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JP4402871B2 - Manufacturing method of spark plug - Google Patents

Manufacturing method of spark plug Download PDF

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Publication number
JP4402871B2
JP4402871B2 JP2002297067A JP2002297067A JP4402871B2 JP 4402871 B2 JP4402871 B2 JP 4402871B2 JP 2002297067 A JP2002297067 A JP 2002297067A JP 2002297067 A JP2002297067 A JP 2002297067A JP 4402871 B2 JP4402871 B2 JP 4402871B2
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intermediate member
tip
electrode
base material
diameter
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JP2004134209A (en
Inventor
英己 寺村
友聡 加藤
清博 近藤
計良 鳥居
守 無笹
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Niterra Co Ltd
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NGK Spark Plug Co Ltd
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Description

【0001】
【発明の属する技術分野】
本発明はスパークプラグの製造方法に関する。
【0002】
【従来の技術】
従来のスパークプラグは、筒状の主体金具を備えており、この主体金具内には、主体金具の軸方向に延在し、両端を主体金具の両端から突出させた筒状の絶縁体が固定されている。また、主体金具の軸方向には中心電極が延在し、中心電極の先端は絶縁体の先端から突出され、中心電極の後端は絶縁体内に固定されている。一方、主体金具には接地電極の一端が固定され、接地電極の他端部は中心電極との間に放電ギャップを形成している。中心電極及び接地電極は、各々Inconel(登録商標)600等のNi合金等からなる電極母材と、放電ギャップ側を形成する位置にIrを含むPt合金等の耐火花消耗材からなるチップとを有している。また、中心電極及び接地電極の少なくとも一方の電極母材とチップとの間には、電極母材及びチップの中間的な融点又は線膨張係数をもつ中間部材が設けられている(特許文献1)。
【0003】
このようなスパークプラグは以下の製造方法により製造されていた。すなわち、特許文献1では、まず第1工程として、電極母材及びチップの中間的な融点又は線膨張係数をもつ円柱棒状の中間材を用意する。そして、第2工程として、その中間材の先端に円柱状のチップをTIG溶接又はレーザ溶接し、チップ付き中間材を得る。この後、第3工程として、このチップ付き中間材を切断し、チップ付き中間部材とする。こうして得られるチップ付き中間部材は、円柱状をなす中間部材と、この中間部材の第1面に溶接された円柱状のチップとからなる。次いで、第4工程として、このチップ付き中間部材における中間部材の第2面を電極母材の放電ギャップ側の接合面に抵抗溶接し、中心電極又は接地電極とする。
【0004】
このスパークプラグでは、耐火花消耗材からなるチップが消耗に強くて高い耐久性を発揮する一方、そのチップと電極母材との熱応力差に基づくチップが電極母材に対して接合し難いという不具合を中間部材によって解決している。
【0005】
【特許文献1】
特開平8−298178号公報
【0006】
【発明が解決しようとする課題】
しかし、上記従来のスパークプラグでは、中心電極及び接地電極の少なくとも一方におけるチップと電極母材とのより強固な接合が求められている。
【0007】
すなわち、従来の製造方法では、円柱棒状の中間材にチップをTIG溶接又はレーザ溶接した後、得られたチップ付き中間材を切断することにより、チップ付き中間部材を得ている。このため、こうして得られるスパークプラグでは、チップ付き中間材の切断の際に溶接部にクラックが発生するおそれがあり、そのクラックによってチップと中間部材との接合力が弱められるおそれがある。
【0008】
また、チップ付き中間材を切断してチップ付き中間部材を得る際、チップの先端面とチップ付き中間部材の第2面とを互いに平行に切断することが困難である。このため、チップの先端面とチップ付き中間部材の第2面とが互いに平行でないチップ付き中間部材をスパークプラグの例えば中心電極として使用した場合には、チップの縁部で放電ギャップが形成され、チップ自体の耐火花消耗性が低下してしまうおそれがある。
【0009】
本発明は、上記従来の実情に鑑みてなされたものであって、中心電極及び接地電極の少なくとも一方における電極母材とチップとのより強固な接合と、チップ自体の耐火花消耗性の維持とを実現可能なスパークプラグの製造方法を提供することを解決すべき課題としている。
【0010】
【課題を解決するための手段】
本発明のスパークプラグの製造方法は、筒状の主体金具と、該主体金具の軸方向に延在し、両端を該主体金具の両端から突出させて該主体金具内に固定された筒状の絶縁体と、該主体金具の軸方向に延在し、先端を該絶縁体の先端から突出させて後端が該絶縁体内に固定された中心電極と、該主体金具に一端が固定され、他端部と該中心電極との間に放電ギャップを形成する接地電極とからなり、該中心電極及び該接地電極は各々電極母材と該電極母材の該放電ギャップを形成する位置に耐火花消耗材からなるチップとを有し、該中心電極及び該接地電極の少なくとも一方の該電極母材と該チップとの間に該電極母材及び該チップの中間的な融点又は線膨張係数をもつ中間部材が設けられたスパークプラグの製造方法において、
第1面と該第1面に平行な第2面とをもつ前記中間部材を作製する第1工程と、
該中間部材の該第1面に該チップをレーザにより溶接し、チップ付き中間部材とする第2工程と、
前記中心電極及び前記接地電極の少なくとも一方における該電極母材の前記放電ギャップを形成する位置の接合面に該チップ付き中間部材の該第2面を抵抗溶接する第3工程とを備え
前記中間部材は、底面で前記第2面を形成するフランジ部と、該フランジ部から該フランジ部より小径で立ち上がり、上面で前記第1面を形成する柱部とからなり、
前記第3工程では、前記フランジ部に所定の加圧力を加えるとともに、前記チップ付き中間部材における前記チップと前記中間部材との間の溶接部に加圧力が加わらないように抵抗溶接を行うことを特徴とする。
【0011】
本発明の製造方法では、第1工程で第1面と第1面に平行な第2面とをもつ中間部材を作製し、第2工程でその中間部材の第1面にチップをレーザにより溶接し、チップ付き中間部材とする。レーザで溶接することにより、Ir、Pt、Ru合金等の様々なチップを中間部材に強固に接合することができる。そして、第3工程において、中心電極及び接地電極の少なくとも一方における電極母材の放電ギャップを形成する位置の接合面にそのチップ付き中間部材の第2面を溶接する。ここで、第1工程で用意される中間部材は、中心電極及び接地電極の少なくとも一方の電極母材とチップとの中間的な融点又は線膨張係数を有している。このため、こうして得られるスパークプラグでは、中間部材に生じる熱応力により電極母材に生じる熱応力とチップに生じる熱応力との差異を小さくすることができる。このため、中間部材自体に歪みが生じ難く、電極母材と中間部材との間又は中間部材とチップとの間に剥離が生じ難い。
本発明の製造方法では、第3工程を抵抗溶接により行なう。電極母材とチップとの中間的な融点又は線膨張係数をもつ中間部材では、第3工程において、大がかりな設備であるレーザによる溶接を行なわなくても、汎用的である抵抗溶接によって十分な溶接強度を確保できるからである。
【0012】
2工程で得られるチップ付き中間部材は、中間部材の第1面にチップがレーザにより溶接されている。このため、チップ付き中間部材におけるチップと中間部材との接合力は高くなっている。そして、第3工程では、そのチップ付き中間部材をそのまま電極母材に溶接しており、特許文献1記載の製造方法のように、チップ付き中間材を切断したチップ付き中間部材を溶接することとはしていない。このため、こうして得られるスパークプラグでは、チップ付き中間部材の溶接部にクラックが発生せず、チップと中間部材との接合力が維持される。
【0013】
さらに、第1工程で第1面と第1面に平行な第2面とをもつ中間部材を作製するため、第2工程で得られるチップ付き中間部材は、チップの先端面とチップ付き中間部材の第2面とを互いに平行に維持しやすく、ひいてはチップの先端面と電極母材の接合面とを互いに平行に維持しやすい。このため、このチップ付き中間部材をスパークプラグの例えば中心電極として使用した場合においても、チップの縁部で放電ギャップが形成され難く、チップ自体の耐火花消耗性を維持しやすい。
【0014】
したがって、本発明のスパークプラグの製造方法では、中心電極及び接地電極の少なくとも一方における電極母材とチップとのより強固な接合と、チップ自体の耐火花消耗性の維持とを実現することができる
【0017】
また、中間部材は、底面で第2面を形成するフランジ部と、フランジ部からそのフランジ部より小径で立ち上がり、上面で第1面を形成する円柱部とからなるので、フランジ部によって第2面の面積を大きくできる。このため、中間部材の第2面が電極母材の放電ギャップ側の接合面と大きな面積で溶接されることとなるため、抵抗溶接における中間部材と電極母材との接合力が確実に向上する。また、円柱部によって中間部材とチップとの溶接性を向上させることができる。その際、フランジ部が第1面側に突出するテーパ面をもつことがより好ましい。フランジ部が第1面側に突出するテーパ面をもつことにより、中間部材の強度を確保することができる。
【0018】
本発明の製造方法では、チップは円柱状をなし、第1面はチップの底面を含む円形であり、第1面の直径はチップの直径よりも大きいことが好ましい。特に、第1面の直径をd1、チップの直径をD1としたとき、D1<d1≦D1+0.6(mm)であることが好ましい。こうであれば、チップの底面と中間部材の第1面とをレーザ溶接により溶融することにより、チップと中間部材とを強固に接合しやすい。発明者らの試験結果によれば、第1面の直径がチップの直径以下の場合(d1≦D1の場合)、チップと中間部材との溶融のバランスが悪くなり、チップと中間部材とを強固に接合しにくい。また、第1面の直径がチップの直径より0.6mmを超えた大きさである場合(D1+0.6<d1)、レーザの焦点を確保しにくく、チップと中間部材とを強固に接合し難い。
【0019】
また、第2面は中心電極における電極母材の直径又は接地電極における電極母材の幅内にある円形であり、第2面の直径は中心電極における電極母材の直径又は接地電極における電極母材の幅よりも小さいことが好ましい。電極母材の直径は中心電極にチップ付き中間部材を溶接する場合を意図している。電極母材の幅は接地電極にチップ付き中間部材を溶接する場合を意図している。こうであれば、中間部材の第2面を最大に利用することができるからである。特に、第1面の直径をd1、第2面の直径をd2、中心電極における電極母材の直径又は接地電極における電極母材の幅をD2としたとき、d1+0.3<d2≦D2(mm)であることが好ましい。こうであれば、抵抗溶接の際の中間部材の第2面を最大に利用することができ、チップ付き中間部材と電極母材とを強固に接合することができる。発明者らの試験結果によれば、第2面の直径と第1面の直径との差が0.3mm以下の場合、接合面が小さくなることから、チップ付き中間部材を強固に電極母材に接合し難い。その上、チップ付き中間部材の側面によりチップ付き中間部材を軸方向に押圧する場合、その押圧が行われ難くなることから、チップ付き中間部材を強固に電極母材に接合することが困難となる。また、第2面の直径が中心電極における電極母材の直径又は接地電極における電極母材の幅より大きい場合、抵抗溶接後の中間部材の第2面が中心電極又は接地電極からはみ出てしまい、スパークプラグの着火性が低下する。
【0020】
本発明の製造方法では、第1工程における中間部材は電極母材の成分を含むことが好ましい。こうであれば、中間部材と電極母材とが溶接によって相溶して強固に接合しやすい。また、その中間部材はチップの成分を含むことも好ましい。こうであれば、中間部材とチップとがレーザ溶接によって相溶して強固に接合しやすい。
【0021】
本発明の製造方法は、第3工程を接地電極について行なう場合に効果が顕著である。接地電極側にチップを設けようとする場合、接地電極の電極母材にチップを直接レーザ溶接することはレーザの入射角の関係上困難である(例えば、特開2001−135456号公報)。これに対し、本発明の製造方法のように、予め中間部材とチップとを接合したチップ付き中間部材を用意し、このチップ付き中間部材を接地電極の電極母材に溶接するとすれば、レーザの入射角の制限を受けることなく接地電極側にチップを設けることができるからである。
【0031】
【発明の実施の形態】
以下、本発明のスパークプラグの製造方法を具体化した実施形態を図面1〜を参照しつつ説明する。
【0032】
先ず、図1に示すように、第1工程S10において、40質量%のNiを含有するIr合金からなる中間部材10を製作する。その中間部材10は、図2に示すように、直径1.5(mm)、周囲の厚さ0.2(mm)のフランジ部12と、フランジ部12の上面より立ち上がり、直径0.8(mm)、厚さ0.2(mm)の円柱部14とから構成されている。フランジ部12の底面が第2面12aであり、円柱部14の上面が第1面14aである。第1面14a及び第2面12aは中間部材10の軸と直交している。フランジ部12の上面は第1面14a側に突出するテーパ面12bを形成している。
【0033】
次に、図1に示す第2工程S20では、図3に示すように、20質量%のRh、5質量%のPt又は1.7質量%のY23を含むIr合金製の耐火花消耗材からなるチップ16を製作する。このチップ16は直径0.6(mm)、厚さ0.8(mm)の円柱状をなしており、チップ16の先端面と底面とは互いに平行で、チップ16の軸と直交している。
【0034】
そして、中間部材10の第1面14aにこのチップ16を載せ、これらを図示しないレーザで溶接する。この際、図7に示す中心電極30に接合するものにしろ、接地電極40に接合するものにしろ、レーザの入射角の制限を受けずに、図3に示すチップ付き中間部材20を得ることができる。また、レーザにより中間部材10とチップ16とを接合しているため、これらの接合力が高い。特に、中間部材10の第1面14aの直径d1とチップ16の直径D1との関係がD1<d1≦D1+0.6(mm)になっていることから、レーザの焦点を確保しやすく、チップ16を中間部材10に強固に接合することができる。また、中間部材10がチップ16の成分であるIrを含むため、チップ付き中間部材20は中間部材とチップ16とが相溶して強固に接合されたものとなる。
【0035】
次いで、図1に示す第3工程S30では、図4に示すように、中心電極30にチップ付き中間部材20を抵抗溶接する。この中心電極30は、Inconel(登録商標)600のNi合金を電極母材とする直径2.5(mm)のものである。その際、まず中心電極30の放電ギャップ側の接合面32にチップ付き中間部材20の中間部材10の第2面12aを配置する。そして、中間部材10のフランジ部12上に電気抵抗溶接機50を設け、所定の加圧力の下、所定の電流を通電する。こうして、図5に示すように、中心電極30にチップ付き中間部材20を抵抗溶接する。その後、図7に示すように、先端が突出するように絶縁体62内に中心電極30を組み込み、絶縁体62内の中心電極30の後端に端子63を挿入する。そして、これらを主体金具60に組み込む。
【0036】
同様に、図7に示すように、予め主体金具60に溶接された接地電極40を作製する。この接地電極40は、中心電極30と同様、Inconel(登録商標)600のNi合金を電極母材とする幅2.5(mm)のものである。そして、図4に示すように、その接地電極40にチップ付き中間部材20の中間部材10の第2面12aを抵抗溶接する。その際、まず接地電極40の放電ギャップ側の接合面42にチップ付き中間部材20の中間部材10の第2面12aを配置し、同様に抵抗溶接する。この際、チップ付き中間部材20を接地電極40の電極母材に抵抗溶接すればよいため、レーザの入射角の制限を受けることなく接地電極40側にチップ16を設けることができる。
【0037】
そして、図6に示すように、チップ付き中間部材20を溶接した接地電極40の電極母材の一端を中心電極30側に屈曲する。こうして、図7に示すスパークプラグが得られる。
【0038】
これらの際、中間部材10は中心電極30及び接地電極40の電極母材とチップ20との中間的な融点又は線膨張係数を有している。このため、このスパークプラグでは、中間部材10に生じる熱応力により中心電極30及び接地電極40の電極母材に生じる熱応力とチップ16に生じる熱応力との差異が小さくなっている。このため、中間部材10自体に歪みが生じ難く、中心電極30又は接地電極40の電極母材と中間部材10との間や中間部材10とチップ16との間に剥離が生じ難い。また、電極母材とチップ16との中間的な融点又は線膨張係数をもつ中間部材10では、第3工程S30において、大がかりな設備であるレーザによる溶接を行なわなくても、汎用的である抵抗溶接によって十分な溶接強度を確保できる。
【0039】
また、第2工程S20で得られるチップ付き中間部材20は、中間部材10の第1面14aにチップ16がレーザにより溶接されている。このため、チップ付き中間部材20におけるチップ16と中間部材10との接合力は高くなっている。そして、第3工程S30では、そのチップ付き中間部材20をそのまま中心電極30及び接地電極40の電極母材に溶接しており、従来のようにチップ付き中間材を切断したチップ付き中間部材を溶接することとはしていない。このため、こうして得られるスパークプラグでは、チップ16と中間部材10との間の溶接部にクラックが発生せず、チップ16と中間部材10との接合力が維持されている。
【0040】
さらに、第1工程S10で第1面14aと第1面14aに平行な第2面12aとをもつ中間部材10を作製するため、第2工程S20で得られるチップ付き中間部材20は、チップ16の先端面とチップ付き中間部材20の第2面12aとを互いに平行に維持しやすく、ひいてはチップ16の先端面と電極母材の接合面とを互いに平行に維持しやすい。このため、このチップ付き中間部材20をスパークプラグの中心電極30として使用した場合においても、チップ16の縁部で放電ギャップが形成され難く、チップ16自体の耐火花消耗性を維持しやすい。
【0041】
特に、この製造方法では、中間部材10の第1面14aの直径d1及び第2面12aの直径d2と中心電極30における電極母材の直径又は接地電極40における電極母材の幅D2との関係がd1+0.3<d2≦D2(mm)になっていることから、抵抗溶接の際の中間部材10の第2面12aを最大に利用することができ、チップ付き中間部材20と電極母材とを強固に接合することができる。また、中間部材10が接地電極40の電極母材の成分であるNiを含むため、チップ付き中間部材20は中間部材と接地電極40の電極母材とが相溶して強固に接合されたものとなる。
【0042】
また、中間部材10は、図2に示すように、第1面14a及び第2面12aが中間部材10の軸と直交するものであるとともに、第1面14aの最大径が第2面12aの最大径よりも小さい台座形状をなしている。そして、チップ付き中間部材20は、図3に示すように、円柱状のチップ16が溶接された中間部材10の第1面14aよりも、中心電極30及び接地電極40の電極母材の放電ギャップ側に溶接された中間部材10の第2面12aが大径である。このため、中間部材10の第2面12aが中心電極30及び接地電極40の電極母材の放電ギャップ側の接合面32、42と大きな面積で抵抗溶接されることとなるため、中間部材10とその電極母材との接合力が確実に向上する。
【0043】
さらに、この製造方法では、中間部材10が底面で第2面12aを形成するフランジ部12と、フランジ部12からそのフランジ部12より小径で立ち上がり、上面で第1面14aを形成する円柱部14とからなるため、フランジ部12によって第2面12aの面積を大きくしながら、円柱部14によって中間部材10とチップ16との溶接性を向上させることができる。特に、フランジ部12が第1面14a側に突出するテーパ面12bをもつため、中間部材10の強度を確保している。
【0044】
したがって、このスパークプラグの製造方法では、中心電極30及び接地電極40における電極母材とチップ16とのより強固な接合と、チップ16自体の耐火花消耗性の維持とを実現することができる。
【0045】
こうして得られたスパークプラグは、図7に示すように、筒状の主体金具60を備えており、この主体金具60内には、主体金具60の軸方向に延在し、両端を主体金具60の両端から突出させた筒状の絶縁体62が固定されている。また、主体金具60の軸方向には中心電極30が延在し、中心電極30の先端は絶縁体62の先端から突出され、中心電極30の後端は絶縁体62内に固定されている。一方、主体金具60には接地電極40の一端が固定され、接地電極40の他端部は中心電極30との間に放電ギャップを形成している。中心電極30及び接地電極40にはチップ付き中間部材20が放電ギャップを形成しながら対向して設けられている。
【0046】
このスパークプラグでは、中間部材10が台座形状であるため、中間部材10の第2面12aが電極母材の放電ギャップ側の接合面と大きな面積で溶接され、中間部材10と中心電極30及び接地電極40の電極母材との接合力が確実に向上している。また、このスパークプラグでは、中間部材10の第1面14aと第2面12aとが互いに平行であるため、チップ16の先端面と中間部材10の第2面12aとを互いに平行に維持しやすく、ひいてはチップ16の先端面と電極母材の接合面とを互いに平行に維持しやすい。このため、チップ16の縁部で放電ギャップが形成され難く、チップ16自体の耐火花消耗性を維持しやすい。
【0047】
したがって、このスパークプラグは、チップ16によって発揮される耐久性を長期に亘って維持することができる。
【0048】
なお、実施形態の製造方法では、例えば、図8(a)〜(f)に示すように、様々な形状の中間部材10を採用することもできる。図8(a)に示す中間部材71は上記実施形態のものよりテーパ面12bの傾斜が大きいものである。図8(b)に示す中間部材72はフランジ部12が周囲の厚さを有していないものである。図8(c)に示す中間部材73は円柱部14を有さないものである。図8(d)に示す中間部材74は、フランジ部12が周囲の厚さを有さず、かつ円柱部14を有さないものである。図8(e)に示す中間部材75は、上面が平坦なフランジ部12と、フランジ部12の上面より立ち上がる円柱部14とから構成されたものである。図8(f)に示す中間部材76は、図8(e)のものに比して円柱部14の厚さが小さいものである。このような中間部材71〜76であっても、本発明の効果を奏することができる。
【図面の簡単な説明】
【図1】実施形態に係り、スパークプラグの製造方法の工程図である。
【図2】実施形態に係り、中間部材の側面図である。
【図3】実施形態に係り、チップ付き中間部材の側面図である。
【図4】実施形態に係り、抵抗溶接時のチップ付き中間部材の側面図である。
【図5】実施形態に係り、中心電極又は接地電極の部分拡大断面図である。
【図6】実施形態に係り、スパークプラグの一部拡大側面図である。
【図7】実施形態に係り、スパークプラグの一部断面の側面図である。
【図8】実施形態に係り、他の中間部材の側面図である。
【符号の説明】
60…主体金具
62…絶縁体
30…中心電極
40…接地電極
16…チップ
10、71〜76…中間部材
S10…第1工程
14a…第1面
20…チップ付き中間部材
S20…第2工程
32、34…接合面
12a…第2面
S30…第3工程
12…フランジ部
14…円柱部
12b…テーパ面
[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a method of manufacturing a spark plug.
[0002]
[Prior art]
Conventional spark plugs are provided with a cylindrical metal shell, and a cylindrical insulator extending in the axial direction of the metal shell and projecting from both ends of the metal shell is fixed in the metal shell. Has been. The central electrode extends in the axial direction of the metal shell, the tip of the center electrode protrudes from the tip of the insulator, and the rear end of the center electrode is fixed in the insulator. On the other hand, one end of the ground electrode is fixed to the metal shell, and a discharge gap is formed between the other end of the ground electrode and the center electrode. The center electrode and the ground electrode are each made of an electrode base material made of Ni alloy or the like such as Inconel (registered trademark) 600 and a chip made of a spark consumable material such as Pt alloy containing Ir at a position forming the discharge gap side. Have. An intermediate member having an intermediate melting point or linear expansion coefficient between the electrode base material and the tip is provided between at least one of the center electrode and the ground electrode and the tip (Patent Document 1). .
[0003]
Such a spark plug has been manufactured by the following manufacturing method. That is, in Patent Document 1, first, as a first step, a cylindrical rod-shaped intermediate material having an intermediate melting point or linear expansion coefficient between the electrode base material and the tip is prepared. And as a 2nd process, a cylindrical chip | tip is TIG-welded or laser-welded to the front-end | tip of the intermediate material, and the intermediate material with a chip | tip is obtained. Thereafter, as a third step, the chip-attached intermediate material is cut into a chip-attached intermediate member. The tip-attached intermediate member thus obtained includes a columnar intermediate member and a columnar tip welded to the first surface of the intermediate member. Next, as a fourth step, the second surface of the intermediate member of the intermediate member with a tip is resistance-welded to the joint surface on the discharge gap side of the electrode base material to form a center electrode or a ground electrode.
[0004]
In this spark plug, the tip made of a spark-resistant consumable material is resistant to wear and exhibits high durability, while the tip based on the thermal stress difference between the tip and the electrode base material is difficult to join to the electrode base material. The problem is solved by the intermediate member.
[0005]
[Patent Document 1]
JP-A-8-298178 [0006]
[Problems to be solved by the invention]
However, in the conventional spark plug described above, stronger bonding between the tip and the electrode base material in at least one of the center electrode and the ground electrode is required.
[0007]
That is, in the conventional manufacturing method, the tip-attached intermediate member is obtained by cutting the obtained tip-attached intermediate member after TIG welding or laser welding of the tip to the cylindrical rod-like intermediate member. For this reason, in the spark plug obtained in this way, there is a possibility that a crack is generated in the welded portion when the intermediate material with the tip is cut, and the joining force between the tip and the intermediate member may be weakened by the crack.
[0008]
Further, when the intermediate member with the chip is cut to obtain the intermediate member with the chip, it is difficult to cut the tip end surface of the chip and the second surface of the intermediate member with the chip in parallel with each other. For this reason, when an intermediate member with a chip in which the tip end surface of the chip and the second surface of the intermediate member with a chip are not parallel to each other is used as, for example, the center electrode of the spark plug, a discharge gap is formed at the edge of the chip, There is a possibility that the spark wear resistance of the chip itself may be reduced.
[0009]
The present invention has been made in view of the above-described conventional situation, and more firmly joining the electrode base material and the chip in at least one of the center electrode and the ground electrode, and maintaining the spark consumption of the chip itself, and an object to be achieved by providing a method for manufacturing a spark plug capable of realizing.
[0010]
[Means for Solving the Problems]
The spark plug manufacturing method of the present invention includes a cylindrical metal shell, and a cylindrical metal shell that extends in the axial direction of the metal shell and is fixed in the metal shell with both ends projecting from both ends of the metal shell. An insulator, a central electrode that extends in the axial direction of the metal shell, has a tip protruded from the tip of the insulator, and a rear end is fixed in the insulator; one end is fixed to the metal shell; A ground electrode that forms a discharge gap between the end portion and the center electrode, and the center electrode and the ground electrode are spark-resistant at positions that form the discharge gap of the electrode base material and the electrode base material, respectively. An intermediate having an intermediate melting point or linear expansion coefficient between the electrode base material and the tip between the tip base material and the tip of at least one of the center electrode and the ground electrode. In the method of manufacturing a spark plug provided with a member,
A first step of producing the intermediate member having a first surface and a second surface parallel to the first surface;
A second step of welding the tip to the first surface of the intermediate member with a laser to form an intermediate member with a tip;
A third step of resistance welding the second surface of the intermediate member with the tip to a joint surface at a position where the discharge gap of the electrode base material is formed in at least one of the center electrode and the ground electrode ;
The intermediate member includes a flange portion that forms the second surface on the bottom surface, and a column portion that rises from the flange portion with a smaller diameter than the flange portion and forms the first surface on the top surface,
In the third step, a predetermined pressure is applied to the flange portion, and resistance welding is performed so that no pressure is applied to a weld portion between the tip and the intermediate member in the intermediate member with the tip. Features.
[0011]
In the manufacturing method of the present invention, an intermediate member having a first surface and a second surface parallel to the first surface is produced in the first step, and a chip is welded to the first surface of the intermediate member by a laser in the second step. And an intermediate member with a tip. By welding with a laser, various chips such as Ir, Pt, and Ru alloy can be firmly bonded to the intermediate member. In the third step, the second surface of the tip-attached intermediate member is welded to the joint surface at the position where the discharge gap of the electrode base material is formed in at least one of the center electrode and the ground electrode. Here, the intermediate member prepared in the first step has an intermediate melting point or linear expansion coefficient between at least one of the center electrode and the ground electrode and the tip. For this reason, in the spark plug obtained in this way, the difference between the thermal stress generated in the electrode base material and the thermal stress generated in the chip due to the thermal stress generated in the intermediate member can be reduced. For this reason, it is difficult for distortion to occur in the intermediate member itself, and separation between the electrode base material and the intermediate member or between the intermediate member and the chip is difficult to occur.
In the manufacturing method of the present invention, the third step is performed by resistance welding. In the intermediate member having an intermediate melting point or linear expansion coefficient between the electrode base material and the chip, sufficient welding can be performed by general-purpose resistance welding without performing laser welding, which is a large facility, in the third step. This is because the strength can be secured.
[0012]
In the intermediate member with tip obtained in the second step, the tip is welded to the first surface of the intermediate member by a laser. For this reason, the bonding force between the tip and the intermediate member in the tip-attached intermediate member is high. In the third step, the intermediate member with tip is directly welded to the electrode base material, and the intermediate member with tip obtained by cutting the intermediate member with tip is welded as in the manufacturing method described in Patent Document 1. I have not done it. For this reason, in the spark plug obtained in this way, cracks do not occur in the welded portion of the tip-attached intermediate member, and the joining force between the tip and the intermediate member is maintained.
[0013]
Furthermore, in order to produce an intermediate member having a first surface and a second surface parallel to the first surface in the first step, the intermediate member with chip obtained in the second step is the tip surface of the chip and the intermediate member with chip. It is easy to maintain the second surface of the chip in parallel with each other, and in turn, it is easy to maintain the tip surface of the chip and the bonding surface of the electrode base material in parallel with each other. For this reason, even when this intermediate member with a chip is used as, for example, a center electrode of a spark plug, it is difficult to form a discharge gap at the edge of the chip, and it is easy to maintain the spark wear resistance of the chip itself.
[0014]
Therefore, in the spark plug manufacturing method of the present invention, it is possible to achieve stronger bonding between the electrode base material and the chip in at least one of the center electrode and the ground electrode and maintenance of the spark wear resistance of the chip itself. .
[0017]
The intermediate member includes a flange portion that forms the second surface on the bottom surface, and a cylindrical portion that rises from the flange portion with a smaller diameter than the flange portion and forms the first surface on the top surface. The area of can be increased. For this reason, since the second surface of the intermediate member is welded to the joining surface on the discharge gap side of the electrode base material in a large area, the joining force between the intermediate member and the electrode base material in resistance welding is reliably improved. . Further, the weldability between the intermediate member and the tip can be improved by the cylindrical portion. In that case, it is more preferable that the flange portion has a tapered surface protruding to the first surface side. Since the flange portion has a tapered surface protruding to the first surface side, the strength of the intermediate member can be ensured.
[0018]
In the manufacturing method of the present invention, it is preferable that the chip has a cylindrical shape, the first surface has a circular shape including the bottom surface of the chip, and the diameter of the first surface is larger than the diameter of the chip. In particular, when the diameter of the first surface is d1 and the diameter of the chip is D1, it is preferable that D1 <d1 ≦ D1 + 0.6 (mm). In this case, it is easy to firmly join the tip and the intermediate member by melting the bottom surface of the tip and the first surface of the intermediate member by laser welding. According to the test results of the inventors, when the diameter of the first surface is equal to or smaller than the diameter of the chip (when d1 ≦ D1), the melting balance between the chip and the intermediate member is deteriorated, and the chip and the intermediate member are strengthened. It is hard to join to. Further, when the diameter of the first surface is larger than the diameter of the chip by 0.6 mm (D1 + 0.6 <d1), it is difficult to secure the focal point of the laser and it is difficult to firmly bond the chip and the intermediate member. .
[0019]
The second surface is a circle within the diameter of the electrode base material in the center electrode or the width of the electrode base material in the ground electrode, and the diameter of the second surface is the diameter of the electrode base material in the center electrode or the electrode base in the ground electrode. It is preferably smaller than the width of the material. The diameter of the electrode base material is intended when the intermediate member with the tip is welded to the center electrode. The width of the electrode base material is intended when the intermediate member with a tip is welded to the ground electrode. This is because the second surface of the intermediate member can be utilized to the maximum. In particular, when the diameter of the first surface is d1, the diameter of the second surface is d2, and the diameter of the electrode base material at the center electrode or the width of the electrode base material at the ground electrode is D2, d1 + 0.3 <d2 ≦ D2 (mm ) Is preferable. If it is like this, the 2nd surface of the intermediate member in the case of resistance welding can be utilized to the maximum, and the intermediate member with a chip | tip and an electrode base material can be joined firmly. According to the test results of the inventors, when the difference between the diameter of the second surface and the diameter of the first surface is 0.3 mm or less, the joint surface becomes small, so that the intermediate member with the chip is firmly attached to the electrode base material. It is difficult to join. In addition, when the intermediate member with the tip is pressed in the axial direction by the side surface of the intermediate member with the tip, it becomes difficult to press the intermediate member with the tip, so that it becomes difficult to firmly join the intermediate member with the tip to the electrode base material. . Further, when the diameter of the second surface is larger than the diameter of the electrode base material in the center electrode or the width of the electrode base material in the ground electrode, the second surface of the intermediate member after resistance welding protrudes from the center electrode or the ground electrode, Spark plug ignitability is reduced.
[0020]
In the manufacturing method of this invention, it is preferable that the intermediate member in a 1st process contains the component of an electrode base material. In this case, the intermediate member and the electrode base material are compatible with each other by welding and are easily joined firmly. In addition, the intermediate member preferably contains a component of the chip. In this case, the intermediate member and the tip are compatible with each other by laser welding and are easily joined firmly.
[0021]
The manufacturing method of the present invention is remarkable when the third step is performed on the ground electrode. When a tip is to be provided on the ground electrode side, it is difficult to directly laser weld the tip to the electrode base material of the ground electrode because of the incident angle of the laser (for example, JP-A-2001-135456). On the other hand, as in the manufacturing method of the present invention, if an intermediate member with a tip in which an intermediate member and a tip are joined in advance is prepared and this intermediate member with a tip is welded to the electrode base material of the ground electrode, the laser This is because the chip can be provided on the ground electrode side without being limited by the incident angle.
[0031]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, an embodiment embodying the method of manufacturing the spark plug of the present invention with reference to the drawings 1-8.
[0032]
First, as shown in FIG. 1, in the first step S10, an intermediate member 10 made of an Ir alloy containing 40% by mass of Ni is manufactured. As shown in FIG. 2, the intermediate member 10 rises from a flange portion 12 having a diameter of 1.5 (mm) and a surrounding thickness of 0.2 (mm), and an upper surface of the flange portion 12, and has a diameter of 0.8 ( mm) and a cylindrical portion 14 having a thickness of 0.2 (mm). The bottom surface of the flange portion 12 is the second surface 12a, and the top surface of the cylindrical portion 14 is the first surface 14a. The first surface 14 a and the second surface 12 a are orthogonal to the axis of the intermediate member 10. The upper surface of the flange portion 12 forms a tapered surface 12b that protrudes toward the first surface 14a.
[0033]
Next, in the second step S20 shown in FIG. 1, as shown in FIG. 3, a refractory spark made of an Ir alloy containing 20% by mass of Rh, 5% by mass of Pt or 1.7% by mass of Y 2 O 3 is used. A chip 16 made of a consumable material is manufactured. The chip 16 has a cylindrical shape with a diameter of 0.6 (mm) and a thickness of 0.8 (mm), and the tip surface and the bottom surface of the chip 16 are parallel to each other and orthogonal to the axis of the chip 16. .
[0034]
And this chip | tip 16 is mounted on the 1st surface 14a of the intermediate member 10, and these are welded with the laser which is not shown in figure. At this time, whether it is bonded to the center electrode 30 shown in FIG. 7 or to the ground electrode 40, the intermediate member 20 with a chip shown in FIG. 3 is obtained without being limited by the incident angle of the laser. Can do. Further, since the intermediate member 10 and the chip 16 are bonded by the laser, their bonding force is high. In particular, since the relationship between the diameter d1 of the first surface 14a of the intermediate member 10 and the diameter D1 of the chip 16 is D1 <d1 ≦ D1 + 0.6 (mm), it is easy to secure the focal point of the laser, and the chip 16 Can be firmly bonded to the intermediate member 10. Moreover, since the intermediate member 10 contains Ir which is a component of the chip 16, the intermediate member 20 with the chip is a member in which the intermediate member and the chip 16 are mixed and firmly bonded.
[0035]
Next, in a third step S30 shown in FIG. 1, the tip-attached intermediate member 20 is resistance-welded to the center electrode 30 as shown in FIG. The center electrode 30 has a diameter of 2.5 (mm) using a Ni alloy of Inconel (registered trademark) 600 as an electrode base material. At that time, first, the second surface 12a of the intermediate member 10 of the intermediate member 20 with the tip is disposed on the joint surface 32 of the center electrode 30 on the discharge gap side. Then, an electric resistance welder 50 is provided on the flange portion 12 of the intermediate member 10, and a predetermined current is applied under a predetermined pressure. Thus, as shown in FIG. 5, the tip-attached intermediate member 20 is resistance-welded to the center electrode 30. After that, as shown in FIG. 7, the center electrode 30 is incorporated into the insulator 62 so that the tip protrudes, and the terminal 63 is inserted into the rear end of the center electrode 30 in the insulator 62. These are incorporated into the metal shell 60.
[0036]
Similarly, as shown in FIG. 7, the ground electrode 40 previously welded to the metal shell 60 is produced. The ground electrode 40 has a width of 2.5 (mm) using a Ni alloy of Inconel (registered trademark) 600 as an electrode base material, like the center electrode 30. And as shown in FIG. 4, the 2nd surface 12a of the intermediate member 10 of the intermediate member 20 with a tip is resistance-welded to the ground electrode 40. In that case, first, the second surface 12a of the intermediate member 10 of the intermediate member 20 with the tip is disposed on the joint surface 42 of the ground electrode 40 on the discharge gap side, and resistance welding is similarly performed. At this time, since the intermediate member with tip 20 may be resistance-welded to the electrode base material of the ground electrode 40, the tip 16 can be provided on the side of the ground electrode 40 without being limited by the incident angle of the laser.
[0037]
Then, as shown in FIG. 6, one end of the electrode base material of the ground electrode 40 welded to the tip-attached intermediate member 20 is bent toward the center electrode 30 side. In this way, the spark plug shown in FIG. 7 is obtained.
[0038]
In these cases, the intermediate member 10 has an intermediate melting point or linear expansion coefficient between the electrode base material of the center electrode 30 and the ground electrode 40 and the chip 20. For this reason, in this spark plug, the difference between the thermal stress generated in the electrode base material of the center electrode 30 and the ground electrode 40 due to the thermal stress generated in the intermediate member 10 and the thermal stress generated in the chip 16 is reduced. For this reason, the intermediate member 10 itself is hardly distorted, and peeling between the electrode base material of the center electrode 30 or the ground electrode 40 and the intermediate member 10 or between the intermediate member 10 and the chip 16 is difficult to occur. Further, in the intermediate member 10 having an intermediate melting point or linear expansion coefficient between the electrode base material and the tip 16, a general-purpose resistance can be obtained without performing laser welding, which is a large facility, in the third step S30. Sufficient weld strength can be secured by welding.
[0039]
Further, in the intermediate member with tip 20 obtained in the second step S20, the tip 16 is welded to the first surface 14a of the intermediate member 10 by laser. For this reason, the joining force between the tip 16 and the intermediate member 10 in the tip-attached intermediate member 20 is high. In the third step S30, the tip-attached intermediate member 20 is directly welded to the electrode base material of the center electrode 30 and the ground electrode 40, and the tip-attached intermediate member obtained by cutting the tip-attached intermediate member is welded as in the prior art. Not to do. For this reason, in the spark plug obtained in this way, a crack is not generated in the welded portion between the tip 16 and the intermediate member 10, and the joining force between the tip 16 and the intermediate member 10 is maintained.
[0040]
Furthermore, in order to produce the intermediate member 10 having the first surface 14a and the second surface 12a parallel to the first surface 14a in the first step S10, the intermediate member 20 with a chip obtained in the second step S20 is the chip 16 It is easy to maintain the front end surface of the chip and the second surface 12a of the intermediate member 20 with the tip in parallel with each other. For this reason, even when this tip-attached intermediate member 20 is used as the center electrode 30 of the spark plug, it is difficult to form a discharge gap at the edge of the tip 16, and it is easy to maintain the spark wear resistance of the tip 16 itself.
[0041]
In particular, in this manufacturing method, the relationship between the diameter d1 of the first surface 14a and the diameter d2 of the second surface 12a of the intermediate member 10 and the diameter of the electrode base material at the center electrode 30 or the width D2 of the electrode base material at the ground electrode 40. Since d1 + 0.3 <d2 ≦ D2 (mm), the second surface 12a of the intermediate member 10 at the time of resistance welding can be utilized to the maximum, and the intermediate member 20 with the tip, the electrode base material, Can be firmly joined. Further, since the intermediate member 10 contains Ni which is a component of the electrode base material of the ground electrode 40, the intermediate member 20 with the tip is obtained by mixing and firmly joining the intermediate member and the electrode base material of the ground electrode 40. It becomes.
[0042]
Further, as shown in FIG. 2, the intermediate member 10 has the first surface 14a and the second surface 12a orthogonal to the axis of the intermediate member 10, and the maximum diameter of the first surface 14a is that of the second surface 12a. The base is smaller than the maximum diameter. And as shown in FIG. 3, the intermediate member 20 with a chip | tip has the discharge gap of the electrode base material of the center electrode 30 and the ground electrode 40 rather than the 1st surface 14a of the intermediate member 10 with which the cylindrical chip | tip 16 was welded. The second surface 12a of the intermediate member 10 welded to the side has a large diameter. For this reason, since the second surface 12a of the intermediate member 10 is resistance-welded in a large area with the joint surfaces 32 and 42 on the discharge gap side of the electrode base material of the center electrode 30 and the ground electrode 40, the intermediate member 10 and The joining force with the electrode base material is reliably improved.
[0043]
Furthermore, in this manufacturing method, the intermediate member 10 has a flange portion 12 that forms the second surface 12a on the bottom surface, and a cylindrical portion 14 that rises from the flange portion 12 with a smaller diameter than the flange portion 12 and forms the first surface 14a on the top surface. Therefore, the weldability between the intermediate member 10 and the tip 16 can be improved by the cylindrical portion 14 while the area of the second surface 12 a is increased by the flange portion 12. In particular, since the flange portion 12 has a tapered surface 12b that protrudes toward the first surface 14a, the strength of the intermediate member 10 is ensured.
[0044]
Therefore, in this spark plug manufacturing method, it is possible to realize stronger bonding between the electrode base material and the chip 16 in the center electrode 30 and the ground electrode 40 and maintenance of the spark wear resistance of the chip 16 itself.
[0045]
As shown in FIG. 7, the spark plug thus obtained includes a cylindrical metal shell 60. The metal shell 60 extends in the axial direction of the metal shell 60, and both ends are connected to the metal shell 60. A cylindrical insulator 62 protruding from both ends is fixed. Further, the center electrode 30 extends in the axial direction of the metal shell 60, the tip of the center electrode 30 protrudes from the tip of the insulator 62, and the rear end of the center electrode 30 is fixed in the insulator 62. On the other hand, one end of the ground electrode 40 is fixed to the metal shell 60, and a discharge gap is formed between the other end of the ground electrode 40 and the center electrode 30. The center electrode 30 and the ground electrode 40 are provided with the chip-attached intermediate member 20 facing each other while forming a discharge gap.
[0046]
In this spark plug, since the intermediate member 10 has a pedestal shape, the second surface 12a of the intermediate member 10 is welded in a large area to the joint surface on the discharge gap side of the electrode base material, and the intermediate member 10, the central electrode 30, and the ground The bonding force between the electrode 40 and the electrode base material is reliably improved. Further, in this spark plug, since the first surface 14a and the second surface 12a of the intermediate member 10 are parallel to each other, the tip surface of the chip 16 and the second surface 12a of the intermediate member 10 can be easily maintained parallel to each other. As a result, the tip surface of the chip 16 and the bonding surface of the electrode base material can be easily maintained in parallel with each other. For this reason, it is difficult to form a discharge gap at the edge of the chip 16, and it is easy to maintain the spark wear resistance of the chip 16 itself.
[0047]
Therefore, this spark plug can maintain the durability exhibited by the chip 16 over a long period of time.
[0048]
In the manufacturing method of the embodiment, for example, as shown in FIGS. 8A to 8F, various shapes of the intermediate member 10 can be employed. The intermediate member 71 shown in FIG. 8A has a tapered surface 12b having a larger inclination than that of the above embodiment. The intermediate member 72 shown in FIG. 8B is one in which the flange portion 12 does not have a surrounding thickness. The intermediate member 73 shown in FIG. 8C does not have the cylindrical portion 14. In the intermediate member 74 shown in FIG. 8D, the flange portion 12 does not have a surrounding thickness and does not have the cylindrical portion 14. The intermediate member 75 shown in FIG. 8 (e) is composed of a flange portion 12 having a flat upper surface and a cylindrical portion 14 rising from the upper surface of the flange portion 12. The intermediate member 76 shown in FIG. 8 (f) has a thickness of the cylindrical portion 14 smaller than that of FIG. 8 (e). Even if it is such an intermediate member 71-76, there can exist the effect of this invention.
[Brief description of the drawings]
FIG. 1 is a process diagram of a method for manufacturing a spark plug according to an embodiment.
FIG. 2 is a side view of the intermediate member according to the embodiment.
FIG. 3 is a side view of the intermediate member with tip according to the embodiment.
FIG. 4 is a side view of the intermediate member with a tip during resistance welding according to the embodiment.
FIG. 5 is a partial enlarged cross-sectional view of a center electrode or a ground electrode according to the embodiment.
FIG. 6 is a partially enlarged side view of the spark plug according to the embodiment.
FIG. 7 is a partial cross-sectional side view of the spark plug according to the embodiment.
FIG. 8 is a side view of another intermediate member according to the embodiment.
[Explanation of symbols]
60 ... metal shell 62 ... insulator 30 ... center electrode 40 ... ground electrode 16 ... tip 10, 71-76 ... intermediate member S10 ... first step 14a ... first surface 20 ... intermediate member with tip S20 ... second step 32, 34 ... Joining surface 12a ... 2nd surface S30 ... 3rd process 12 ... Flange part 14 ... Cylindrical part 12b ... Tapered surface

Claims (9)

筒状の主体金具と、該主体金具の軸方向に延在し、両端を該主体金具の両端から突出させて該主体金具内に固定された筒状の絶縁体と、該主体金具の軸方向に延在し、先端を該絶縁体の先端から突出させて後端が該絶縁体内に固定された中心電極と、該主体金具に一端が固定され、他端部と該中心電極との間に放電ギャップを形成する接地電極とからなり、該中心電極及び該接地電極は各々電極母材と該電極母材の該放電ギャップを形成する位置に耐火花消耗材からなるチップとを有し、該中心電極及び該接地電極の少なくとも一方の該電極母材と該チップとの間に該電極母材及び該チップの中間的な融点又は線膨張係数をもつ中間部材が設けられたスパークプラグの製造方法において、
第1面と該第1面に平行な第2面とをもつ前記中間部材を作製する第1工程と、
該中間部材の該第1面に該チップをレーザにより溶接し、チップ付き中間部材とする第2工程と、
前記中心電極及び前記接地電極の少なくとも一方における該電極母材の前記放電ギャップを形成する位置の接合面に該チップ付き中間部材の該第2面を抵抗溶接する第3工程とを備え
前記中間部材は、底面で前記第2面を形成するフランジ部と、該フランジ部から該フランジ部より小径で立ち上がり、上面で前記第1面を形成する柱部とからなり、
前記第3工程では、前記フランジ部に所定の加圧力を加えるとともに、前記チップ付き中間部材における前記チップと前記中間部材との間の溶接部に加圧力が加わらないように抵抗溶接を行うことを特徴とするスパークプラグの製造方法。
A cylindrical metal shell, a cylindrical insulator that extends in the axial direction of the metal shell, protrudes from both ends of the metal shell, and is fixed in the metal shell, and an axial direction of the metal shell A center electrode with a tip projecting from the tip of the insulator and a rear end fixed in the insulator, and one end fixed to the metal shell, between the other end and the center electrode. A ground electrode that forms a discharge gap, the center electrode and the ground electrode each having an electrode base material and a tip made of a spark-resistant consumable material at a position where the discharge gap of the electrode base material is formed, A spark plug manufacturing method in which an intermediate member having an intermediate melting point or a linear expansion coefficient of the electrode base material and the tip is provided between the tip and at least one of the center electrode and the ground electrode. In
A first step of producing the intermediate member having a first surface and a second surface parallel to the first surface;
A second step of welding the tip to the first surface of the intermediate member with a laser to form an intermediate member with a tip;
A third step of resistance welding the second surface of the intermediate member with the tip to a joint surface at a position where the discharge gap of the electrode base material is formed in at least one of the center electrode and the ground electrode ;
The intermediate member includes a flange portion that forms the second surface on the bottom surface, and a column portion that rises from the flange portion with a smaller diameter than the flange portion and forms the first surface on the top surface,
In the third step, a predetermined pressure is applied to the flange portion, and resistance welding is performed so that no pressure is applied to a weld portion between the tip and the intermediate member in the intermediate member with the tip. A method of manufacturing a spark plug characterized by the above.
上記フランジ部は上記第1面側に突出するテーパ面をもつことを特徴とする請求項記載のスパークプラグの製造方法。The flange the method of manufacturing a spark plug according to claim 1, characterized by having a tapered surface which projects to the first surface side. 上記チップは円柱状をなし、上記第1面は該チップの底面を含む円形であり、該第1面の直径は該チップの直径よりも大きいことを特徴とする請求項1又は2記載のスパークプラグの製造方法。 3. The spark according to claim 1, wherein the tip has a cylindrical shape, the first surface is a circle including a bottom surface of the tip, and the diameter of the first surface is larger than the diameter of the tip. Plug manufacturing method. 上記第1面の直径をd1、上記チップの直径をD1としたとき、D1<d1≦D1+0.6(mm)であることを特徴とする請求項記載のスパークプラグの製造方法。4. The spark plug manufacturing method according to claim 3 , wherein D1 <d1 ≦ D1 + 0.6 (mm), where d1 is a diameter of the first surface and D1 is a diameter of the tip. 上記第2面は上記中心電極における上記電極母材の直径又は上記接地電極における上記電極母材の幅内にある円形であり、該第2面の直径は該中心電極における該電極母材の直径又は該接地電極における該電極母材の幅よりも小さいことを特徴とする請求項乃至のいずれか1項記載のスパークプラグの製造方法。The second surface is a circle within the width of the electrode base material in the center electrode or the width of the electrode base material in the ground electrode, and the diameter of the second surface is the diameter of the electrode base material in the center electrode. The spark plug manufacturing method according to any one of claims 1 to 4 , wherein the width of the electrode base material in the ground electrode is smaller. 上記第1面の直径をd1、上記第2面の直径をd2、上記中心電極における上記電極母材の直径又は上記接地電極における上記電極母材の幅をD2としたとき、d1+0.3<d2≦D2(mm)であることを特徴とする請求項記載のスパークプラグの製造方法。When the diameter of the first surface is d1, the diameter of the second surface is d2, and the diameter of the electrode base material at the center electrode or the width of the electrode base material at the ground electrode is D2, d1 + 0.3 <d2 <= D2 (mm), The manufacturing method of the spark plug of Claim 5 characterized by the above-mentioned. 上記第1工程における上記中間部材は上記電極母材の成分を含むことを特徴とする請求項1乃至のいずれか1項記載のスパークプラグの製造方法。The spark plug manufacturing method according to any one of claims 1 to 6 , wherein the intermediate member in the first step includes a component of the electrode base material. 上記第1工程における上記中間部材は上記チップの成分を含むことを特徴とする請求項1乃至のいずれか1項記載のスパークプラグの製造方法。The spark plug manufacturing method according to any one of claims 1 to 7 , wherein the intermediate member in the first step includes a component of the tip. 上記第3工程を上記接地電極について行なうことを特徴とする請求項1乃至のいずれか1項記載のスパークプラグの製造方法。A spark plug manufacturing method according to any one of claims 1 to 8, characterized by performing the third step for the ground electrode.
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BRPI0713681A2 (en) * 2006-06-19 2012-10-23 Federal Mogul Corp spark plug for a spark ignition combustion event
JP4603005B2 (en) 2007-03-28 2010-12-22 日本特殊陶業株式会社 Manufacturing method of spark plug
EP2221931B1 (en) 2007-11-15 2017-01-11 NGK Spark Plug Co., Ltd. Spark plug
KR101513325B1 (en) 2007-11-15 2015-04-17 니혼도꾸슈도교 가부시키가이샤 Spark plug for internal combustion engine
US8378560B2 (en) 2007-11-15 2013-02-19 Ngk Spark Plug Co., Ltd. Spark plug
WO2009066716A1 (en) * 2007-11-20 2009-05-28 Ngk Spark Plug Co., Ltd. Spark plug
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KR101508407B1 (en) * 2007-12-27 2015-04-06 니혼도꾸슈도교 가부시키가이샤 Spark plug
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JP5396535B2 (en) 2010-09-24 2014-01-22 日本特殊陶業株式会社 Method for manufacturing electrode composite for forming electrode for spark plug, and method for manufacturing spark plug
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