, an oval shape or an elliptical shape. The first major axis X means herein a major axis of the cross-sectional shape of the first straight line section 31a, and the second major axis Y means herein a major axis of the cross-sectional shape of the second straight line section 31b. It is noted that the oval shape, the elliptical shape, or the like is not completely an oval shape, an elliptical shape, or the like and may have stepped portions or irregular portions to a certain extent. The first straight line section 31a and the second straight line section 31b can be deviated by, for example, about 5 to 30°.
As for the “centroid Gr of the first straight line section 31a and the second straight line section 31b”, a midpoint of a virtual line which connects a centroid G1 of the cross-sectional shape to a centroid G2 of the cross-sectional shape of the second straight line section 31b can be defined as the centroid Gr of the first straight line section 31a and the second straight line section 31b.
In addition, “being deviated to the side on which the distance between the first major axis X and the second major axis Y is narrower” means that the centroid Gr of the first straight line section 31a and the second straight line section 31b is deviated from the centroid Gc of the cross section of the ceramic body 2 to the side on which the distance between the first major axis X and the second major axis Y is narrower (a side on which extension lines of the first major axis X and the second major axis Y intersect each other) as viewed in a direction perpendicular to an arrangement direction of the first straight line section 31a and the second straight line section 31b. In other words, the centroid Gr of the first straight line section 31a and the second straight line section 31b may be deviated in the direction perpendicular to the arrangement direction and may be either completely deviated or not at all deviated in the arrangement direction.
When the cross-sectional shape of the ceramic body 2 is, for example, a circular shape, the centroid Gr of the first straight line section 31a and the second straight line section 31b can be deviated by, for example, 5 to 40% with respect to a diameter of the ceramic body 2.
Furthermore, as illustrated in
Moreover, the inclination of the second major axis Y with respect to the first major axis X may be higher as the first straight line section 31a and the second straight line section 31b are farther from the folded section 32. An interface between the first straight line section 31a and the ceramic body 2 and an interface between the second straight line section 31b and the ceramic body 2 can be each made into a twisted shape. Therefore, even when cracking occurs to the interfaces, it is possible to suppress the development of the cracking. This makes it possible to improve long-term reliability of the heater 1.
On tip ends of the first straight line section 31a and the second straight line section 31b, an inclination θa of the second major axis Y with respect to the first major axis X can be set to, for example, 5°. Furthermore, on rear ends of the first straight line section 31a and the second straight line section 31b, an inclination θb of the second major axis Y with respect to the first major axis X can be set to, for example, 30°.
Moreover, when the folded section 32 is viewed at this time, the folded section 32 has a major axis, as well. In addition, as illustrated in
Furthermore, a point at which the first major axis X and the second major axis Y intersect each other may be located inward of the surface of the ceramic body 2. This can further improve the rate of temperature rise of the surface of the ceramic body 2.
Moreover, in
As illustrated in
The metal cylinder 5 is a member for holding the ceramic body 2. The metal cylinder 5 is a cylindrical member and is attached so as to surround a rear end side of the ceramic body 2. In other words, the rod-like ceramic body 2 is inserted into the cylindrical metal cylinder 5. The metal cylinder 5 is electrically connected to a lead 4-exposed portion which is located on a side surface near the rear end side of the ceramic body 2. The metal cylinder 5 is formed of, for example, a stainless steel or iron (Fe)-nickel (Ni)-cobalt (Co) alloy.
The metal cylinder 5 is bonded to the ceramic body 2 by a brazing material. The brazing material is disposed between the metal cylinder 5 and the ceramic body 2 so as to surround the rear end side of the ceramic body 2. By disposing this brazing material, the metal cylinder 5 and the leads 4 are electrically connected to each other.
As the brazing material, a silver (Ag)—copper (Cu) brazing material, an Ag brazing material, a Cu brazing material, or the like containing 5 to 20% by mass of a glass component can be used. The glass component has an excellent wettability with ceramics of the ceramic body 2 and a high coefficient of friction; thus, the glass component can improve a bonding strength between the brazing material and the ceramic body 2 or a bonding strength between the brazing material and the metal cylinder 5.
The electrode fitting 6 is located inside the metal cylinder 5 and is attached to the rear end of the ceramic body 2 so as to be electrically connected to the lead 4. While the electrode fitting 6 in various forms can be used, in an example illustrated in
The electrode fitting 6 is a metallic wire having the coiled section provided to alleviate a stress in connection to the external power supply. The electrode fitting 6 is electrically connected to the lead 4 and is also electrically connected to the external power supply. By applying a voltage between the metal cylinder 5 and the electrode fitting 6 by the external power supply, a current can be carried to the heat generating resistor 3 via the metal cylinder 5 and the electrode fitting 6. The electrode fitting 6 is formed of, for example, nickel or stainless steel.
The heater 1 can be formed by, for example, an injection molding method or otherwise using molds of the shapes of the heat generating resistor 3, the leads 4, and the ceramic body 2 configured as described above. As for the heat generating resistor 3, a molded body which has the two straight line sections 31a and 31b having the first major axis X and the second major axis Y parallel to each other and the folded section 32 is first prepared. A pressure is then applied to rear end sides of the two straight line sections 31a and 31b (a side on which the two straight line sections 31a and 31b are not connected to the folded section 32) so that the second major axis Y is inclined with respect to the first major axis X in a state of fixing the folded section 32. In this way, it is possible to obtain the heat generating resistor 3 which has the second major axis Y inclined with respect to the first major axis X and which has a higher inclination as the first straight line section 31a and the second straight line section 31b are farther from the folded section 32.
1: Heater
2: Ceramic body
3: Heat generating resistor
31
a: First straight line section
31
b: Second straight line section
32: Folded section
4: Lead
5: Metal cylinder
6: Electrode fitting
10: Glow plug
X: First major axis
Y: Second major axis
Number | Date | Country | Kind |
---|---|---|---|
2015-232035 | Nov 2015 | JP | national |
Filing Document | Filing Date | Country | Kind |
---|---|---|---|
PCT/JP2016/078676 | 9/28/2016 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO2017/090313 | 6/1/2017 | WO | A |
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Number | Date | Country |
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2015-018625 | Jan 2015 | JP |
Number | Date | Country | |
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20180310364 A1 | Oct 2018 | US |