JP3880275B2 - Ceramic heater and glow plug using the ceramic heater - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a ceramic heater used in a glow plug for a diesel engine and a glow plug in which the ceramic heater is used. More specifically, the present invention relates to a technique for bringing the portion of the surface of the ceramic heater that is at the maximum temperature due to resistance heat generation by a ceramic heating element disposed in the ceramic heater to the tip.
[0002]
[Prior art]
2. Description of the Related Art Conventionally, ceramic heaters used for ceramic glow plugs have a structure in which an insulating ceramic base is embedded with a ceramic heating element having a U-shaped direction changing portion that generates resistance when energized. Yes. In the ceramic heating element, one end of a linear electrode is embedded on the end side for energization. This ceramic heater is manufactured as follows, for example. That is, first, an integral molded body of a U-shaped conductive ceramic powder molded body that becomes a ceramic heating element after firing and an electrode is formed by injection molding or the like. At this time, the U-shaped portion is formed in a rod shape having substantially the same outer diameter. On the other hand, a separate preform for forming a ceramic base after firing is formed by press molding or the like using the base ceramic powder. Next, the integral molded body is accommodated in the concave portion, the divided preforms are molded, and then these are pressed and integrated using a mold to obtain a composite molded body. Here, the pressing direction is set substantially perpendicular to the mating surface of the divided preform. The composite molded body thus obtained is subjected to a hot press treatment in which firing is performed while pressing in the direction perpendicular to the pressing direction, that is, the mating surface direction, and the outer peripheral surface of the obtained fired body is polished. Thus, a ceramic heater is obtained.
[0003]
The ceramic heater manufactured by hot pressing in this way has a shape in which the internal ceramic heating element is crushed in the pressing direction during hot pressing. However, the top of the U-shaped direction changing portion is similar to the shape of the conductive ceramic powder compact before firing because the pressing direction is perpendicular to the cross section. That is, since it is formed in a U-shaped rod shape before firing, it remains circular even after hot press firing.
[0004]
[Problems to be solved by the invention]
As a result of FEM analysis of the heat generation state of the ceramic heating element in the conventional ceramic heater as described above, it can be seen that concentrated heat is generated in a local minute portion on the inner diameter side of the top of the U-shaped direction changing portion. It was found that heat was not generated at all from the middle of the top of the letter-shaped direction changing portion to the outer diameter side. For this reason, on the surface of the ceramic heater, the portion at which the maximum temperature is reached is not the tip, but the portion close to the end portion where one end of the linear electrode is embedded is at the maximum temperature. As a result, the temperature rise characteristics at the tip of the ceramic heater are slightly inferior, wasteful power is consumed, and heat is concentrated in a small local area, so there is a high possibility that a crack will occur in that area. Problems with durability are anticipated.
[0005]
As an example, FIG. 14 and FIG. 15 show the results of calculating the tip temperature distribution of a conventional ceramic heater by FEM analysis. FIG. 15 shows the calorific value distribution per unit volume when the cross section inside the ceramic heater is taken. The low calorific value is shown in black, and the calorific value increases as it becomes white. ing. According to this analysis result, it is considered that only the inner diameter side of the top portion generates heat, so that heat diffuses from this portion to each portion. FIG. 14 shows the distance along the surface from the position to the end portion from the position where the horizontal axis is the most advanced position 0 of the ceramic heater, and the vertical axis shows the temperature at that distance. From this analysis result, as described above, it can be seen that the portion of the ceramic heater surface where the maximum temperature is reached is not the tip but a portion near the end.
[0006]
An object of the present invention is to prevent a local heat generation of a ceramic heating element disposed in a ceramic heater and to have a superior durability in which the tip surface of the ceramic heater has a maximum temperature, and such a ceramic heater. It is to provide a glow plug that uses.
[0010]
[Means for solving the problems and actions / effects]
FirstThe ceramic heater of the present invention is a ceramic heater comprising an axial rod-shaped ceramic base, and a ceramic heating element embedded in the ceramic base and generating resistance heat when energized from its end side. The heating element includes a U-shaped direction changing portion, and has a portion in which the width b ′ on the base side of the top cross-sectional shape of the direction changing portion satisfies the relationship of b> b ′. Features.
[0011]
  As described above, the ceramic heating element disposed in the ceramic heater having the conventional structure has the U-shaped portion formed into a rod shape having substantially the same diameter before firing. Therefore, the width of the U-shaped portion after firing is also the same. Was almost constant. For this reason, in the top part which becomes a circular section after baking, it generates heat locally on the inner diameter side. As a method to increase the inner diameter areaThe topEven if the cross-sectional shape of the section is circular,1Method for increasing the area at the top as in the inventionIs. Thus, than the width b at the top of the direction changerBaseThe above-mentioned problem can be solved by satisfying the relation b> b 'of the width b' on the part side. The cross-sectional shape at the top is not necessarily limited to a circle, and any shape may be used as long as the effect of the present invention is achieved..
[0012]
  Next2The ceramic heater of the present invention is a ceramic heater comprising an axial rod-shaped ceramic base, and a ceramic heating element embedded in the ceramic base and generating resistance heat when energized from its end side. The body includes a U-shaped direction changing portion, and includes an end portion side contour line in a range of the center 60% of the width b in the top cross-sectional shape of the direction changing portion, and a tangent line at the center of the end portion side contour line. The area formed by the virtual circle and the tangent in the range of 60% of the center when the virtual circle having a diameter of width b and the area A formed by A ′ has a portion that satisfies the relationship of A ′> A. By adopting such a configuration, it is possible to increase the area on the inner diameter side, particularly in the range of the center 60% where local heat generation is likely to occur. Note that the cross-sectional shape at the top may be any shape as long as the effects of the present invention are achieved. For example, it may be a rectangle, a square, or an oval shape. Moreover, the shape as shown in FIG. 9 may be used. Further, the first inventionWhenFirst2inventionWhenEven if it is the shape which combined these, the effect of this invention can be improved further.
[0013]
  Next3In the ceramic heater of the invention, the top cross-sectional shape is such that the end side outline in the range of the center 60% of the width is formed by a single line or two straight lines, and is constituted by two straight lines Is characterized in that the included angle α is 160 ° ≦ α <180 °. The present invention prescribes a straight sandwiching angle α when the rhombus apex as shown in FIG. 7 is formed into an R shape or as shown in FIG. When the end side outline is formed by a single straight line, it is considered that the included angle α = 180 °, and therefore α can be considered as 160 ° ≦ α ≦ 180 °. By adopting such a configuration, the area on the inner diameter side of the top portion where local heat generation is performed can be further increased, so that the effect of the present invention can be more easily achieved. Moreover, since the U-shaped conductive ceramic powder molded body and the electrode, which are ceramic heating elements after firing, are formed by injection molding or the like, it is preferable to make a taper from the viewpoint of work. Since the draft taper is considered to require about 1 °, the opening angle α of the end side outline is preferably α ≦ 178 °. From the first invention to the first3Even if it is the shape which combined any two or more of invention, the effect of this invention can be improved further.
[0015]
  Ceramic heater with a small tipCeramic heater arranged so that the top of the direction changing part of the ceramic heating element is located in the tip of the heaterThe portion formed in a small diameter becomes the maximum temperature of the surface of the ceramic heater due to the resistance heating of the ceramic heating element as described above. Therefore, it is possible to improve the temperature rise characteristic at the tip of the ceramic heater and to suppress wasteful power consumption.
[0016]
If a ceramic heater as described above is used for a glow plug for a diesel engine, it becomes possible to improve the ignition characteristics of the diesel engine. It is more preferable that the portion of the ceramic heater surface where the maximum temperature is reached is the most advanced.
[0017]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, embodiments of the present invention will be described with reference to examples shown in the drawings. FIG. 1 shows a glow plug using a ceramic heater according to the present invention together with its internal structure. That is, the ceramic glow plug 50 includes a ceramic heater 1 provided at one end thereof, a metal outer cylinder 3 that covers an outer peripheral surface of the ceramic heater 1 so that a tip 2 side formed in a curved shape of the ceramic heater 1 protrudes, A cylindrical metal housing 4 or the like that covers the outer cylinder 3 from the outside is provided. The ceramic heater 1 and the outer cylinder 3 and the outer cylinder 3 and the metal housing 4 are joined by brazing. In addition, one end of a coupling member 5 whose both ends are formed in a coiled spring shape by a metal wire is fitted from the outside to the rear end portion of the ceramic heater 1, and the other end side is inserted into the metal housing 4. The metal shaft 6 is fitted on one end. The other end side of the metal shaft 6 extends to the outside of the metal housing 4, and a nut 7 is screwed into a screw portion 6 a formed on the outer peripheral surface of the metal shaft 6, and is tightened toward the metal housing 4. The metal shaft 6 is fixed to the metal housing 4. An insulating bush 8 is fitted between the nut 7 and the metal housing 4. A screw 5 a for fixing the ceramic glow plug 50 to an engine block (not shown) is formed on the outer peripheral surface of the metal housing 4.
[0018]
The ceramic heater 1 is formed in a small diameter with respect to the straight bar 14 part by forming the tip 2 of the cylindrical straight bar 14 part into a curved surface. Further, as shown in FIG. 2, the ceramic heater 1 includes a direction changing part 10a extending from one end part to the other end part and changing in the same direction from each end part of the direction changing part 10a. A U-shaped ceramic heating element 10 having two linear portions 10b extending to the ends of the rod-shaped electrode portions 11 and 12 is embedded at both ends thereof. On the other hand, the ceramic heating element 10 has a shape as shown in FIG. 3 as an overall view and in FIG. 7 as a half sectional view when the cross section is taken at the top portion 10c. The ceramic heating element 10 includes a direction changing portion 10a and a straight portion 10b. The cross-sectional area is the smallest at the connecting portion. The width b 'and the thickness c' at the connecting portion between the direction changing portion 10a and the straight portion 10b are larger and thinner toward the top portion 10c. And in the top part 10c, it has the cross-sectional shape which made the rhombus apex substantially R shape.
[0019]
  In the present embodiment, the width b 'and the thickness c' at the connecting portion between the direction changing portion 10a and the linear portion 10b are set to b '= 1.2 mm and c' = 0.8 mm, respectively. In addition, the width b ″ and the thickness c ″ of the straight portion 10b are set to b ″ = 2 mm and c ″ = 1.2 mm, respectively. Furthermore, in this embodiment, the cross-sectional shape at the top portion 10c.SummitAlthough the point is formed in an approximately rhombus shape with an R shape, it may be oval. The cross-sectional area of the direction changing portion 10a is made smaller than that of the straight portion 10b so that the temperature on the surface of the ceramic heater 1 has an overshoot characteristic at the initial stage of voltage application, but the direction changing portion 10a and the straight portion 10b are The cross-sectional areas may be equal to each other.
[0020]
The ceramic heating element 10 is arranged such that the top portion 10c is located in the tip 2 formed in the curved shape of the ceramic base 13 of the ceramic heater 1. Note that the top portion 10c is set in a range of 1 to 3 mm, desirably 0.5 to 3 mm from the forefront of the ceramic base 13. Each of the electrode portions 11 and 12 extends in a direction away from the ceramic heating element 10 in the ceramic base 13, and one of the electrodes (12) is in the outer cylinder 3 and the other (11) is the ceramic base. In the vicinity of the other end portion of 13, the respective rear end portions are exposed on the surface of the ceramic base 13 to form exposed portions 12 a and 11 a. And each front-end | tip 11b and 12b embed | buried under the ceramic heat generating body 10 is arrange | positioned so that it may enter this outer cylinder 3 side rather than the end surface 3a of the outer cylinder 3. FIG. The distance from the tip to the end surface 3a of the outer cylinder 3 is set in the range of 2 to 20 mm, preferably 3 to 20 mm.
[0021]
Ceramic heating elements include conductive ceramics such as tungsten carbide (WC), molybdenum silicide (MoSi).₂), Tungsten (W), tungsten silicide (WSi)₂) And other low resistance materials and silicon nitride (Si₃N₄), Etc., or a semiconductor ceramic such as silicon carbide (SiC) can be used. The electrode portions 11 and 12 are made of a refractory metal material alloy such as tungsten (W) or tungsten-rhenium (Re). The electrode portions 11 and 12 may be made of the above-described low resistance material selected from the material group constituting the ceramic heating element 10. In this case, the electrode parts 11 and 12 are set to have a resistance value lower than that of at least the ceramic heating element 10. Further, in the present embodiment, the electrode portions 11 and 12 are connected to both end sides of the ceramic heating element 10, but both end portions of the ceramic heating element 10 may be directly exposed on the surface of the ceramic base 13 to be conducted. . On the other hand, the ceramic base 13 is mainly made of insulating ceramics such as alumina (Al₂O₃), Silica (SiO₂), Zirconia (ZrO₂), Titania (TiO₂), Magnesia (MgO), mullite (3Al₂O₃・ 2SiO₂), Zircon (ZrO₂・ SiO₂), Cordierite (2MgO · 2Al)₂O₃・ 5SiO₂), Silicon nitride (Si₃N₄), Aluminum nitride (AlN), or the like.
[0022]
In FIG. 2, glass (not shown) is baked on the surface of the ceramic substrate 13 except for the region including the exposed portion 12a of the electrode portion 12, and the ceramic substrate 13 and the outer cylinder are interposed through the glass layer. 3 are joined by brazing. On the other hand, the electrode portion 12 is electrically connected to the outer cylinder 3 because the exposed portion 12a and the brazing material are directly joined at the time of brazing. Further, the coupling member 5 is also brazed to a region including the exposed portion 11 a of the electrode portion 11. By comprising in this way, it supplies with electricity to the ceramic heat generating body 10 via the metal shaft 6 (FIG. 1), the coupling member 5, and the electrode part 11 from the power supply which is not shown in figure, Furthermore, the electrode part 12, the outer cylinder 3, It is grounded through a metal housing 4 (FIG. 1) and an engine block (not shown). By this energization, the ceramic heating element 10 generates resistance heat. In the present embodiment, the exposed portion 12a is formed in the outer cylinder 3 in the electrode portion 12. However, the exposed portion 12a is formed in the central portion of the ceramic base 13 outside the outer tube 3, and the coil-shaped coupling member is interposed therebetween. The outer cylinder 3 may be brazed to be conducted.
[0023]
Here, the tips 11b and 12b of the electrode parts 11 and 12 are arranged so as to enter the outer cylinder 3 side with respect to the end surface 3a of the outer cylinder 3, whereby the electrode parts 11 and 12 and the ceramic heating element 10 The interface portion P is located away from the vicinity of the end surface of the outer cylinder 3 which is easily expanded / contracted due to energization heat generation from the ceramic heater or heat from the engine, and the compressive stress from the outer cylinder 3 due to the expansion / contraction is described above. However, it becomes difficult to act on the interface portion P. As a result, it is possible to prevent or suppress the occurrence of cracks or the like in the ceramic heating element 10 in the vicinity of the interface portion P. Here, when the distance 1 from the respective tips 11b and 12b of the electrode portions 11 and 12 to the end surface 3a of the outer cylinder 3 is less than 2 mm, the above effect may not be achieved. The distance l is more preferably set to 3 mm or more. On the other hand, when the distance l exceeds 20 mm, the length existing in the outer cylinder 3 of the ceramic heating element 10 becomes longer, and the brazing material joining the outer cylinder 3 and the ceramic heater 1 becomes the heating element 10. Problems such as melting and outflow due to excessive heat generation from the pipe may occur. Therefore, the distance l is set to 20 mm or less.
[0024]
The ceramic heater 1 can be manufactured, for example, by the following method. First, as shown in FIG. 4A, the electrode material 30 is inserted into the mold 31 having the U-shaped cavity 32 corresponding to the ceramic heating element 10 so that the end portion enters the cavity 32. To place. Then, in this state, by injecting a compound 33 containing conductive ceramic powder and a binder, as shown in FIG. 5B, the electrode material 30 and the U-shaped conductive ceramic powder molding portion 34 Is formed into an integrated injection-molded body 35. The portion 34b that becomes the straight portion 10b after firing has a substantially circular cross-sectional shape.
[0025]
On the other hand, separately from this, by pre-molding the ceramic powder forming the ceramic base 13 by die press molding, pre-formed bodies 36 and 37 formed as separate upper and lower bodies as shown in FIG. 5A are prepared. Keep it. These preforms 36 and 37 are formed in a shape corresponding to each of the divided parts when the ceramic base 13 is assumed to be divided into two parts by a cross section substantially parallel to the axis thereof. A concave portion 38 having a shape corresponding to the integrally formed body 35 is formed in a corresponding portion. Then, the integral injection molded body 35 is accommodated in the recess 38, and the upper and lower preformed bodies 36 and 37 are mold-matched, and in this state, the preformed bodies 36 and 37 and the integral injection molded body 35 are further molded. By using and pressing and integrating, a composite molded body 39 as shown in FIG. 5B is created.
[0026]
The composite molded body 39 thus obtained is first calcined in order to remove the binder component from the conductive ceramic powder molded portion 34 or the preformed bodies 36 and 37 by injection molding, and subsequently, as shown in FIG. 6 (a). Further, by performing hot press firing at a predetermined temperature while pressing between molding machines 40 made of graphite or the like, a fired body 41 as shown in FIG. At this time, the conductive ceramic powder molding machine 34 shown in FIG. 5 (b) forms the ceramic heating element 10, the preforms 36 and 37 form the ceramic base 13, and the electrode material 30 forms the electrode portions 11 and 12, respectively. It will be. Then, the ceramic heater 1 as shown in FIG. 2 is obtained by processing the outer surface of the fired body 41 as necessary, such as polishing.
[0027]
【Example】
  Next, experimental examples for showing the effects of the present invention will be described. Sample No.(1)~(7)Is an example according to the present invention.(8)Is a comparative product for confirming the difference in effect from this example. Sample No.(1)~(3)Is an example when the cross-sectional shape of the top portion 10c is an ellipse.(4)~(6)Is an example in which the cross-sectional shape shown in FIG.(7)These show the Example in the case of the cross-sectional shape which made the rhombus apex substantially R shape. And width b and thickness c, and a sample(4)~(7)In this case, various shapes of the included angle α of the base side outline in the range of 60% of the center of the width b were prepared. Sample No.(1)~(3)Is shown in FIG.(4)~(6)Is shown in FIG.(7)FIG. 8 shows an enlarged view of the cross-sectional shape at the top. In these drawings, the tangent line 20, the imaginary circle 21, and the imaginary line 22 indicating the range of the center 60% of the width are shown by dotted lines so as to contact each other at the center of the base end side outline 10d.
[0028]
  Sample No.(4)~(7)In the cross-sectional shape of the top portion 10c, the base-side contour line 10d in the range of the center 60% of the width is formed by two straight lines. The included angle α of these two straight lines is the sample No.(4), (5)And Sample No.(7)Is formed at 160 ° ≦ α <180 °.(6)Is formed such that α = 156 ° <160 °.
[0029]
  Sample No. which is a comparative product.(8)The cross-sectional shape of the top of the circular cross-sectional shape as shown in FIG. Therefore, both the width b and the thickness c are the same as the diameter. In addition, the width b in this cross section, that is, the diameter and the width b 'on the base side is the same, and the thickness c in this cross section, that is, the diameter and the thickness c' on the base side are the same. FIG. 12 shows the results of each test of temperature rise characteristics, power consumption, and energization durability for each of these samples. Further, in FIG. 12, the area A surrounded by the imaginary line 22 indicating the range of the center 60% of the tangent line 20 and the width b and the base end side outline 10d, and the range of the center 60% of the tangent line 20 and the width b. An area A ′ surrounded by a virtual line 22 and a virtual circle 21 is shown at the same time.
[0030]
  From these test results, a sample having a large width b and a small thickness c(7)It can be seen that each test shows the best results. In addition, the test method of each test is shown below. Temperature rise characteristic test: When a voltage at which the temperature of the tip 2 formed in a curved surface is 1350 ° C. is applied 60 seconds after the start of energization, the temperature of the tip 2 after 3 seconds from the start of application is measured. . In this case, a range of 800 ° C. or more and less than 850 ° C. was judged as acceptable (Δ), a range of 850 ° C. or more and less than 900 ° C. was judged as good (◯), and 900 ° C. or more was judged as excellent (◎). Power consumption test: Measure power consumption at steady temperature when a voltage at which the temperature of the tip 2 formed in a curved surface is 1350 ° C. is applied at steady temperature. In this case, 80 W or more was judged as normal (×), a range from 75 W to less than 80 W was acceptable (Δ), a range from 70 W to less than 75 W was judged as good (◯), and a range less than 70 W was judged as excellent (◎). Energization endurance test: A cycle in which the temperature of the tip 2 formed in a curved surface is 1350 ° C. when the temperature is steady is energized for 1 minute, interrupted for 1 minute, and forcedly cooled with air when energized. When the durability test is performed, the number of cycles until the temperature of the tip 2 becomes 1300 ° C. or less due to factors such as an increase in the resistance value of the ceramic heating element is measured. In this case, the range from 15000 cycles to less than 20000 cycles is normal (x), the range from 20000 cycles to less than 25000 cycles is acceptable (Δ), the range from 25000 cycles to less than 30000 cycles is good (◯), and 30000 cycles are performed. Also, those with no abnormalities were judged as excellent (◎).
[0031]
  From these test results, the following was confirmed.
1. Sample No. 2 in which the width b and the thickness c satisfy the relationship b> c.(1)~(3)And Sample No.(7)Is a sample No. as a comparative example.(8)It can be seen that the current-carrying durability is superior to
2. Sample No. 2 in which the width b 'on the base side with respect to the width b satisfies the relationship b> b'.(1)And Sample No.(7)Is a sample No. as a comparative example.(8)It can be seen that the current-carrying durability is superior to
3. Sample No. A in which the area A and the area A ′ satisfy the relationship of A ′> A.(1)~(7)Is a sample No. as a comparative example.(8)It can be seen that the current-carrying durability is superior to
4). Sample No. in which the base side outline in the range of 60% of the center of the width b is formed by a single line or two straight lines.(4)~(7)Among them, the sample No. in which the included angle α is 160 ° ≦ α ≦ 180 °.(4), (5)And Sample No.(7)Is the included angle α,156 °Sample to be(6)It can be seen that the energization durability is further improved as compared with the above.
5. Sample No. 2 in which the thickness c ′ on the base side with respect to the thickness c satisfies the relationship c <c ′.(2), (3)And Sample No.(7)Is a sample No. as a comparative example.(8)As compared with the above, it is excellent in energization durability, and the maximum temperature portion of the ceramic heating element can be disposed on the most advanced side of the ceramic substrate, so that it can be seen that the temperature rise characteristics are also improved. In addition, power consumption can be further reduced.
6). The width b and the thickness c satisfy the relationship b> c, the width b ′ closer to the base than the width b satisfies the relationship b> b ′, and the area A and the area A ′ are represented by A ′. > A, the included angle α is 160 ° ≦ α ≦ 180 °, and the thickness c ′ on the base side with respect to the thickness c satisfies the relationship c <c ′.(7)It is understood that the temperature rise characteristics, power consumption, and energization durability are the best.
[0032]
  Next, the sample No. with the best energization durability, power consumption, and temperature rise characteristics was obtained.(7)Sample No. as a comparative example.(8)FIG. 13 shows the result of measuring the temperature distribution at the time of steady temperature when a voltage at which the temperature of the tip 2 formed in a curved surface at the temperature steady state is 1350 ° C. is applied. In FIG. 13, the horizontal axis indicates the distance along the surface in the base direction from this position, where the most advanced position of the ceramic heater is 0, and the vertical axis indicates the temperature at the distance. The symbol P in FIG. 13 indicates the position of the boundary between the tip 2 and the straight bar 14 in the ceramic heater 1. As a result, sample no.(7)The highest temperature of the ceramic heater is the highest, and the temperature decreases toward the base side.RukoI understand. In contrast, Sample No. as a comparative example.(8)It can be seen that the portion of the ceramic heater surface where the maximum temperature is reached is not at the tip 2 but at a position closer to the base side.
[Brief description of the drawings]
FIG. 1 is a front partial sectional view showing an example of a glow plug of the present invention.
FIG. 2 is a front sectional view of the ceramic heater.
FIG. 3 is an overall view of a ceramic heating element.
FIG. 4 is an explanatory diagram of a manufacturing process of a ceramic heater.
FIG. 5 is a process explanatory diagram subsequent to FIG. 4;
6 is a process explanatory diagram subsequent to FIG. 5. FIG.
FIG. 7 is a half cross-sectional view of the ceramic heating element according to the present invention as a cross section at the top.
FIG. 8 is an enlarged top view of a ceramic heating element according to the present invention.
FIG. 9 is an enlarged top view of a ceramic heating element according to another embodiment of the present invention.
FIG. 10 is an enlarged top view of a ceramic heating element according to another embodiment of the present invention.
FIG. 11 is an enlarged top view of a ceramic heating element according to a comparative example of the present invention.
FIG. 12 is a diagram showing experimental results of the present invention.
FIG. 13 is a drawing showing temperature distribution of ceramic heaters according to examples and comparative examples of the present invention.
FIG. 14 is a view showing a temperature distribution of a conventional ceramic heater.
FIG. 15 is a drawing in which a temperature distribution in a cross section of a conventional ceramic heater is obtained by FEM analysis.
[Explanation of symbols]
1 Ceramic heater
2 Tip
10 Ceramic heating element
10a Direction change part
10b Straight section
10c top
10d Proximal contour line
11 Electrode section
12 Electrode section
13 Ceramic substrate
20 Tangent
21 virtual circle
22 Virtual line (line showing the center 60% of the width)
50 ceramic glow plug
α
b width
c Thickness

Claims (6)

In a ceramic heater comprising an axial rod-shaped ceramic base and a ceramic heating element embedded in the ceramic base and generating heat by being energized from the end side of the ceramic base,
The ceramic heating element includes a U-shaped direction changing portion, and a portion where the width b ′ on the end side satisfies the relationship of b> b ′ with respect to the width b in the top cross-sectional shape of the direction changing portion. A ceramic heater comprising: In a ceramic heater comprising an axial rod-shaped ceramic base and a ceramic heating element embedded in the ceramic base and generating heat by being energized from the end side of the ceramic base,
The ceramic heating element includes a U-shaped direction change portion, an end side contour line in a range of the center 60% of the width b in the top cross-sectional shape of the direction change portion, and the end side contour line. When a virtual circle having an area A formed by a tangent at the center and a diameter of width b is drawn so as to touch the center of the edge side contour line, A ceramic heater characterized in that an area A ′ formed by the tangent line has a portion satisfying a relationship of A ′> A. When the top cross-sectional shape is formed by one or two straight lines in the range of the center 60% of the width and is constituted by two straight lines, the included angle is 3. The ceramic heater according to claim 2 , wherein α is 160 ° ≦ α <180 °. The ceramic heater has a tip formed with a small diameter, and the top of the direction changing portion of the ceramic heating element is disposed so as to be located in the tip of the ceramic heater, and the ceramic heating element The ceramic heater according to any one of claims 1 to 3 , wherein the tip of the surface of the ceramic heater having the highest temperature due to resistance heat generation is the tip. The ceramic heater according to any one of claims 1 to 4 , wherein a portion of the surface of the ceramic heater where the maximum temperature is reached is the most advanced. A glow plug comprising the ceramic heater according to claim 1 .