JP4562315B2 - Ceramic heater, ceramic heater manufacturing method, and glow plug - Google Patents

Description

【００５６】
【表２】

【００５７】
傾斜角度を５０°よりも大きく設定した比較例においては、グロープラグ５０に組み付けたときの気密性を確保することができなかった。他方、傾斜角度をテーパ面２ｐを設けた場合で４０°以下、曲面部１ｑを設けた場合で４５°以下とすることにより、分解後締め代の値を８μｍ以上に確保することができ、さらに接触抵抗値を減少させることができ、良好な導通状態が得られた。これは、圧入荷重が大きすぎるため金属外筒３の塑性変形量が増大し、緊束力が不足した結果であると考えられる。さらに、分解後締め代のより望ましい値である１５〜４０μｍが確保されているものについていうと、テーパ面２ｐの傾斜角度が０．５°〜３０°に調整されたセラミックヒータ２０である。
【図面の簡単な説明】
【図１】本発明のセラミックヒータを備えるグロープラグを示す縦断面図。
【図２】図１の要部を示す縦断面図。
【図３】軸線方向と垂直な方向からのヒータ本体の先端部の拡大投影図。
【図４】ヒータ本体を金属外筒に圧入する際の模式図。
【図５】ヒータ本体の製造工程の説明図。
【図６】図５に続く説明図。
【図７】分解後締め代の算出に使用する部位を説明する図。
【図８】図１のグロープラグの第一変形例を示す要部縦断面図。
【図９】同じく第二変形例を示す要部縦断面図。
【図１０】ヒータ本体の別形態を示す図３と同様の投影図。
【図１１】実験結果の要部を示すグラフ
【図１２】同じく図１１に続くグラフ。
【符号の説明】
１ ヒータ本体
２ 先端部
３ 金属外筒
１１ 抵抗発熱体
２０ セラミックヒータ
１ｐ 定径部
１ｑ 曲面部
２ｐ テーパ面
２ｍ 丸め部
Ｏ 軸線
ＰＬ 基準線[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a ceramic heater and a manufacturing method thereof, and further relates to a glow plug including the ceramic heater.
[0002]
[Prior art]
Conventionally, for example, as shown in FIG. 1, a glow plug 50 in which a ceramic heater 20 is held by a metal shell 4 is known, and is used for promoting starting of a diesel engine or the like. The ceramic heater 20 includes a heater main body 1 in which a resistance heating element 11 is embedded, and a metal outer cylinder 3 attached to the outer peripheral surface of the heater main body 1.
[0003]
Energization of the heater body is performed through a metal shaft (connected to a power source) provided at the rear end portion of the metal shell and a metal lead portion connecting the metal shaft and the heater body. Taking a conventional ceramic heater type glow plug as an example, the connection between the heater main body and the metal lead portion is, for example, as disclosed in JP-A-10-205753 or JP-A-2000-356343. This is done by forming the tip of the coil in the shape of a coil, inserting the rear end of the heater body with the heater terminal exposed and inserting it inside, and brazing the two. In addition, a structure in which the other terminal of the heater body is connected to the metal shell via a metal outer cylinder and grounded via an engine block to which a glow plug is attached is also adopted. It is joined to the heater body by brazing.
[0004]
However, the joining form by brazing has a drawback that the efficiency is poor due to a large number of man-hours such as a process for assembling the materials to be joined by sandwiching the brazing material and a heating process for melting the brazing material. Also, since it is a joint between ceramic and metal members such as metal leads or metal outer cylinders, expensive active brazing materials must be used, and the heating temperature and atmosphere for brazing are also delicately adjusted. In combination with the above-described problem of increasing man-hours, the manufacturing cost is likely to increase. Japanese Patent Application Laid-Open No. 2000-356343 discloses a method of assembling the metal outer cylinder to the ground terminal of the heater body by shrink fitting.
[0005]
[Problems to be solved by the invention]
When the assembly of the heater main body and the metal outer cylinder is performed by, for example, press fitting, it is important that the heater main body can be smoothly pressed into the metal outer cylinder. At this time, the diameter difference between the outer diameter of the heater body and the inner diameter of the metal outer cylinder, so-called tightening margin, is an important parameter. The tightening allowance includes an initial tightening allowance measured before assembling each member and an after-disassembly tightening allowance measured after disassembling after assembling. Mainly, if the tightening allowance after disassembly is too small, the binding force is insufficient and sufficient bonding strength cannot be obtained. On the other hand, when the initial tightening allowance is too large, the press-fitting of the heater body into the metal outer cylinder cannot be performed smoothly, and the press-fitting load naturally increases, causing cracks, cracks, etc. in the heater body, resulting in poor bonding.
[0006]
The subject of this invention is providing the ceramic heater manufactured by the manufacturing method of the ceramic heater which can carry out the press-fit fitting of the heater main body and metal outer cylinder which are ceramic members smoothly, and the method.
[0007]
[Means for solving the problems and actions / effects]
In order to solve the above problem, the first configuration of the ceramic heater of the present invention is:
It has a rod shape that has a front end and a rear end and extends in the axis, Own Tip A resistance heating element is embedded inside Tahi Data body, Above On the outer peripheral surface of the heater body , Exposing the leading end and the trailing end of the heater body, With a metal outer cylinder attached by press fitting,
Of the heater body Tip A taper surface having an inclination angle with respect to the axis of 0.5 ° or more and 50 ° or less is formed on the outer peripheral surface in a form that decreases in diameter toward the tip.
[0008]
Similarly, the second configuration is
It has a rod shape that has a front end and a rear end and extends in the axis, Own Tip A resistance heating element is embedded inside Tahi Data body, Above On the outer peripheral surface of the heater body , Exposing the leading end and the trailing end of the heater body, With a metal outer cylinder attached by press fitting,
Of the heater body Tip Is configured to include a constant diameter portion and a curved surface portion having a different radius of curvature that is formed adjacent to the constant diameter portion and decreases in diameter toward the tip.
Regarding the projection plane from the direction perpendicular to the axis,
When a reference line is drawn at a position 95% of the radius of the heater body in the constant diameter portion in parallel with the outer shape line of the heater body in the constant diameter portion, the reference line of the tangent line of the curved surface portion outside the reference line The maximum value of the tilt angle is adjusted to be not less than 0.5 ° and not more than 50 °.
[0009]
Furthermore, the manufacturing method of the ceramic heater of the present invention in the first configuration is as follows.
A method of manufacturing a ceramic heater comprising a rod-shaped heater body in which a resistance heating element is embedded inside itself, and a metal outer cylinder attached to the outer peripheral surface of the heater body,
Of the heater body Resistance heating element was buried One end The tip of the Forming a tapered surface having a diameter that decreases toward the tip on the outer peripheral surface so that the insertion side edge of the metal outer cylinder is in contact with the tapered surface; and
Tip The heater main body is press-fitted into the metal outer cylinder from the side and is fitted.
[0010]
The manufacturing method of the ceramic heater of the present invention in the second configuration is as follows:
It has a rod shape that has a front end and a rear end and extends in the axis, Own Tip A resistance heating element is embedded inside Tahi A method of manufacturing a ceramic heater comprising a main body and a metal outer cylinder attached to an outer peripheral surface of the heater body,
The diameter is smaller toward the tip, adjacent to the constant diameter portion of the heater body and having a different curvature radius,
When a reference line is drawn parallel to the outline of the heater main body at the constant diameter portion at a position 95% of the radius of the heater main body at the constant diameter portion with respect to the projection plane from the direction perpendicular to the axis, the reference Forming a curved surface portion having a maximum inclination angle of 0.5 ° to 50 ° with respect to a reference line of its tangent line outside the line;
And a step of press-fitting and fitting the heater body into the metal outer cylinder from the side where the curved surface portion is formed.
[0011]
In the method for manufacturing a ceramic heater according to the present invention, the method for joining the heater main body and the metal outer cylinder is press-fitting. If the end of the heater body has a tapered surface or curved surface with a diameter that decreases toward the tip, the heater body can be smoothly pressed into the metal outer cylinder, and cracks and cracks will occur. Can be suppressed. As a result, joining of a heater main body and a metal outer cylinder can be performed reliably.
[0012]
In addition, the present inventors have found that even when the initial tightening allowance is the same, as the tilt angle (including the concept of the maximum value of the tilt angle) increases, the post-disassembly tightening allowance decreases. As a result of further investigation, if the inclination angle exceeds 50 °, when the heater main body and the metal outer cylinder are assembled by press-fitting, the post-disassembly tightening margin is insufficient and sufficient bonding strength cannot be obtained. As a result, the inventors have invented the ceramic heater of the present invention and the manufacturing method thereof. When the inclination angle exceeds 50 °, the press-fitting load required for press-fitting the heater body into the metal outer cylinder is remarkably increased. If the press-fit load increases, the stress acting on the metal outer cylinder also increases, and the amount of plastic deformation also increases. As a result, a significant amount of post-disassembly tightening allowance cannot be secured, resulting in a decrease in airtightness.
[0013]
Further, an excessive press-fitting load causes the heater main body to crack or crack. For example, the glow plug is attached so as to be exposed in the combustion chamber of the engine, and the heat receiving / cooling cycle is frequently repeated. Therefore, even a minute crack generated at the time of press-in may cause the heater body to be damaged.
[0014]
On the other hand, even if the tapered surface or the curved surface portion is formed at an inclination angle of less than 0.5 °, further improvement in the effect of facilitating press-fitting cannot be expected. Further, in order to design the edge of the metal outer cylinder to be in contact with the inclined portion at the time of press-fitting, the smaller the inclination angle, the wider the polishing area in the axial direction. That is, it is not desirable because processing becomes difficult and an increase in cost cannot be avoided. Considering the processing cost and the effect of facilitating press-fitting, it is more desirable that the inclination angle be 0.5 ° or more and 30 ° or less.
[0015]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, embodiments of the present invention will be described with reference to the drawings.
FIG. 1 shows an example in which the ceramic heater of the present invention is applied to a glow plug, and shows the internal structure thereof. FIG. 2 is an enlarged view of the main part. The glow plug 50 includes the ceramic heater 20 and the metal shell 4 coupled thereto. In the ceramic heater 20, the heater main body 1 has a rod-like shape, and the resistance heating element 11 is embedded in the front end portion 2 thereof. The metal outer cylinder 3 holds the heater body 1 inside itself in such a manner that the rear end portion and the front end portion 2 protrude in the direction of the axis O, respectively. Moreover, the 1st heater terminal 12a for supplying with electricity to the resistance heating element 11 is exposedly formed by the own rear end part outer peripheral surface. The metal shell 4 is formed in a cylindrical shape that coaxially covers the outside of the ceramic heater 20.
[0016]
Next, the outer peripheral surface of the metal shell 4 is formed with a screw portion 5 as an attachment portion for fixing the glow plug 50 to an engine block (not shown), and a metal shaft 6 is attached to the rear end portion. . The metal shaft 6 has a rod shape and is inserted in the direction of the axis O inside the rear end of the metal shell 4, and its front end surface 65 faces the rear end surface 2 r of the heater body 1 in the direction of the axis O. Arranged in a shape. On the other hand, on the outer peripheral surface of the rear end portion of the heater body 1 in the ring arrangement gap G, a metal terminal ring 14 that is electrically connected to the first heater terminal 12a covers the first heater terminal 12a in an interference fit state. It is attached. The metal shaft 6 and the first heater terminal 12 a are electrically connected by a metal lead portion 17 having one end coupled to the terminal ring 14 and the other end coupled to the metal shaft 6. Since the metal lead portion 17 is attached to the terminal ring 14 by metal / metal bonding, complicated structures such as a metal / ceramic brazing structure and embedded bonding of the metal lead portion 17 to the heater body 1 are eliminated. And can be manufactured inexpensively. Further, since the terminal ring 14 is fitted to the heater body 1 by interference fitting, no brazing material layer is interposed as in the conventional structure by brazing, and the coaxiality between the metal shaft 6 and the terminal ring 14 is easily secured. Thereby, it becomes difficult to produce a shift | offset | difference etc. in the joining surface of the metal lead part 17, and the metal shaft 6 or the terminal ring 14, and a favorable and high intensity | strength joining part can be formed by extension.
[0017]
On the outer peripheral surface of the heater body 1, a second heater terminal 12b for energizing the resistance heating element 11 is exposed and formed in front of the first heater terminal 12a in the axis O direction. And the cylindrical metal outer cylinder 3 which covers the second heater terminal 12b and is electrically connected to the outer periphery of the heater main body 1 in a state where the rear end of the heater main body 1 protrudes toward the rear side of the heater main body 1 A ceramic heater 20 is formed by being attached to the surface by press fitting.
[0018]
According to the above configuration, the metal outer cylinder 3 inserted between the metal shell 4 and the heater main body 1 is used as a spacer, so that the rear of the heater main body 1 protruded rearward from the metal outer cylinder 3. An appropriate gap can be formed between the outer peripheral surface of the end portion and the inner peripheral surface on the rear side of the heater holding surface 4a of the metal shell 4. This makes it easier to arrange the terminal ring 14 at the rear end of the heater body 1.
[0019]
In addition, as shown in FIG. 9, it is also possible to employ | adopt the structure which combined the metal shell 4 and the metal outer cylinder 3 (dashed line part). The heater main body 1 can be directly press-fitted into the metal shell 4 by integrally forming the metal outer cylinder 3 and the metal shell 4 in the ceramic heater 20. This is advantageous in that the number of parts can be reduced.
[0020]
Next, as for the assembly form of the metal shell 4 and the metal outer cylinder 3, for example, it is brazed so as to fill a gap between the inner and outer peripheral surfaces of the metal shell 4 or the inner edge of the metal shell 4 and the metal outer cylinder 3 However, in the present embodiment, the metal shell 4 is also attached to the outer peripheral surface of the metal outer cylinder 3 in an interference fit state on the heater holding surface 4a. I am doing so. Thereby, the assembly process of the glow plug 50 can be further simplified. Further, the fitting surface (heater holding surface 4 a) of the metal shell 4 with respect to the metal outer cylinder 3 overlaps with the fitting surface between the metal outer cylinder 3 and the heater body 1. The tightness of the metal shell 4 is superimposed on the tightness of the metal heater 4, and the reliability of the fitting in the ceramic heater 20 can be further enhanced.
[0021]
For example, as shown in FIG. 6, the terminal ring 14 or the metal outer cylinder 3 is assembled to the heater main body 1 while inserting the terminal ring 14 or the metal outer cylinder 3 into the heater main body 1 in the direction of the axis O from the end. Can be assembled by press-fitting. Of these, the terminal ring 14 only needs to have a binding force that can ensure electrical continuity with the first heater terminal 12a. On the other hand, the metal outer cylinder 3 is required to have a tighter binding force than the terminal ring 14 because it is necessary to ensure airtightness on the fitting surface in addition to ensuring conduction with the second heater terminal 12b. In any case, it is important that a necessary and sufficient binding force is ensured not only at room temperature but also at the time of temperature rise of the heater body 1 where thermal expansion occurs in each part. In general, when comparing ceramic and metal, except for special alloys such as Invar, metal has a higher coefficient of linear expansion, and the terminal ring 14 and the metal outer cylinder 3 tend to loosen tightly when the temperature rises. is there.
[0022]
In this case, although the level of tight force secured at the time of temperature rise varies depending on the material and the wall thickness t, as shown in FIG. 7, in a disassembled state in which the terminal ring 14 or the metal outer cylinder 3 is removed from the heater body 1. The inner diameter of the terminal ring 14 is D1, and the outer diameter of the heater body 1 at the position where the first heater terminal 12a is formed in the disassembled state is D2, and D2-D1 (hereinafter referred to as the post-disassembly tightening margin of the terminal ring 14: In the present specification, the value in the room temperature state) is preferably adjusted to a range of 8 μm or more and 2% or less of the outer diameter of the heater body 1 at the attachment position of the terminal ring 14.
[0023]
Further, the inner diameter of the metal outer cylinder 3 measured in a disassembled state in which the metal outer cylinder 3 is removed from the heater body 1 is d1, and the outer diameter of the heater body 1 is d2, and d2-d1 (hereinafter referred to as a metal outer cylinder). 3 is also referred to as a value at room temperature in this specification). Similarly, it is 8 μm or more and 2% or less of the outer diameter of the heater body 1 at the mounting position of the metal outer cylinder 3. It is desirable that the range is adjusted.
[0024]
The post-disassembly tightening allowance can be regarded as a parameter reflecting the amount of elastic return of the terminal ring 14 and the metal outer cylinder 3 when removed from the heater body 1, that is, the elastic binding force to the heater body 1 by them. . If the post-decomposition tightening allowance is less than 8 μm, the required tight force cannot be secured when the temperature of the metal outer cylinder 3 or the terminal ring 14 rises within the temperature range. For example, an increase in contact resistance with the first heater terminal 12a in the terminal ring 14 and an increase in contact resistance with the second heater terminal 12b in the metal outer cylinder 3 are caused as specific problems. On the other hand, if the tightening allowance after disassembly exceeds 2% of the outer diameter of the heater body 1 at the position of the terminal ring 14 or the metal outer cylinder 3 (for example, 70 μm when the outer diameter is 3.5 mm), the heater body 1 In some cases, an excessive tight force acts on the surface, leading to the occurrence of cracks and cracks. When the thickness of the metal outer cylinder 3 and the terminal ring 14 is small, the amount of plastic deformation of the metal outer cylinder 3 and the terminal ring 14 increases, and therefore it is essentially impossible to set the post-decomposition tightening allowance above the upper limit. There is. The post-disassembly tightening allowance D2-D1 or d2-d1 is more preferably adjusted to a range of 15 to 40 μm. Further, even if the fastening value after disassembly is the same, a larger wall thickness is more advantageous in terms of increasing the value of the elastic binding force.
[0025]
Next, FIG. 3 shows an enlarged projection view of the distal end portion 2 of the heater body 1 from a direction perpendicular to the direction of the axis O in the ceramic heater 20. As shown in the figure, the tip 2 of the heater body 1 is formed with a tapered surface 2p inclined by θ ° with respect to the axis O in such a form that the diameter decreases toward the tip. That is, the tip 2 is formed to include a tapered surface 2p and a spherical rounded portion 2m following the tapered surface 2p. An outer peripheral surface adjacent to the tapered surface 2p and located on the side opposite to the rounded portion 2m is a cylindrical surface parallel to the axis O, and forms a constant diameter portion in the heater body 1.
[0026]
In the manufacturing method of the ceramic heater 20 of the present invention, the heater body 1 is press-fitted into the metal outer cylinder 3 and joined. As described above, when the tapered surface 2p is formed at the distal end portion 2 of the heater main body 1, the heater main body 1 can be smoothly inserted into the metal outer cylinder 3, and the occurrence of cracks and cracks can be suppressed. The inclination angle θ of the tapered surface 2p with respect to the axis O may be adjusted to 0.5 ° or more and 50 ° or less. If the inclination angle exceeds 50 °, the press-fitting load required for press-fitting the heater body 1 into the metal outer tube 3 is remarkably increased, which causes the occurrence of cracks and cracks. On the other hand, if the angle is less than 0.5 °, an improvement in the effect of enabling smooth press-fitting cannot be expected any more, and processing becomes difficult and costs increase, which is not desirable.
[0027]
Further, in order to obtain the same effect as that in the case where the tapered surface 2p is provided, the following configuration can be made and further adjustment can be made. That is, as shown in FIG. 10, at least one end in the axis O direction of the heater body 1 is formed with a constant diameter portion 1p and a curvature that is formed adjacent to the constant diameter portion 1p and decreases in diameter toward the tip. The curved surface portion 1q having different radii is included. In this case, with respect to the projection plane from the direction perpendicular to the axis O (shown in FIG. 10), the heater main body 1 at the constant diameter portion 1p is positioned at 95% of the radius of the heater main body 1 at the constant diameter portion 1p. When the reference line PL is drawn parallel to the outline, the maximum value ω of the inclination angle with respect to the reference line PL of the tangent to the curved surface portion 1q outside the reference line PL (opposite to the axis O) is 0.5 ° or more. Adjust to 50 ° or less.
[0028]
When the heater main body 1 is press-fitted into the metal outer cylinder 3 from the side where the curved surface portion 1q is formed, the inner peripheral edge of the metal outer tube 3 first comes into contact with the vicinity of the reference line PL of the curved surface portion 1q. When the inner peripheral edge of the metal outer cylinder 3 is set so as to contact the inside larger than the reference line PL at 95% of the radius, press-fitting becomes difficult regardless of the inclination angle of the tangent line. Cheap. Further, by making the curvature different, it is possible to easily perform processing for preventing the occurrence of a step with the constant diameter portion 1p.
[0029]
Further, as will be clarified in Examples described later, even if the initial tightening allowance is exactly the same, if the inclination angle of the tapered surface 2p is different, the load required for press-fitting is also different, and the heater body 1 and the metal outer cylinder 3 are assembled. The post-decomposition tightening margin that is measured after decomposing also differs. That is, the inclination angle of the tapered surface 2p is a parameter that governs the plastic deformation amount and the elastic deformation amount of the metal outer cylinder 3, and at the same time, a parameter that affects the bonding strength between the heater body 1 and the metal outer cylinder 3. is there.
[0030]
FIG. 4 is a schematic diagram when the heater main body 1 is press-fitted into the metal outer cylinder 3. First, FIG. 4A schematically shows the distribution W of stress acting on the metal outer cylinder 3 when the heater main body 1 having the tapered surface 2p adjusted to approximately 20 ° to 30 ° is press-fitted into the metal outer cylinder 3. Indicated. FIG. 4B schematically shows a distribution W of stress acting on the metal outer cylinder 3 when the heater main body 1 whose taper surface is adjusted to be larger than 50 ° is press-fitted into the metal outer cylinder 3. As shown in each figure, since the outer diameter of the heater body 1 is designed to be larger than the inner diameter of the metal outer cylinder 3, the taper surface 2p abuts on the metal outer cylinder 3 and stress is applied in the vicinity thereof. W works. If the inclination angle of the taper surface 2p is increased, the press-fitting load is increased, and the force applied to the metal outer cylinder 3 is increased accordingly. As shown in FIGS. 4 (a ′) and 4 (b ′), when the acting force increases, the amount of plastic deformation of the metal outer cylinder 3 increases, and the amount of elastic deformation decreases accordingly. Since the outer cylinder 3 holds the heater body 1, the binding force does not sufficiently work. The inclination angle of the tapered surface 2p is more preferably 0.5 ° or more and 30 ° or less.
[0031]
As a material of the terminal ring 14 and the metal outer cylinder 3, it is desirable to use an Fe-based alloy having a certain level of hardness and heat resistance in consideration of the balance between high temperature strength and material cost. In particular, in order to increase the tightening allowance after disassembly and ensure a sufficient elastic binding force, the Vickers hardness (measured at a load of 10 N by a method prescribed in JIS: Z2244 (1998)) Hv is 170 or more ( The use of an Fe-based alloy (preferably 350 or more) is recommended. As such an Fe-based alloy, precipitation hardening stainless steel such as SUS630 or SUS631 can be preferably used. For example, SUS630 can be age-precipitated and hardened by heat treatment of any of H900, H1025, H1075 or H1105 specified in JIS G4303 (1988). On the other hand, SUS631 can be age precipitation hardened by heat treatment of TH1050 or RH950 of the same standard, and both can ensure Hv350 or more. Moreover, although it is slightly inferior in terms of hardness, ferritic stainless steel such as SUS430 can also be used.
[0032]
In addition, when it is required to ensure higher heat resistance and to further suppress the decrease in tightness at high temperatures, an iron-based superalloy (for example, Incoloy 909 (trade name of Inco Corporation)) Age-hardened products, work hardening of Ni-base superalloys (eg Waspaloy (trade name of United Technology)) or non-age-hardening Ni-base heat-resistant alloys (Inconel 625 (trade name of Inco)) It is also possible to use goods. However, these materials are expensive, and are the normal use environment of the glow plug, and the ultimate temperature of the terminal ring 14 is about 50 to 200 ° C., and the ultimate temperature of the metal outer cylinder 3 is about 500 to 700 ° C. The total content of alloy elements to be added for matrix solid solution strengthening or precipitate formation, such as precipitation hardened stainless steel, such as Ni, Cr, Cu, Nb or Al, is in the range of 50% by mass or less. It is desirable to use a limited Fe-based alloy. However, it is desirable that 20% by mass or more of these total contents is added from the viewpoint of securing high-temperature strength or corrosion resistance.
[0033]
As shown in FIG. 2, the metal lead portion 17 is arranged in a bent shape between the metal shaft 6 and the terminal ring 14. Thereby, even when a heating / cooling cycle is applied due to heat generation of the heater body 1, the metal lead portion 17 can absorb expansion / contraction at the bent portion, and thus the metal lead portion 17 and the terminal ring 14 can be absorbed. It is possible to prevent problems such as contact failure and disconnection due to excessive stress concentration at the joint. On the other hand, in order to easily and firmly join the metal lead portion 17 and the metal shaft 6, the joining end portion of the metal lead portion 17 with the metal shaft 6 is planar with respect to the outer peripheral surface tip portion of the metal shaft 6. It is connected with the joint surface. For example, when joining the metal lead portion 17 and the metal shaft 6 by resistance welding, making the joining surface flat is to apply a pressure force during resistance welding evenly and form a welded portion with few defects. But it is advantageous.
[0034]
On the other hand, the joining of the metal lead portion 17 and the terminal ring 14 is performed after the terminal ring 14 is first assembled to the heater body 1 so as not to interfere when the terminal ring 14 is assembled to the heater body 1 by press fitting or the like. It is desirable to join the end portion of the metal lead portion 17 to, for example, the outer peripheral surface of the assembled terminal ring 14. In this case, resistance welding can be employed as the joining method.
[0035]
Next, the heater body 1 is configured as a rod-shaped heater element in which a resistance heating element 11 is embedded in a ceramic base 13 made of an insulating ceramic. In the present embodiment, the heater body 1 is configured such that a ceramic resistor 10 made of a conductive ceramic is embedded in a ceramic base 13 made of an insulating ceramic. The ceramic resistor 10 is made of a first conductive ceramic disposed at the tip of the heater body 1, and a first resistor portion 11 that functions as a resistance heating element, and a rear side of the first resistor portion 11, respectively. The heater main body 1 is arranged in such a manner as to extend in the direction of the axis O, the tip portion is joined to both end portions in the energizing direction of the first resistor portion 11, and the resistivity is lower than that of the first conductive ceramic. And a pair of second resistor portions 12 and 12 made of two conductive ceramics. The pair of second resistor portions 12 and 12 of the ceramic resistor 10 are formed with branch portions at different positions in the direction of the axis O, respectively, and the branch portions are exposed to the surface of the heater body 1. However, the first heater terminal 12a and the second heater terminal 12b are respectively formed.
[0036]
Note that energization of the resistance heating element 11 can also be performed through embedded lead wires 18 and 19 made of a refractory metal wire such as W embedded in the ceramic substrate 13 as shown in FIG. In this case, the first heater terminal is formed as the exposed lead 18 and the second heater terminal is formed as the exposed portions 18 a and 19 a of the embedded lead 19.
[0037]
Next, in this embodiment, a silicon nitride ceramic is adopted as the insulating ceramic constituting the ceramic base 13. The structure of the silicon nitride ceramic is silicon nitride (Si ₃ N ₄ ) As a main component, and are bonded together by a grain boundary phase derived from a sintering aid component described later. The main phase may be one in which a part of Si or N is substituted with Al or O, or may be one in which metal atoms such as Li, Ca, Mg, and Y are dissolved in the phase. .
[0038]
In the silicon nitride ceramic, at least one selected from the group of elements 3A, 4A, 5A, 3B (for example Al) and 4B (for example Si) in the periodic table and Mg is used as the cation element. It can be made to contain 1-10 mass% in conversion of an oxide in content in the whole body. These components are mainly added in the form of oxides, and are contained in the sintered body mainly in the form of complex oxides such as oxides or silicates. When the sintering aid component is less than 1% by mass, it is difficult to obtain a dense sintered body, and when it exceeds 10% by mass, the strength, toughness or heat resistance is insufficient. The content of the sintering aid component is desirably 2 to 8% by mass. When a rare earth component is used as the sintering aid component, Sc, Y, La, Ce, Pr, Nd, Sm, Eu, Gd, Tb, Dy, Ho, Er, Tm, Yb, and Lu can be used. Among these, Tb, Dy, Ho, Er, Tm, and Yb can be suitably used because they promote the crystallization of the grain boundary phase and improve the high temperature strength.
[0039]
Next, the first resistor portion 11 and the second resistor portions 12 and 12 constituting the ceramic resistor 10 are made of conductive ceramics having different electric resistivity as described above. The method for making the electrical resistivity of the two conductive ceramics different from each other is not particularly limited. For example,
(1) A method in which the same kind of conductive ceramic phase is used and the contents thereof are different from each other;
(2) A method of using different types of conductive ceramic phases having different electric resistivity;
Method by combination of (3) (1) and (2);
In this embodiment, the method (1) is adopted.
[0040]
Examples of the conductive ceramic phase include tungsten carbide (WC) and molybdenum disilicide (MoSi). ₂ ) And tungsten disilicide (WSi) ₂ Etc.) can be used. In this embodiment, WC is adopted. In order to reduce the difference in coefficient of linear expansion from the ceramic substrate 13 and increase the thermal shock resistance, an insulating ceramic phase, which is the main component of the ceramic substrate 13, here, a silicon nitride ceramic phase can be blended. Therefore, by changing the content ratio between the insulating ceramic phase and the conductive ceramic phase, the electrical resistivity of the conductive ceramic constituting the resistor portion can be adjusted to a desired value.
[0041]
Specifically, in the first conductive ceramic that is the material of the first resistor portion 11 that forms the resistance heating portion, the content of the conductive ceramic phase is 10 to 25% by volume, and the remainder is the insulating ceramic phase. Is good. If the content of the conductive ceramic phase exceeds 25% by volume, the conductivity becomes too high and a sufficient calorific value cannot be expected. If the content is less than 10% by volume, the conductivity becomes too low, and similarly the calorific value. Cannot be secured sufficiently.
[0042]
On the other hand, the second resistor parts 12 and 12 serve as a conduction path to the first resistor part 11, and the second conductive ceramic as the material has a content of the conductive ceramic phase of 15 to 30 volumes. %, The balance should be an insulating ceramic phase. If the content of the conductive ceramic phase exceeds 30% by volume, densification by firing becomes difficult and the strength tends to be insufficient, and even if the temperature reaches the normal temperature range for preheating the engine, the electrical resistivity is reduced. In some cases, the rise is insufficient, and the self-saturation function for stabilizing the current density cannot be realized. On the other hand, if it is less than 15% by volume, heat generation in the second resistor portions 12 and 12 becomes too large, leading to deterioration in heat generation efficiency of the first resistor portion 11. In the present embodiment, the content of WC in the first conductive ceramic is 16% by volume (55% by mass), and the content of WC in the second conductive ceramic is 20% by volume (70% by mass) (the balance). Both are silicon nitride ceramics (including sintering aids).
[0043]
In the present embodiment, the ceramic resistor 10 is arranged such that the first resistor portion 11 has a U-shape and the bottom of the U-shape is located on the front end side of the heater body 1. These are rod-like portions that are substantially parallel to each other and extend backward from the both end portions of the U-shaped first resistor portion 11 along the direction of the axis O, respectively.
[0044]
In the ceramic resistor 10, the first resistor portion 11 has a diameter smaller than that of both end portions 11 b and 11 b in order to concentrate current on the end portion 11 a that should be at the highest temperature during operation. And the joining surface 15 with the 2nd resistor part 12 and 12 is formed in the both ends 11b and 11b which became larger diameter than the front-end | tip part 11a.
[0045]
As shown in FIG. 8, in the structure in which the buried lead wires 18 and 19 are arranged in the ceramic, when a heater driving voltage is applied at a high temperature, the metal atoms constituting the buried lead wires 18 and 19 are In some cases, it is consumed by a so-called electromigration effect that is forcedly diffused to the ceramic side under the electrochemical driving force due to the electric field gradient, and breakage or the like is likely to occur. However, since the embedded lead wire is abolished in the configuration of FIG. 2, there is an advantage that it is hardly affected by the electromigration effect.
[0046]
Next, as shown in FIG. 1, as described above, the metal shaft 6 for supplying power to the heater body 1 is disposed in an insulated state from the metal shell 4 inside the rear end portion of the metal shell 4. Yes. In this embodiment, the ceramic ring 31 is arranged between the rear end side outer peripheral surface of the metal shaft 6 and the inner peripheral surface of the metal shell 4, and a glass filling layer 32 is formed and fixed on the rear side thereof. . A ring-side engagement portion 31a is formed on the outer peripheral surface of the ceramic ring 31 in the form of a large diameter portion, and the metal fitting formed in the shape of a circumferential step near the rear end of the inner peripheral surface of the metal shell 4 By engaging with the side engaging portion 4e, it is prevented from slipping forward in the axial direction. Moreover, the outer peripheral surface part which contacts the glass filling layer 32 of the metal axis | shaft 6 is uneven | corrugated by knurling etc. (area | region which shaded in the figure). Further, the rear end portion of the metal shaft 6 extends rearward of the metal shell 4, and the terminal metal fitting 7 is fitted into the extended portion via the insulating bush 8. The terminal fitting 7 is fixed in a conductive state to the outer peripheral surface of the metal shaft 6 by a caulking portion 9 in the circumferential direction.
[0047]
The glow plug 50 is attached to the diesel engine at the attachment portion 5 of the metal shell 4 so that the tip 2 of the heater body 1 is located in the combustion chamber. Then, by connecting the terminal fitting 7 to the power source, the metal shaft 6 → the metal lead 17 → the terminal ring 14 → the ceramic heater 20 (heater body 1 → the metal outer cylinder 3) → the metal shell 4 → (ground through the engine block) The current flows in the order of), the tip 2 of the heater body 1 generates heat, and the combustion chamber can be preheated.
[0048]
Hereinafter, a method for manufacturing the ceramic heater 20 will be described.
First, as shown in FIG. 5A, a resistor powder molding portion 34 to be the ceramic resistor 10 is formed by injection molding. Moreover, the division | segmentation preforming bodies 36 and 37 as a base-molding body formed in the upper-lower separate body are prepared by carrying out the die press molding of the raw material powder for forming the ceramic base | substrate 13 previously. A concave portion 37a having a shape corresponding to the resistor powder molding portion 34 (a concave portion on the side of the divided preform body 36 is not shown in the drawing) is formed on the mating surfaces of the divided preforms 36 and 37. The resistor powder molding portion 34 is accommodated here, and the divided preforms 36 and 37 are fitted on the mating surfaces, and further pressed and compressed to integrate them as shown in FIG. 5 (b). A composite molded body 39 is produced.
[0049]
The composite molded body 39 thus obtained is subjected to a binder removal treatment, and then fired at 1700 ° C. or higher, for example, around about 1800 ° C. by hot pressing or the like to obtain a fired body, and the outer peripheral surface is polished into a cylindrical shape. The heater body 1 is obtained by forming a tapered surface 2p having a smaller diameter toward the end on the outer peripheral surface at the end portion of the first by polishing. The tapered surface 2p is formed such that when the heater body 1 is press-fitted into the metal outer cylinder 3, the taper surface 2p is in a positional relationship in contact with the insertion side edge of the metal outer cylinder 3. . And as shown in FIG. 6, this heater main body 1 is press-fitted and fitted to the metal outer cylinder 3 from the front-end | tip part 2 side in which the taper surface 2p is formed, and the ceramic heater 20 of this invention is obtained. If necessary parts such as the metal lead portion 17 and the metal shell 4 are assembled, the glow plug 50 including the ceramic heater 20 can be obtained.
[0050]
【Example】
Hereinafter, experiments conducted for confirming the effects of the present invention will be described.
First, the heater body 1 having the form shown in FIG. 1 was produced by the method described above. However, the length of the heater body 1 is 40 mm, the outer diameter is 3.5 mm, the thickness of the second resistor parts 12 and 12 is 1.0 mm, and the first heater terminal 12a and the second heater terminal 12b are Each was a circular region having a diameter of 0.8 mm.
[0051]
On the other hand, the metal outer cylinder 3 was produced using the above-mentioned SUS630 (H900 age-hardened product: Hv = about 400). The thickness of the metal outer cylinder 3 was set to 0.9 mm, its inner diameter d1i was set to 3.4 mm, and the initial tightening margin was set to 100 μm. The length of the metal outer tube 3 in the direction of the axis O was 20 mm. In Experiment 1, the tip 2 of the heater body 1 was provided with the tapered surface 2p by outer periphery polishing as described above. As a comparative example, a ceramic heater in which the inclination angle of the tapered surface 2p was adjusted to 0.1 °, 52 °, and 60 ° was also produced. In Experiment 2, an elliptical curved surface portion 1q was formed on the tip 2 of the heater body 1 by peripheral polishing. As a comparative example in Experiment 2, a sample in which the above-described maximum inclination angle was adjusted to 0.1 °, 52 °, and 60 ° was also produced.
[0052]
And the said metal outer cylinder 3 was assembled | attached to the predetermined position of the heater main body 1 by press injection, and the ceramic heater 20 was produced. The press-fitting speed was 5 mm / min for any sample. Moreover, the load required when the metal outer cylinder 3 was press-fitted for each sample was also measured. At the time of press-fitting, an appropriate amount of lubricant (Paskin M30 (trade name: Kyoeisha Chemical Co., Ltd.) is applied to the inner surface of the metal outer cylinder 3, and after the press-fitting, the lubricant is decomposed at 300 ° C. .
[0053]
Then, the series resistance between the first heater terminal and the metal outer cylinder 3 is measured by the four-terminal method, and the contact between the metal outer cylinder 3 and the second heater terminal 12b is reduced by reducing the specific resistance of the heater body 1 that has been measured in advance. The resistance was measured to determine whether or not good conduction was obtained. Those having a value of less than 10 mΩ were evaluated as ◯, those having a value of 10 mΩ or more and less than 50 mΩ as Δ, and those having a value of 50 mΩ or more as x. After the contact resistance measurement was completed, each of the ceramic heaters 20 was attached to the metal shell 4 by press-fitting to produce a glow plug 50. The airtight leak test prescribed | regulated to JIS-D5103 was done about each of them (test conditions are 4 Mpa, 15 second). ◯ when no leak was detected, Δ when less than 0.25 cc, and x when 0.25 cc or more.
[0054]
Thereafter, the ceramic heater 20 was removed from the metal shell 4, the metal outer cylinder 3 was further removed from the heater body 1, and the post-disassembly tightening margin between the metal outer cylinder 3 and the heater body 1 was measured. The post-disassembly tightening allowance was calculated by directly measuring the allowance for removing the terminal ring. On the other hand, when it was difficult to remove the metal shell 4 or the metal outer cylinder 3, the measurement was performed as follows. First, the glow plug 50 is cut into two vertically together with the inner heater body 1 and disassembled, and the inner peripheral surface and outer peripheral surface shape of each piece of the metal outer cylinder 3 and the heater main body 1 after cutting are laser-type 3. Measured with a dimensional shape measuring machine. Then, arc-shaped outline segments of each peripheral surface are extracted from the measurement profile, and the outline segments are circularly interpolated to estimate and restore the peripheral surface before cutting, and the inner diameter and outer diameter of each restored peripheral surface are estimated. The post-decomposition tightening margin was calculated from the diameter. The above results are shown in Tables 1 and 2. Moreover, the principal part of Table 1 and Table 2 was graphed to FIG.11 and FIG.12.
[0055]
[Table 1]

[0056]
[Table 2]

[0057]
In the comparative example in which the inclination angle was set to be larger than 50 °, the airtightness when assembled to the glow plug 50 could not be ensured. On the other hand, by setting the inclination angle to 40 ° or less when the tapered surface 2p is provided and 45 ° or less when the curved surface portion 1q is provided, the post-disassembly tightening allowance value can be secured to 8 μm or more. The contact resistance value could be reduced, and a good conduction state was obtained. This is considered to be a result of the amount of plastic deformation of the metal outer cylinder 3 being increased because the press-fitting load is too large, and the binding force being insufficient. Furthermore, in the case where 15 to 40 μm, which is a more desirable value of the fastening allowance after disassembly, is described, it is the ceramic heater 20 in which the inclination angle of the tapered surface 2p is adjusted to 0.5 ° to 30 °.
[Brief description of the drawings]
FIG. 1 is a longitudinal sectional view showing a glow plug including a ceramic heater according to the present invention.
FIG. 2 is a longitudinal sectional view showing the main part of FIG.
FIG. 3 is an enlarged projection view of the front end portion of the heater body from a direction perpendicular to the axial direction.
FIG. 4 is a schematic view when a heater body is press-fitted into a metal outer cylinder.
FIG. 5 is an explanatory diagram of a manufacturing process of a heater body.
FIG. 6 is an explanatory diagram following FIG. 5;
FIG. 7 is a diagram for explaining a part used for calculating a post-disassembly tightening allowance.
FIG. 8 is a longitudinal sectional view of an essential part showing a first modified example of the glow plug of FIG. 1;
FIG. 9 is a longitudinal sectional view of an essential part showing a second modified example.
10 is a projection view similar to FIG. 3, showing another form of the heater body. FIG.
FIG. 11 is a graph showing the main part of the experimental results.
FIG. 12 is a graph following FIG.
[Explanation of symbols]
1 Heater body
2 Tip
3 Metal outer cylinder
11 Resistance heating element
20 Ceramic heater
1p constant diameter part
1q curved surface
2p taper surface
2m rounding part
O axis
PL reference line

Claims (8)

Exhibits a rod which extends in the axial (O) has tip and (2) a rear end, Heater body internal to the resistance heating element (11) is embedded in the tip of itself (2) ( 1), on the outer circumferential surface of the heater body (1), wherein the tip portion of the heater body (2) to expose said rear end portion, is attached by press fit from the tip (2) A metal outer cylinder (3),
A tapered surface having an inclination angle with respect to the axis (O) of not less than 0.5 ° and not more than 50 ° on the outer peripheral surface of the tip portion (2) of the heater body (1), the diameter of which decreases toward the tip. The ceramic heater (20), wherein 2p) is formed. The ceramic heater (20) according to claim 1, wherein the tip (2) includes the tapered surface (2p) and a spherical rounded portion (2m) following the tapered surface (2p). Exhibits a rod which extends in the axial (O) has tip and (2) a rear end, Heater body internal to the resistance heating element (11) is embedded in the tip of itself (2) ( 1), on the outer circumferential surface of the heater body (1), wherein the tip portion of the heater body (2) to expose said rear end portion, is attached by press fit from the tip (2) A metal outer cylinder (3),
The tip (2) of the heater body (1) has a constant diameter portion (1p) and a shape with different curvature radii that are formed adjacent to the constant diameter portion (1p) and become smaller in diameter toward the tip. A curved surface portion (1q),
Regarding a projection plane from a direction perpendicular to the axis (O),
A reference line (PL) is placed parallel to the outline of the heater body (1) at the constant diameter portion (1p) at a position of 95% of the radius of the heater body (1) at the constant diameter portion (1p). When drawn, the maximum value of the inclination angle of the tangent of the curved surface portion (1q) outside the reference line (PL) with respect to the reference line (PL) is adjusted to be 0.5 ° or more and 50 ° or less. A ceramic heater (20) characterized by comprising: In the disassembled state where the metal outer cylinder (3) is removed from the heater body (1), the inner diameter of the metal outer cylinder (3) is d1, the outer diameter of the heater body (1) is d2, and d2-d1. 4 is 8 μm or more, and is adjusted to a range of 2% or less of the outer diameter of the heater body (1) at the mounting position of the metal outer cylinder (3). Ceramic heater (20). The ceramic heater (20) according to any one of claims 1 to 4, wherein the inclination angle or the maximum value of the inclination angle is adjusted to 0.5 ° or more and 30 ° or less. A glow plug comprising the ceramic heater (20) according to any one of claims 1 to 5. Ceramic heater (20) comprising a rod-shaped heater body (1) having a resistance heating element (11) embedded therein and a metal outer cylinder (3) attached to the outer peripheral surface of the heater body (1). A manufacturing method of
On the outer peripheral surface of the tip end portion (2), which is one end portion in which the resistance heating element (11 ) of the heater body (1) is embedded , a taper surface (2p) whose diameter decreases toward the tip end, Forming the taper surface (2p) so that the insertion side edge of the metal outer cylinder (3) is in contact with the taper surface (2p);
A method of manufacturing a ceramic heater (20), comprising: press-fitting the heater main body (1) into the metal outer cylinder (3) from the tip (2) side. Exhibits a rod which extends in the axial (O) has tip and (2) a rear end, Heater body internal to the resistance heating element (11) is embedded in the tip of itself (2) ( 1) and a manufacturing method of a ceramic heater (20) comprising a metal outer cylinder (3) attached to the outer peripheral surface of the heater body (1),
The diameter is smaller toward the tip, adjacent to the constant diameter portion (1p) of the heater body (1) and having a different curvature radius,
With respect to the projection plane from a direction perpendicular to the axis (O), the constant diameter portion (1p) at the constant diameter portion (1p) is positioned at 95% of the radius of the heater body (1) in the constant diameter portion (1p). When a reference line (PL) is drawn in parallel to the outline of the heater body (1), the maximum inclination angle of the tangent line on the outside of the reference line (PL) with respect to the reference line (PL) is 0. Forming a curved surface portion (1q) of 5 ° or more and 50 ° or less;
Manufacturing the ceramic heater (20) characterized by performing a step of press-fitting and fitting the heater body (1) into the metal outer cylinder (3) from the side where the curved surface portion (1q) is formed. Method.

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