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JP2006289527A - Press fit joining method and press fit joining component - Google Patents

Press fit joining method and press fit joining component Download PDF

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Publication number
JP2006289527A
JP2006289527A JP2005110290A JP2005110290A JP2006289527A JP 2006289527 A JP2006289527 A JP 2006289527A JP 2005110290 A JP2005110290 A JP 2005110290A JP 2005110290 A JP2005110290 A JP 2005110290A JP 2006289527 A JP2006289527 A JP 2006289527A
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electrode
press
hole
shaft body
joining
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JP4694873B2 (en
Inventor
Akira Nozue
明 野末
Osamu Kanehara
理 金原
Akira Kanda
亮 神田
Kazuyoshi Harada
和愛 原田
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Ohashi Technica Inc
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Ohashi Technica Inc
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Priority to CNA2006800109154A priority patent/CN101155663A/en
Priority to PCT/JP2006/307232 priority patent/WO2006109650A1/en
Publication of JP2006289527A publication Critical patent/JP2006289527A/en
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  • Pressure Welding/Diffusion-Bonding (AREA)
  • Electroplating Methods And Accessories (AREA)
  • Coating With Molten Metal (AREA)
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  • Resistance Welding (AREA)

Abstract

<P>PROBLEM TO BE SOLVED: To provide a press fit joining method and press fit joining component excellent in mass production property, reliability, and strength wherein the joining is easily performed under the good environment in press fitting of mutual members composing metal element component. <P>SOLUTION: While a first member 2 is disposed on the surface part of a first electrode 6, the side surface part 12 of a second member 4 is mechanically held by a second electrode 8 composed of a plurality of electrode pieces 9 by using the first member 2 having a hole part 3 where the same inner wall surface part is formed for the cross section of the press fit part, and the shaft like second member 4 where a predetermined press fit allowance is provided between the first member 2 and the hole part 3. The second member 4 held toward in the hole part 3 of the first member 2 is pressed by a predetermined pressure and an electric resistance heat is generated at both joining parts by energizing between the two members. The second member 4 is press fitted in the hole part 3 and a joining boundary surface is formed at the joining part between the joining surface part of the second member 4 and the inner wall surface part of the hole part. The joining is made to be the joining in a solid phase state. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

本発明は、金属製要素部品を構成する部材同士の圧入接合方法及び圧入接合部品に関する。   The present invention relates to a press-fit joining method and press-fit joining parts between members constituting a metal element part.

従来、自動車等に使用される金属製要素部品を製造する場合、例えば抵抗溶接法として、スポット溶接法、プロジェクション溶接法により部材同士を接合する方法が行われている。またアイジョイントの製造方法に係り、パイプ接続孔に挿入するパイプ部の挿入側元部にビードを形成し、あるいは上記パイプ接続孔の入口側周縁にリップを形成して、アイ部とパイプ部を抵抗溶接する技術も開示されている(例えば、特許文献1)。   2. Description of the Related Art Conventionally, when manufacturing metal element parts used for automobiles and the like, for example, as a resistance welding method, a method of joining members by a spot welding method or a projection welding method has been performed. Further, according to the eye joint manufacturing method, a bead is formed on the insertion side base portion of the pipe portion to be inserted into the pipe connection hole, or a lip is formed on the inlet side periphery of the pipe connection hole so that the eye portion and the pipe portion are connected. A technique for resistance welding is also disclosed (for example, Patent Document 1).

上記抵抗溶接法は重ね抵抗溶接法が主力であり、いずれも接合部にナゲットと呼ばれる溶融組織を形成することで接合している。この重ね抵抗溶接では、溶接を強くするためにはナゲットの数を増やす結果、接合母材の熱的劣化や寸法精度への影響が避けられない。また、上記ビード或いはリップの形成には製造工程が複雑化し、また後加工等を行う必要もある。   The main resistance of the resistance welding method is the lap resistance welding method, and all are joined by forming a molten structure called a nugget at the joint. In this lap resistance welding, in order to strengthen the welding, as a result of increasing the number of nuggets, thermal deterioration of the joint base material and influence on dimensional accuracy are inevitable. In addition, the formation of the beads or lips complicates the manufacturing process and requires post-processing.

特開平7−40058号公報Japanese Patent Laid-Open No. 7-40058 特開2001−353628公報JP 2001-353628 A

これに対して、本件出願人は先に圧入接合構造を提案した(特許文献2)。この圧入接合構造は、図13に示すように、治具を用いてプレート90の孔部94に軸体92を圧入接合する。この治具は、電極としてクローム銅製の下型96と、下部に円柱状の穴部97が設けられた上型98とを有し、一方下型96の上部にプレート90を配置し、上型98の穴部97に軸体92の上部を突入保持させて圧入接合を行う。   On the other hand, the present applicant has previously proposed a press-fit joint structure (Patent Document 2). In this press-fit joining structure, as shown in FIG. 13, the shaft body 92 is press-fit and joined to the hole 94 of the plate 90 using a jig. This jig has a lower die 96 made of chrome copper as an electrode and an upper die 98 provided with a cylindrical hole 97 in the lower part, while a plate 90 is disposed on the upper part of the lower die 96, and the upper die The upper portion of the shaft body 92 is plunged and held in the hole portion 97 of 98 to perform press-fit joining.

圧入接合に際しては、上記プレート90の孔部94内に軸体92を所定の圧力で押圧するとともに、これら両部材間に上記電極を介して通電し両者の接合部に電気抵抗熱を発生させ、上記軸体92を上記孔部94に圧入し、軸体92の接合面部と孔部94の内壁面部との接合部に接合界面を形成させ、かつこの接合を固相状態の接合とするものである。   In press-fit joining, the shaft body 92 is pressed into the hole portion 94 of the plate 90 with a predetermined pressure, and the two members are energized through the electrodes to generate electrical resistance heat at the joint portion. The shaft body 92 is press-fitted into the hole portion 94, a bonding interface is formed at the joint portion between the joint surface portion of the shaft body 92 and the inner wall surface portion of the hole portion 94, and this bonding is a solid-phase bonding. is there.

さて、上記圧入接合では、部材同士の間に通電とともに圧入を行うため相当の電流を必要とし、このため部材と電極との接触部における電気抵抗を低減して効率的に電流を接合部に供給する必要がある。この場合、上記軸体92には電極として上型98が被着された形態であるが、軸体92を上型98の穴部97に着脱自在に配置するためには、軸体92の側面部と上型98の穴部97の内壁面との間は若干の隙間を形成する必要がある。   Now, in the above press-fit joining, a considerable current is required to perform press-fitting together with energization between members. For this reason, the electrical resistance at the contact portion between the member and the electrode is reduced, and the current is efficiently supplied to the joined portion. There is a need to. In this case, an upper die 98 is attached to the shaft body 92 as an electrode. However, in order to detachably place the shaft body 92 in the hole 97 of the upper die 98, the side surface of the shaft body 92 is provided. It is necessary to form a slight gap between the portion and the inner wall surface of the hole 97 of the upper mold 98.

このため、上型98から軸体92への通電は、軸体92の上面部及び側面部の一部で行われることになる。このとき、軸体が太身で外径が大きい場合は、軸体の上面部と上型98との接触面積が広いため通電には都合が良いが、軸体が細身で外径が小さい場合には、軸体と上型98との接触面積が狭くなりまた軸体の支持も安定しない。この接触面積が少ないと、両者の接触部の電気抵抗が大きくなって発熱量も多くなり、加えて軸体自体の電気抵抗の影響も無視できなくなり、接合部への電流の供給が妨げられるという問題がある。   For this reason, energization from the upper mold 98 to the shaft body 92 is performed on a part of the upper surface portion and the side surface portion of the shaft body 92. At this time, when the shaft body is thick and the outer diameter is large, the contact area between the upper surface portion of the shaft body and the upper mold 98 is wide, which is convenient for energization, but the shaft body is thin and the outer diameter is small. In this case, the contact area between the shaft body and the upper mold 98 becomes narrow, and the support of the shaft body is not stable. If this contact area is small, the electrical resistance of the contact portion between both increases and the amount of heat generation also increases, and in addition, the influence of the electrical resistance of the shaft body itself cannot be ignored, and the current supply to the joint is hindered. There's a problem.

また従来、亜鉛メッキ鋼板等におけるプロジェクション溶接においては、適正溶接条件の範囲が狭くこれがナゲット生成に影響を及ぼし、また亜鉛メッキにより電極チップの消耗が激しく電極寿命が低下し、さらには裸材に比べて大電流を必要としスパッターが発生し易いなどの問題があった。このため、特にメッキ加工が施された部材の接合においてはプロジェクション溶接法或いはスポット溶接法では多くの課題があった。   Also, conventionally, in projection welding on galvanized steel sheets, etc., the range of proper welding conditions is narrow, which affects nugget formation, and electrode tips are consumed significantly due to galvanization, and the electrode life is reduced. In addition, there is a problem that a large current is required and sputtering is likely to occur. For this reason, there are many problems in the projection welding method or spot welding method, particularly in the joining of members that have been plated.

本発明は、上記問題点に鑑みてなされたものであり、接合が容易にかつ良好な環境で行われるとともに量産性及び信頼性に優れ、かつ強度的にも優れた圧入接合方法及び圧入接合部品を提供することを目的としている。   The present invention has been made in view of the above-mentioned problems, and is a press-fit joining method and a press-fit joined component that are easily and well-bonded, are excellent in mass productivity and reliability, and are excellent in strength. The purpose is to provide.

以上の技術的課題を解決するため、本発明に係る圧入接合方法は、図1に示すように、圧入部分の断面が同一の内壁面部が形成された孔部3を有する第一の部材2と、上記孔部との間に所定の圧入代が設けられ、軸方向に向かう接合面部が形成される軸状の第二の部材4とを用い、上記第一の部材2を第一の電極6の表面部に配置する一方、上記第二の部材4の側面部を複数の電極片9からなる第二の電極8で機械的に挟持し、上記第一の部材2の孔部3内に向けて上記狭持された第二の部材4を所定の圧力で押圧するとともに、これら両部材間に通電して両者の接合部に電気抵抗熱を発生させ、上記第二の部材を上記孔部に圧入し、上記第二の部材の接合面部と上記孔部の内壁面部との接合部に接合界面を形成させ、かつこの接合を固相状態の接合としたことである。   In order to solve the above technical problem, the press-fit joining method according to the present invention includes a first member 2 having a hole 3 in which an inner wall surface portion having the same cross-section of the press-fit portion is formed, as shown in FIG. A predetermined press-fitting allowance is provided between the hole and the shaft-shaped second member 4 in which a joint surface portion extending in the axial direction is formed, and the first member 2 is replaced with the first electrode 6. The side surface of the second member 4 is mechanically sandwiched between the second electrodes 8 made up of a plurality of electrode pieces 9 and directed into the hole 3 of the first member 2. The second member 4 held between the two members is pressed with a predetermined pressure, and an electric current is generated between the two members to generate electric resistance heat at the joint between the two members. Press-fit to form a joint interface at the joint between the joint surface of the second member and the inner wall surface of the hole, and this joint is solid Is that the bonding between the.

本発明に係る圧入接合方法は、図12に示すように、圧入部分の断面が同一の内壁面部が形成された孔部53を有する筒状の第一の部材52と、上記孔部53との間に所定の圧入代が設けられ、軸方向に向かう接合面部が形成される軸状の第二の部材54とを用い、上記第一の部材52の側面部を複数の電極片59からなる第一の電極58で機械的に挟持する一方、上記第二の部材54の側面部を複数の電極片62,63からなる第二の電極64で機械的に挟持し、上記第一の部材52の孔部53内に向けて上記狭持された第二の部材54を所定の圧力で押圧するとともに、これら両部材間に通電して両者の接合部に電気抵抗熱を発生させ、上記第二の部材を上記孔部に圧入し、上記第二の部材の接合面部と上記孔部の内壁面部との接合部に接合界面を形成させ、かつこの接合を固相状態の接合としたことである。   As shown in FIG. 12, the press-fitting method according to the present invention includes a cylindrical first member 52 having a hole 53 in which an inner wall surface having the same cross-section of the press-fitted portion is formed, and the hole 53. A side portion of the first member 52 is formed of a plurality of electrode pieces 59 using a shaft-like second member 54 provided with a predetermined press-fitting allowance therebetween and having a joint surface portion extending in the axial direction. While one electrode 58 is mechanically clamped, the side surface portion of the second member 54 is mechanically clamped by a second electrode 64 including a plurality of electrode pieces 62 and 63, and the first member 52 The second member 54 held in the hole 53 is pressed with a predetermined pressure, and an electric current is generated between the two members to generate electric resistance heat at the two parts. A member is press-fitted into the hole, and a joint between the joint surface of the second member and the inner wall surface of the hole is formed. If the interface to form, and resides in that the bonding of the solid state of this joint.

本発明に係る圧入接合方法は、上記第一の電極の表面部に、上記第一の部材の孔部と連通しこの孔部よりも大きな口径の穴部を設けたことである。   In the press-fitting method according to the present invention, a hole portion having a larger diameter than that of the hole portion is provided in the surface portion of the first electrode so as to communicate with the hole portion of the first member.

本発明に係る圧入接合方法は、上記第一の電極の穴部内に上下移動可能な絶縁性の位置決部材84を配置し、この位置決部材に上記第一の部材の孔部を係合させて位置決めすることである。   In the press-fitting method according to the present invention, an insulating positioning member 84 that can move up and down is disposed in the hole of the first electrode, and the hole of the first member is engaged with the positioning member. Positioning.

本発明に係る圧入接合方法は、上記第二の電極における電極片の狭持部の形状を、上記第二の部材の側面部の形状と同一に形成し、狭持したときにこの第二の部材の側面部に上記電極片の狭持部の全体又は一部が当接するようにしたことである。   In the press-fitting method according to the present invention, the shape of the sandwiching portion of the electrode piece in the second electrode is formed to be the same as the shape of the side surface portion of the second member. That is, the entire or a part of the sandwiching portion of the electrode piece is in contact with the side surface portion of the member.

本発明に係る圧入接合方法は、上記第二の部材を狭持した状態で上記第二の電極を移動可能に、かつこの第二の部材を所定位置に位置決め保持できるように構成したことである。   The press-fit joining method according to the present invention is configured such that the second electrode can be moved while the second member is held and the second member can be positioned and held at a predetermined position. .

本発明に係る圧入接合方法は、上記第二の電極の電極片に、上記第二の部材の端面部を軸方向に押圧可能な押圧部46を設けたことである。   The press-fit joining method according to the present invention is provided with a pressing portion 46 capable of pressing the end surface portion of the second member in the axial direction on the electrode piece of the second electrode.

本発明に係る圧入接合方法は、上記第二の電極の電極片の数を2個又は3個とし、かつ上記第二の部材の軸方向の端面部に上記第二の電極の一部である第三の電極10を設けたことである。   In the press-fitting method according to the present invention, the number of electrode pieces of the second electrode is two or three, and the second electrode is a part of the second electrode on an end surface portion in the axial direction of the second member. The third electrode 10 is provided.

本発明に係る圧入接合方法は、図10に示すように、上記第二の電極の電極片の上方に押圧電極部71を設け、この押圧電極部71と上記各電極片との間に所定の間隔を維持しかつ上記電極片に電流を供給するための支持電極部72,73を設け、上記第二の部材4の上部を上記押圧電極部71で押圧可能に保持する一方、上記電極片によりこの第二の部材4の下部近傍を狭持することである。   As shown in FIG. 10, the press-fitting method according to the present invention is provided with a pressing electrode portion 71 above the electrode piece of the second electrode, and a predetermined electrode is provided between the pressing electrode portion 71 and each of the electrode pieces. Support electrode portions 72 and 73 for maintaining a distance and supplying current to the electrode pieces are provided, and the upper portion of the second member 4 is held by the pressing electrode portion 71 so that it can be pressed. This is to pinch the vicinity of the lower part of the second member 4.

本発明に係る圧入接合方法は、上記押圧電極部と上記第二の部材の上部との間を電気的に遮断したことである。   The press-fit joining method according to the present invention is to electrically cut off between the pressing electrode portion and the upper part of the second member.

本発明に係る圧入接合方法は、上記第一の部材又は上記第二の部材の表面にメッキが施されていることである。   The press-fit joining method according to the present invention is that the surface of the first member or the second member is plated.

本発明に係る圧入接合方法は、上記メッキとして、溶融亜鉛メッキ、合金化溶融亜鉛メッキ、電気亜鉛メッキ又は合金亜鉛メッキを施したことである。   The press-fit joining method according to the present invention is that the galvanizing, alloying galvanizing, electrogalvanizing or alloy galvanizing is performed as the plating.

また、本発明に係る圧入接合部品は、上記何れかに記載の圧入接合方法により製造され、上記第一の部材の孔部に上記第二の部材が接合されたものである。   Moreover, the press-fitting component according to the present invention is manufactured by any of the press-fitting methods described above, and the second member is joined to the hole of the first member.

本発明に係る圧入接合方法によれば、第一の部材を第一の電極の表面部に配置する一方、第二の部材の側面部を複数の電極片からなる第二の電極で機械的に挟持し、第一の部材の孔部内に向けて狭持された第二の部材を所定の圧力で押圧するとともに、これら両部材間に通電して両者の接合部に電気抵抗熱を発生させ、第二の部材を孔部に圧入して得られる固相状態の接合であるから、通電の際には電極と部材との間の電気抵抗を低減して、良好に第二の電極から第二の部材に電流が供給され、また第二の部材が安定して保持されて精度良く孔部に圧入が行えるとともに、簡単な工程で迅速に接合が行えて量産性、経済性に優れ、また接合界面が清浄化されて接合が良好に行われて強度的にも優れている。加えてこの接合方法は固相状態の接合であるから、スパッターの発生がなく良好な作業環境が得られるとともに、電極及び接合部の熱的劣化がなく電極の耐久性、部材の仕上り精度が良いという効果がある。   According to the press-fitting method according to the present invention, the first member is disposed on the surface portion of the first electrode, while the side surface portion of the second member is mechanically formed by the second electrode including a plurality of electrode pieces. While sandwiching and pressing the second member sandwiched in the hole of the first member at a predetermined pressure, energizing between both of these members to generate electrical resistance heat at the joint of both, Since this is a solid-phase joining obtained by press-fitting the second member into the hole, the electrical resistance between the electrode and the member is reduced during energization, and the second electrode is successfully removed from the second electrode. A current is supplied to the member, and the second member is stably held so that it can be press-fitted into the hole with high accuracy, and can be quickly joined in a simple process, resulting in excellent mass productivity and economy. The interface is cleaned, bonding is performed well, and the strength is excellent. In addition, since this joining method is a solid state joining, there is no occurrence of spatter and a good working environment is obtained, and there is no thermal deterioration of the electrodes and joints, and the durability of the electrodes and the finishing accuracy of the members are good. There is an effect.

また、本発明に係る圧入接合方法によれば、第一の電極の表面部に、第一の部材の孔部と連通しこの孔部よりも大きな口径の穴部を設けたから、圧入接合したときに第一の部材の孔部の周辺が圧入方向に変形するための逃げとなり、また第一の部材と第一の電極との接触が不安定になった場合に、この接触部で発生するスパーク、爆飛などを防止するという効果がある。   In addition, according to the press-fitting method according to the present invention, since the surface portion of the first electrode is provided with a hole portion having a larger diameter than the hole portion in communication with the hole portion of the first member, In addition, when the contact between the first member and the first electrode becomes unstable when the periphery of the hole of the first member is deformed in the press-fitting direction, the spark generated at this contact portion This has the effect of preventing explosions.

また、本発明に係る圧入接合方法によれば、第一の電極の穴部内に位置決部材を配置し、この位置決部材に第一の部材の孔部を係合させて位置決めすることとしたから、第一の部材の位置決めが正確かつ簡単に行えるという効果がある。   Further, according to the press-fitting method according to the present invention, the positioning member is disposed in the hole portion of the first electrode, and the positioning member is positioned by engaging the hole portion of the first member. Therefore, there is an effect that the positioning of the first member can be performed accurately and easily.

また、本発明に係る圧入接合方法によれば、第一の部材の側面部を複数の電極片からなる第一の電極で機械的に挟持する一方、第二の部材の側面部を複数の電極片からなる第二の電極で機械的に挟持し、第一の部材の孔部内に向けて狭持された第二の部材を所定の圧力で押圧するとともに、これら両部材間に通電して両者の接合部に電気抵抗熱を発生させ、第二の部材を孔部に圧入して固相状態の接合であるから、上記と同様の効果が得られるとともに、第一の部材が筒状の場合についても複数の電極片で狭持する構成としたから、上記と同様、量産性、経済性に優れまた簡単な工程で製造が容易に行えかつ強度的にも優れ、仕上り精度が良いという効果がある。   Further, according to the press-fitting method according to the present invention, the side surface portion of the first member is mechanically sandwiched by the first electrode composed of a plurality of electrode pieces, while the side surface portion of the second member is the plurality of electrodes. A second electrode made of a piece is mechanically sandwiched, and the second member sandwiched in the hole of the first member is pressed with a predetermined pressure, and both members are energized by energizing them. In the case where the electrical resistance heat is generated at the joint portion and the second member is press-fitted into the hole portion to effect solid-phase joining, the same effect as described above can be obtained, and the first member is cylindrical As described above, since it is configured to be sandwiched by a plurality of electrode pieces, as described above, it is excellent in mass productivity, economical efficiency, easy manufacturing in a simple process, excellent in strength, and good finishing accuracy. is there.

本発明に係る圧入接合方法によれば、第二の部材の側面部に電極片の狭持部の全体又は一部が当接するようにしたから、電極と部材の接触部の電気抵抗及び発熱量が低減され、このため通電が良好に行えて高精度の接合が行え、また電極及び部材表面への熱影響もなく電極の耐久性及び部材の品質にも優れるという効果がある。   According to the press-fitting method according to the present invention, since the whole or a part of the sandwiching portion of the electrode piece comes into contact with the side surface portion of the second member, the electrical resistance and the heat generation amount of the contact portion between the electrode and the member Therefore, there is an effect that energization can be satisfactorily performed, high-precision joining can be performed, and the durability of the electrode and the quality of the member are excellent without being affected by heat on the surface of the electrode and the member.

また、本発明に係る圧入接合方法によれば、第二の部材を狭持した状態で、第二の電極を移動可能かつ所定位置に位置決め保持できるように構成したから、電極が多機能に活用できて効率的であり、また圧入位置の精度が高められるという効果がある。   In addition, according to the press-fitting method according to the present invention, the second electrode can be moved and positioned and held at a predetermined position while the second member is held, so that the electrode can be used for multiple functions. This is effective because it is efficient and the accuracy of the press-fitting position is improved.

また、本発明に係る圧入接合方法によれば、第二の電極の電極片に第二の部材の端面部を軸方向に押圧可能な押圧部を設けたから、第二の部材の側面部に加えて上面部が接触してさらに電気抵抗が低減され、また第二の部材の押圧も行えて部品点数の削減にも寄与するという効果がある。   Further, according to the press-fitting method according to the present invention, since the pressing portion capable of pressing the end surface portion of the second member in the axial direction is provided on the electrode piece of the second electrode, in addition to the side surface portion of the second member. As a result, the electrical resistance is further reduced due to the contact of the upper surface portion, and the second member can be pressed to contribute to the reduction of the number of parts.

本発明に係る圧入接合方法によれば、第二の電極の電極片の数を2個又は3個とし、かつ第二の部材の端面部に第三の電極を設けたから、実用的かつ接触部の電気抵抗が低減され電気損失が少なくて効率的な接合が行えるという効果がある。   According to the press-fitting method according to the present invention, the number of electrode pieces of the second electrode is two or three, and the third electrode is provided on the end surface portion of the second member. The electrical resistance is reduced, and there is an effect that an efficient joining can be performed with less electrical loss.

また、本発明に係る圧入接合方法によれば、押圧電極部と各電極片との間に支持電極部を設け、第二の部材の上部を押圧電極部で押圧可能に保持する一方、電極片によりこの第二の部材の下部近傍を狭持することとしたから、第二の部材が長尺状であっても安定して支持することができ、かつ良好に圧入接合が行えるという効果がある。   Further, according to the press-fitting method according to the present invention, the supporting electrode portion is provided between the pressing electrode portion and each electrode piece, and the upper portion of the second member is held by the pressing electrode portion so as to be pressed. Therefore, the vicinity of the lower part of the second member is sandwiched, so that the second member can be stably supported even when the second member is long, and the press-fitting can be performed satisfactorily. .

また、本発明に係る圧入接合方法によれば、押圧電極部と第二の部材の上部との間を電気的に遮断したから、第二の部材が長尺でステンレス鋼など電気抵抗が高く、或いは細身の形状の場合であっても良好に圧入接合が行えるという効果がある。   In addition, according to the press-fitting method according to the present invention, since the electrical connection between the pressing electrode part and the upper part of the second member is electrically interrupted, the second member is long and has high electrical resistance such as stainless steel, Or even if it is a case of a slim shape, there exists an effect that press-fit joining can be performed favorably.

本発明に係る圧入接合方法によれば、第一の部材又は第二の部材の表面にメッキが施されているものであっても、熱影響が少ないため電極とメッキとの合金化学反応を起こすこともないことから電極の耐久性が高められ、また部材の表面が良好に維持されてメッキに悪影響を及ぼすこともなく良質の接合部品が得られるという効果がある。   According to the press-fitting method according to the present invention, even if the surface of the first member or the second member is plated, an alloy chemical reaction between the electrode and the plating occurs due to less thermal influence. Therefore, the durability of the electrode is enhanced, and the surface of the member is well maintained, and there is an effect that a high-quality bonded part can be obtained without adversely affecting the plating.

本発明に係る圧入接合方法によれば、メッキとして、溶融亜鉛メッキ、合金化溶融亜鉛メッキ、電気亜鉛メッキ又は合金亜鉛メッキを施したことから、実用的なメッキ処理部材においても上記メッキを施した場合と同様の効果が得られる。   According to the press-fit joining method according to the present invention, since the hot dip galvanizing, the alloyed hot dip galvanizing, the electrogalvanizing or the galvanizing alloy is performed as the plating, the above-mentioned plating is also applied to the practical plating member. The same effect as the case can be obtained.

また本発明に係る圧入接合部品によれば、上記何れかに記載の圧入接合方法により製造され、第一の部材の孔部に第二の部材が接合されたものであるから、精度良く孔部に圧入が行えるとともに、簡単な工程で迅速に接合が行えて量産性、経済性に優れ、また接合界面が清浄化されて接合が良好に行われて強度的にも優れ、加えて固相状態での接合としたことから電極への影響もなくまた接合部の熱的劣化がなく仕上り精度が良いという効果がある。   Further, according to the press-fitting joint component according to the present invention, since the second member is manufactured by the press-fitting method according to any one of the above and the second member is joined to the hole of the first member, the hole is accurately obtained. In addition, it can be press-fitted into a joint, and can be joined quickly in a simple process, providing excellent mass productivity and economy. Also, the joining interface is cleaned and the joining is performed well and the strength is excellent. Since the joining is performed at this point, there is no effect on the electrodes, and there is no effect of thermal deterioration of the joining portion, and the finishing accuracy is good.

以下、本発明に係る圧入接合の実施の形態を図面に基づいて説明する。上記実施の形態に係り、図1及び図2は、圧入接合装置を用いワークとして孔部3が設けられたプレート2と軸体4とを用い、これらを圧入接合する機構を示している。この軸体4としては、棒状(中実)又は筒状(中空)のものがある。なお、以下の各形態に係る説明において、同一の符号を付した構成要素については同一の内容のものであるものとし、繰り返しての説明は省略する。   Embodiments of press-fitting according to the present invention will be described below with reference to the drawings. 1 and 2 show a mechanism for press-fitting and joining a plate 2 and a shaft body 4 provided with a hole 3 as a workpiece using a press-fitting device. The shaft body 4 may be rod-shaped (solid) or cylindrical (hollow). In the description relating to each of the embodiments below, the components having the same reference numerals are assumed to have the same contents, and repeated description will be omitted.

上記圧入接合装置は、上記プレート2と上記軸体4間に通電する電極を有する圧入機構、この軸体を電極によって挟み、所定位置に位置決め移動させる移動機構、及び上記軸体4を押圧可能なプレス機構を有する。なお、このプレス機構は通常の抵抗溶接機に具備されているものである。また上記電極は、上記プレート2を載置可能な肉厚板状の下部電極6、上記軸体4を狭持する2個の電極片9,9に分割された上部電極8、及び軸体4を押圧する押圧電極10からなり、何れも材質はクローム銅製である。この押圧電極10は上部電極8と電気的に導通しており、その一部として機能する。   The press-fitting device includes a press-fitting mechanism having an electrode for energizing between the plate 2 and the shaft body 4, a moving mechanism for sandwiching the shaft body between the electrodes and moving it to a predetermined position, and the shaft body 4 can be pressed. It has a press mechanism. This press mechanism is provided in a normal resistance welding machine. Further, the electrode includes a thick plate-like lower electrode 6 on which the plate 2 can be placed, an upper electrode 8 divided into two electrode pieces 9, 9 holding the shaft body 4, and the shaft body 4. The material is made of chrome copper. The pressing electrode 10 is electrically connected to the upper electrode 8 and functions as a part thereof.

上記上部電極8は移動機構に装備されており、軸体4は上部電極8に狭持された状態でこの移動機構により所定の位置に搬送して位置決めされ保持固定される。また、軸体4の圧入の際には、移動機構の上下移動機能により上部電極8は降下可能である。上記プレス機構は押圧電極10を押圧し、軸体4を加圧力とともに降下させる。   The upper electrode 8 is mounted on a moving mechanism, and the shaft body 4 is transported to a predetermined position by the moving mechanism while being held by the upper electrode 8 and is positioned, held and fixed. When the shaft body 4 is press-fitted, the upper electrode 8 can be lowered by the up-and-down movement function of the moving mechanism. The press mechanism presses the pressing electrode 10 and lowers the shaft body 4 together with the applied pressure.

上記プレート2は所定の厚さを有し、このプレート2に設けられた孔部3は断面の直径が一定の円形であり、プレート2の板面から垂直方向にこの孔部3の内壁面部が形成されている。上記軸体4は円柱状であり、円筒状の側面部12、平坦な上面部14及び下面部13を有している。上記軸体4の接合面部5の外径(直径)は、プレート2の孔部3の直径より僅かに大きく、圧入代はこれらの差となる。この圧入代により、軸体4の接合面部5の外周部位が、プレート2の孔部3の内壁面部と接して擦られて接合界面を形成し、全周に及ぶ圧入接合が行われる。   The plate 2 has a predetermined thickness, the hole 3 provided in the plate 2 has a circular shape with a constant cross-sectional diameter, and the inner wall surface of the hole 3 is perpendicular to the plate surface of the plate 2. Is formed. The shaft body 4 is columnar and has a cylindrical side surface portion 12, a flat upper surface portion 14, and a lower surface portion 13. The outer diameter (diameter) of the joint surface portion 5 of the shaft body 4 is slightly larger than the diameter of the hole portion 3 of the plate 2, and the press-fitting allowance is the difference between them. By this press-fitting allowance, the outer peripheral portion of the joint surface portion 5 of the shaft body 4 is rubbed in contact with the inner wall surface portion of the hole portion 3 of the plate 2 to form a joint interface, and press-fit joining over the entire circumference is performed.

また、上記下部電極6には、プレート2を載置支持する平坦な表面部7が形成されており、この表面部7の中央部付近には円柱状の穴部15が設けられている。上記プレート2は、その孔部3を上記穴部15の上部に中心を略一致させて配置する。この穴部15の穴の大きさ(直径)は、軸体4よりも少し大きく形成する。この穴部15は、軸体をプレート2に圧入接合したときに、プレート2の孔部3の周辺が圧入方向に変形するのでこの逃げを形成するためであり、またこの圧入接合で、軸体4が孔部3を通過して突き抜けた場合には、軸体4が下部電極6と直接接触して爆飛などを起こして不都合をきたすことがあるのでこれを防止するためである。   The lower electrode 6 has a flat surface portion 7 on which the plate 2 is placed and supported, and a cylindrical hole portion 15 is provided near the center of the surface portion 7. The plate 2 is arranged such that the hole 3 is substantially aligned with the center of the hole 3 above the hole 15. The size (diameter) of the hole 15 is slightly larger than that of the shaft body 4. This hole portion 15 is for forming the clearance because the periphery of the hole 3 of the plate 2 is deformed in the press-fitting direction when the shaft member is press-fitted and joined to the plate 2. This is to prevent the shaft 4 from passing through the hole 3 and coming into direct contact with the lower electrode 6 to cause explosions and the like.

上記穴部15は、プレート2に加わる荷重の加減で、プレート2と下部電極6との接触が不安定になった場合に、この接触部で発生するスパーク、爆飛などを防止する。特に、上記孔部3の下部周辺ではスパーク等が発生し易いためこれを防止する。通常上記プレート2は下部電極6とは必ずしも理想的な形で密着しない場合があり、このとき上記穴部15があると上記逃げの効果も相まって、この穴部15の周辺とプレート2とが比較的良好に密着して電流の流れが良くなり、このためスパーク等が低減され併せて下部電極6の消耗も少なくなり良好である。さらに、この穴部15は下記位置決部材84を配置することで、プレート2の位置決めにも利用可能である。以下の実施の形態に係る各下部電極6の穴部15についても、全て同様の効果が得られる。   The hole 15 prevents sparks, explosions, and the like generated at the contact portion when the contact between the plate 2 and the lower electrode 6 becomes unstable due to the load applied to the plate 2. In particular, since a spark or the like is likely to be generated around the lower portion of the hole 3, this is prevented. In general, the plate 2 may not be in close contact with the lower electrode 6 in an ideal shape. If the hole 15 is present, the effect of the escape is combined and the periphery of the hole 15 is compared with the plate 2. Good contact and good current flow can be achieved, and therefore, sparks and the like are reduced, and consumption of the lower electrode 6 is reduced. Further, the hole 15 can be used for positioning the plate 2 by arranging the following positioning member 84. The same effect can be obtained for all the holes 15 of the lower electrodes 6 according to the following embodiments.

上記上部電極8は移動機構により保持され、この移動機構は上記軸体4の側面部12を2個の電極片9,9により所定の押圧力とともに機械的に狭持し、かつ狭持した状態で軸体4を水平垂直移動可能に構成されている。電極片の押圧力は、エアーシリンダ機構、バネ機構などにより得る。これら電極片9,9は、所定の肉厚の板片であり、軸体4を狭持する部位には軸体4の側面部12の断面形状(片半部分)と同一形状の狭持部16が形成されている。ここでは図2に示すように、軸体4の断面形状が円形であり、電極片9,9の各狭持部16の形状は、軸体4と同様な半径の半円状である。   The upper electrode 8 is held by a moving mechanism, and the moving mechanism mechanically holds the side surface portion 12 of the shaft body 4 with two electrode pieces 9 and 9 together with a predetermined pressing force, and is in a state of holding it Thus, the shaft body 4 can be moved horizontally and vertically. The pressing force of the electrode piece is obtained by an air cylinder mechanism, a spring mechanism, or the like. These electrode pieces 9 and 9 are plate pieces having a predetermined thickness, and a pinching portion having the same shape as the cross-sectional shape (half half portion) of the side surface portion 12 of the shaft body 4 is provided at a portion where the shaft body 4 is pinched. 16 is formed. Here, as shown in FIG. 2, the cross-sectional shape of the shaft body 4 is circular, and the shape of each holding portion 16 of the electrode pieces 9, 9 is a semicircular shape having the same radius as that of the shaft body 4.

このように、電極片9,9で軸体4を狭持することで、接合部と電極との距離を小さくすることができ軸体自体の電気抵抗の影響を軽減できる。さらに各電極片9,9の狭持部16の形状を軸体4の側面部12(片半部分)の形状と同一にすることで、軸体4を狭持したときに狭持部16の全体を軸体4の側面部に当接させることができ、これにより両者の接触面積が広く確保できて電気抵抗の低減が図れる。また、所定の押圧力を伴って電極片9,9で軸体4を狭持することから、両者が密着して接触抵抗が低減でき両者間の通電が良好に行える。   Thus, by holding the shaft body 4 between the electrode pieces 9, 9, the distance between the joint and the electrode can be reduced, and the influence of the electrical resistance of the shaft body itself can be reduced. Further, by making the shape of the clamping portion 16 of each electrode piece 9, 9 the same as the shape of the side surface portion 12 (one half portion) of the shaft body 4, when the shaft body 4 is clamped, The entirety can be brought into contact with the side surface portion of the shaft body 4, whereby a large contact area between the two can be ensured and electric resistance can be reduced. In addition, since the shaft body 4 is held between the electrode pieces 9 and 9 with a predetermined pressing force, both are brought into close contact with each other, the contact resistance can be reduced, and electrical conduction between the two can be performed satisfactorily.

この接触部分の電気抵抗を少なくすることで、通電時にこの部位の発熱が少なくなり、材料及び電極の熱による変質(合金化反応)、劣化等の悪影響が防止される。上記上部電極8の移動機構は、軸体4を挟み込んでプレート2の接合予定の孔部3の位置に移動させ位置決めする機能、この孔部3の上部の位置に設定・保持する機能、及び軸体4を狭持した状態で通電する機能とを有する。このように、電極で軸体を保持した状態で通電することで、軸体が正確にかつ安定してプレートの孔部に圧入できる。   By reducing the electrical resistance of this contact portion, heat generation at this portion is reduced during energization, and adverse effects such as alteration (alloying reaction) and deterioration due to heat of the material and the electrode are prevented. The moving mechanism of the upper electrode 8 has a function of sandwiching the shaft body 4 and moving and positioning it to the position of the hole 3 to be joined to the plate 2, a function of setting / holding at the position above the hole 3, and a shaft A function of energizing the body 4 while holding it. In this way, by energizing the shaft with the electrode held, the shaft can be accurately and stably press-fitted into the hole of the plate.

上部電極8は、軸体4の搬送を行わせるために可動の電極片9,9により構成されるが、軸体4の位置決め精度を確保するため、この上部電極により軸体4を狭持してプレート2の孔部3の上部位置に移動した後に、この位置に位置決め固定できる方式とする。他に、電極片9,9の一方を固定位置に配置し、他方を押圧可能として軸体4を狭持させることで位置決め精度を確保することもできる。   The upper electrode 8 is composed of movable electrode pieces 9 and 9 for transporting the shaft body 4. In order to ensure the positioning accuracy of the shaft body 4, the shaft body 4 is sandwiched by the upper electrode. Then, after moving to the upper position of the hole 3 of the plate 2, the position can be fixed at this position. In addition, positioning accuracy can be ensured by arranging one of the electrode pieces 9 and 9 at a fixed position and sandwiching the shaft body 4 so that the other can be pressed.

通電は、下部電極6と上部電極8との間に行う。このとき、上記押圧電極10を上部電極8の一部として用いるので、軸体4と上部電極8との間の電気抵抗が低減され良好な電流の供給が行える。軸体4は、電極と比べて電気抵抗の大きな鋼材などからなるため、3つの電極6,8,10を用いて軸体4自体の電気抵抗の影響を少なくし、電気抵抗による発熱をプレート2と軸体4との接合部11の狭い範囲に集中させることで電気損失を低減する。また、上記上部電極8の電極片9,9は、圧入の妨げとならないよう、上記押圧電極10の下降に伴って滑らかに下方移動できるようにする。   Energization is performed between the lower electrode 6 and the upper electrode 8. At this time, since the pressing electrode 10 is used as a part of the upper electrode 8, the electrical resistance between the shaft body 4 and the upper electrode 8 is reduced, and a good current can be supplied. Since the shaft body 4 is made of a steel material having a larger electrical resistance than the electrodes, the influence of the electrical resistance of the shaft body 4 itself is reduced by using the three electrodes 6, 8, and 10, and heat generated by the electrical resistance is reduced to the plate 2. The electric loss is reduced by concentrating in a narrow range of the joint portion 11 between the shaft body 4 and the shaft body 4. Further, the electrode pieces 9, 9 of the upper electrode 8 can be smoothly moved downward as the pressing electrode 10 is lowered so as not to hinder press-fitting.

電極片9,9の狭持部16の形状は、軸体4などの接合物の断面の片半部分の形状と同じか、少し大きい(半径大)形状とする。例えば、接合物の断面形状が円形の場合には、電極片の狭持部の形状は、同一半径の半円形状或いはこの一部の円弧形状とし、両者の密着性を高めて接触抵抗を低減する。このため、例えば図3(a)に示すように、軸体4の断面形状が円形の場合には、電極片9の狭持部の形状は、同一半径の円弧形状(又は半円形状)とする。   The shape of the sandwiching portion 16 of the electrode pieces 9, 9 is the same as or slightly larger (large radius) than the shape of the half portion of the cross section of the joined body such as the shaft body 4. For example, when the cross-sectional shape of the joined product is circular, the shape of the sandwiching portion of the electrode piece is a semicircular shape with the same radius or a partial arc shape thereof, and the contact resistance is reduced by increasing the adhesion between them. To do. Therefore, for example, as shown in FIG. 3A, when the cross-sectional shape of the shaft body 4 is circular, the shape of the holding portion of the electrode piece 9 is an arc shape (or semicircular shape) having the same radius. To do.

また、電極片が2個の電極の場合には、各部材の製造誤差等により、図3(c)に示すように、電極片の両端のみが軸体に当たって両者の接触が不十分な形態が想定できる。このため、上述したように電極片の狭持部の形状を軸体の側面部の外形形状と同じか、あるいは電極片の狭持部の断面半径を少し大きく形成(図3(b))するようにしても良い。また、図3(d)に示すように、電極の中間部にスリットを設けることで、狭持力によりこのスリットを広げて電極片の狭持部を開き、これにより狭持部を軸体に密着させることができる。   In addition, when the electrode pieces are two electrodes, due to manufacturing error of each member, etc., as shown in FIG. 3C, only both ends of the electrode pieces hit the shaft body and the contact between them is insufficient. Can be assumed. For this reason, as described above, the shape of the holding portion of the electrode piece is the same as the outer shape of the side surface portion of the shaft body, or the cross-sectional radius of the holding portion of the electrode piece is formed slightly larger (FIG. 3B). You may do it. Further, as shown in FIG. 3 (d), by providing a slit in the middle part of the electrode, the slit is widened by the holding force to open the holding part of the electrode piece. It can be adhered.

一方、電極の材質はクロム銅で軟質であり、例えば軸体が鋼材からなる場合には、電極片の形状を軸体に馴染ませることも可能である。また、電極と軸体との接触面積は、圧入接合される接合部11の面積と同等か若しくはより大きく設定して電気抵抗を低くし、電気抵抗による発熱を接合部に集中させるようにする。同時に、各電極片と軸体との接触位置(通電位置)は、軸体とプレートとの接合部11に近い位置(但し圧入される高さ範囲は確保)とし、かつ等距離にあることが望ましく、また隣り合う電極片同士の間隔はできるだけ小さくし、これにより軸体自体の電気抵抗の影響を少なくし、また電極との接触面積を大きくして電気抵抗を低減する。   On the other hand, the electrode material is soft, such as chromium copper. For example, when the shaft body is made of steel, the shape of the electrode piece can be adapted to the shaft body. In addition, the contact area between the electrode and the shaft is set to be equal to or larger than the area of the joint 11 to be press-fitted and joined to lower the electrical resistance so that heat generated by the electrical resistance is concentrated at the joint. At the same time, the contact position (energization position) between each electrode piece and the shaft body is close to the joint 11 between the shaft body and the plate (however, the height range to be press-fitted is ensured) and is equidistant. Desirably, the interval between adjacent electrode pieces is made as small as possible, thereby reducing the influence of the electric resistance of the shaft itself, and increasing the contact area with the electrode to reduce the electric resistance.

上記実施の形態において、上部電極8で軸体4を狭持する構成としたことで、両者の接触面積を広く確保することができ、また接合部11の近傍に電極を設けることができて軸体4自体の電気抵抗の影響が少なくなり、通電が良好行える。また軸体4を挟んで支持することで、軸体4の保持、搬送、着脱等が効率的に行えて作業効率がアップし、作業性が大幅に改善される。   In the above embodiment, the structure in which the shaft body 4 is sandwiched by the upper electrode 8 can ensure a wide contact area between the two, and an electrode can be provided in the vicinity of the joint 11 so that the shaft The influence of the electrical resistance of the body 4 itself is reduced, and energization can be performed well. Further, by supporting the shaft body 4 with the shaft body 4 interposed therebetween, the shaft body 4 can be efficiently held, transported, and attached, so that work efficiency is improved and workability is greatly improved.

図4は、3個の電極片20を用いて軸体4を狭持する形態を示したものである。この形態では、電極片20の狭持部21の形状が接合物である軸体4の側面部12の形状と同じであるが、各電極片20の狭持部21の窪みの程度が浅いため、電極片20は軸体4から容易に外れる。このように電極片が3個以上の場合には、上記電極片が2個の場合のように、電極片の狭持部に軸体が挟まって取り外しにくいという問題は生じない。   FIG. 4 shows a mode in which the shaft body 4 is sandwiched using three electrode pieces 20. In this embodiment, the shape of the sandwiching portion 21 of the electrode piece 20 is the same as the shape of the side surface portion 12 of the shaft body 4 that is a joined product, but the degree of depression of the sandwiching portion 21 of each electrode piece 20 is shallow. The electrode piece 20 is easily detached from the shaft body 4. Thus, when there are three or more electrode pieces, there is no problem that the shaft body is sandwiched between the electrode pieces and is not easily removed as in the case of two electrode pieces.

上記上部電極8は、2片からなる電極片を用いて軸体の両側から挟持するものであるが、これは上述したように3個の電極片、さらには4個或いはこれ以上の電極片を持つ形態とすることができる。このうち、電極片が2個からなる電極は、電極片を狭持する機構の構成が比較的簡易であり装置の簡素化が期待できる一方、3個或いは4個の電極片を用いた電極は軸体4の支持が中心部に集中して安定し、また軸体の着脱が容易に行えるという利点がある。   The upper electrode 8 is sandwiched from both sides of the shaft using two electrode pieces. As described above, the upper electrode 8 is composed of three electrode pieces, and further four or more electrode pieces. It can be in the form of having. Among these, the electrode composed of two electrode pieces has a relatively simple structure for holding the electrode pieces, and simplification of the apparatus can be expected. On the other hand, an electrode using three or four electrode pieces is There is an advantage that the support of the shaft body 4 is concentrated and stabilized at the center, and the shaft body can be easily attached and detached.

図5は、電極片22を用いて種々の軸体24(中実、中空)を狭持する場合の両者の形態(断面)を示したものである。なお、この形態は両者の狭持部位についての形態を示したものであり、軸体或いは筒体の接合部位の形状とは必ずしも一致するものではない。軸体等について、狭持部位が断面円形であって接合部位の断面が小判状の場合、或いはその逆の場合等が有り得る。   FIG. 5 shows both forms (cross sections) in the case of holding various shaft bodies 24 (solid, hollow) using the electrode pieces 22. In addition, this form shows the form about both pinching site | parts, and it does not necessarily correspond with the shape of the junction part of a shaft or a cylinder. As for the shaft body and the like, there may be a case where the holding portion is circular in cross section and the cross section of the joining portion is oval or vice versa.

図5(a)は軸体24の側面部が断面楕円形の形態を、図5(b)は断面が中空の楕円形の形態を示す。図5(c)は、軸体24の側面部が断面四角形状の形態を、図5(d)は、軸体の側面部が断面小判状をそれぞれ示す。この場合、(a)(b)は、各電極片の狭持部の形状を、軸体の側面部(片半部分)の形状と同一に形成し、狭持したときにこの軸体の側面部(片半部分)の全体に各電極片の狭持部が当接する形態である。また、(c)(d)は、電極片の狭持部の形状を、軸体の側面部(片半部分)の一部又は全体の形状と同一に形成し、狭持したときにこの軸体の側面部(片半部分)の約半分或いは半分以上が各電極片の狭持部に当接する形態である。   FIG. 5A shows an elliptical shape in which the side surface portion of the shaft body 24 has an elliptical cross section, and FIG. 5B shows an elliptical shape in which the cross section is hollow. FIG. 5C shows a configuration in which the side surface portion of the shaft body 24 has a quadrangular cross section, and FIG. 5D shows a shape in which the side surface portion of the shaft body has an oval cross section. In this case, (a) and (b) are the same as the shape of the side surface (half part) of the shaft body, and the side surface of the shaft body is held when the electrode body is sandwiched. This is a form in which the sandwiching portion of each electrode piece comes into contact with the entire portion (half portion). Further, (c) and (d) show that the shape of the holding portion of the electrode piece is the same as the shape of a part or the whole of the side surface portion (half portion of the shaft body), and this shaft is held when held. About half or more than half of the side surface (half part) of the body is in contact with the sandwiching part of each electrode piece.

上記図5(c)の四角形状の軸体24は、各角部の断面形状は軸体の芯を中心とする円の一部形状(円弧)である。この軸体24は、その接合部の外径(直径)がプレート2の孔部3の直径より僅かに大きく、この圧入代により、軸体24の接合部の外周部位が、プレート2の孔部3の内壁面部と接し、プレート2の孔部3に圧入した場合、軸体の角部が孔部3に接して圧入されるため一部が圧入接合される部分接合が行われる。図5(d)の小判状の軸体24についても同様に、部分接合が行われる。   In the rectangular shaft body 24 of FIG. 5C, the cross-sectional shape of each corner is a partial shape (arc) of a circle centering on the core of the shaft body. The shaft body 24 has an outer diameter (diameter) of the joint portion slightly larger than the diameter of the hole portion 3 of the plate 2, and due to this press-fitting allowance, the outer peripheral portion of the joint portion of the shaft body 24 becomes the hole portion of the plate 2. 3 is in contact with the inner wall surface of the plate 2 and press-fitted into the hole 3 of the plate 2, the corner of the shaft body is press-fitted into contact with the hole 3, so that partial joining is performed in which a part is press-fitted. Similarly, partial joining is performed on the oval shaft body 24 shown in FIG.

図6は、軸体と電極片との当接箇所が比較的ラフな形態のものである。図6(a)は、電極片22の狭持部の形状がV字状のものであり、この形態の電極片は種々の形状の軸体24に対応可能であり汎用性がある。図6(b)は、電極片22の狭持部に複数の突起が形成されたものであり、軸体24の側面部の形状が一定しない場合、或いは凸凹がある場合等に適用される。これは、要素部品によっては形状が複雑なものがあり、そのようなものを軸体として扱う場合に用いられる。   FIG. 6 shows a configuration in which the contact portion between the shaft body and the electrode piece is relatively rough. In FIG. 6A, the shape of the sandwiching portion of the electrode piece 22 is V-shaped, and the electrode piece of this form is compatible with various shapes of the shaft body 24 and is versatile. FIG. 6B is a case where a plurality of protrusions are formed on the sandwiching portion of the electrode piece 22, and is applied when the shape of the side surface portion of the shaft body 24 is not constant, or when there are irregularities. This is used when some element parts have complicated shapes, and such parts are handled as shaft bodies.

図7(a)は、他の形態の上部電極30を用いた圧入接合の機構を示したものである。この上部電極30は、一対形状の電極片32,33を有しこれらの電極片で軸体4を狭持する。各電極片32,33にはそれぞれ、L字状に屈曲した押圧部34が形成されている。このため、電極片32,33は、軸体4を狭持する機能に加えて、軸体4を軸方向に押圧する機能を有する。   FIG. 7A shows a press-fit joining mechanism using another form of the upper electrode 30. The upper electrode 30 has a pair of electrode pieces 32 and 33, and the shaft body 4 is sandwiched between these electrode pieces. Each electrode piece 32, 33 is formed with a pressing portion 34 bent in an L shape. For this reason, the electrode pieces 32 and 33 have a function of pressing the shaft body 4 in the axial direction in addition to the function of holding the shaft body 4.

この上部電極30として、例えば、図7(b)に示すコレットチャック35の形態及び締め付け具としての機能を適用することができる。これは上部電極として、クローム銅製の電極片36を3個有し、これら電極片36によりチャックの機能を用いて軸体4を狭持する。このコレットチャックの電極によれば、軸体の狭持及び移動が容易に行え位置決め精度も高められる。また上部電極として、軸体の側面部に加えて上面部が接触してさらに電気抵抗が低減され、また軸体の押圧も行えて部品点数が削減される。   As the upper electrode 30, for example, the form of the collet chuck 35 shown in FIG. 7B and the function as a fastening tool can be applied. This has three electrode pieces 36 made of chrome copper as upper electrodes, and the shaft body 4 is held by these electrode pieces 36 using the function of a chuck. According to the electrode of the collet chuck, the shaft body can be easily held and moved, and the positioning accuracy can be improved. Further, as the upper electrode, in addition to the side surface portion of the shaft body, the upper surface portion contacts to further reduce the electric resistance, and the shaft body can be pressed to reduce the number of parts.

図8は、上記コレットチャック35等の締め付け具を用いて位置決めなどを行う圧入接合の機構を示したものである。これは、上部電極として電極片38,39を有しこれらの電極片で軸体4を狭持する一方、軸体4の上部をコレットチャック35で狭持保持する。そして、このコレットチャック35によって軸体4の移動及び位置決めを行ない、プレス機構によりコレットチャック35を押圧する。   FIG. 8 shows a press-fit joining mechanism for positioning using a fastening tool such as the collet chuck 35. This has electrode pieces 38 and 39 as upper electrodes, and the shaft body 4 is pinched by these electrode pieces, while the upper portion of the shaft body 4 is held by the collet chuck 35. The shaft body 4 is moved and positioned by the collet chuck 35, and the collet chuck 35 is pressed by a press mechanism.

このコレットチャック35によれば、軸体4の狭持及び移動が容易に行え位置決め精度も高められる。このとき、コレットチャック35を上部電極の一部として機能させることができ、これにより電極が軸体の側面部に加えて上部及び上面部が接触してさらに電気抵抗が低減される。この圧入接合機構は、特に軸体4が比較的長尺の場合には、軸体の支持が安定して有効である。   According to the collet chuck 35, the shaft body 4 can be easily held and moved, and the positioning accuracy can be improved. At this time, the collet chuck 35 can function as a part of the upper electrode, whereby the electrode is in contact with the upper and upper surface portions in addition to the side surface portion of the shaft body, and the electrical resistance is further reduced. This press-fit joining mechanism is stable and effective especially when the shaft body 4 is relatively long.

図9(a)は、さらに他の形態の上部電極40を用いた圧入接合の機構を示したものである。この上部電極40は、電極を電極片42,43に2分割し、この分割した電極片42,43で軸体4を狭持する。   FIG. 9 (a) shows a press-fit joining mechanism using still another form of the upper electrode 40. FIG. The upper electrode 40 divides the electrode into two electrode pieces 42 and 43, and the shaft body 4 is held between the divided electrode pieces 42 and 43.

図9(b)に示すように、上記電極片42は、直方体状で、軸体を狭持する側には狭持部44が形成されている。上記電極片43には一定の幅で切れ込んだ溝部45が形成され、また電極片43の下部側には軸体4を狭持する狭持部44が設けられ、上部側には軸体4の上部を被う押圧部46が設けられている。このため、電極片43は、軸体4を狭持し、軸体4を軸方向に押圧する機能を有する。上記電極片42は、電極片43の溝部45に嵌め込みが可能であり、また各電極片42,43の狭持部44の形状は、軸体の側面部(片半部分)の形状と同一に形成されている。この上部電極においても、軸体の側面部に加えて上面部が接触してさらに電気抵抗が低減され、また軸体の押圧も行えて部品点数が削減される。   As shown in FIG. 9B, the electrode piece 42 has a rectangular parallelepiped shape, and a holding portion 44 is formed on the side holding the shaft body. The electrode piece 43 is formed with a groove 45 cut at a constant width, a holding portion 44 for holding the shaft body 4 is provided on the lower side of the electrode piece 43, and the shaft body 4 is provided on the upper side. A pressing portion 46 that covers the upper portion is provided. For this reason, the electrode piece 43 has a function of holding the shaft body 4 and pressing the shaft body 4 in the axial direction. The electrode piece 42 can be fitted into the groove 45 of the electrode piece 43, and the shape of the holding portion 44 of each electrode piece 42, 43 is the same as the shape of the side surface portion (one half portion) of the shaft body. Is formed. Also in this upper electrode, in addition to the side surface portion of the shaft body, the upper surface portion contacts to further reduce the electrical resistance, and the shaft body can be pressed to reduce the number of parts.

図10は、特に軸体4が長尺の場合にこれを支持する上部電極70を備えた圧入接合の機構を示したものである。この上部電極70は、全体がクロム銅で形成された略枠状の形態であり、上部の押圧電極部71、左右の支持電極部72,73、及びこれら支持電極部72,73の下部からそれぞれ向かい合わせに形成された左右の電極片74,75を有する。これら電極片74,75の狭持部76の形状についても、上記電極片9,22と同様に軸体4の側面部(片半部分)の形状と一部又は全体が同一に形成されている。上記支持電極部72,73は、上記押圧電極部と各電極片との間隔を確保するため、軸体4の長さに応じた寸法の長さに形成される。このように支持電極部72,73を両側に設けることにより、電流の供給がバランス良く行えまた軸体の支持も安定し良好である。   FIG. 10 shows a press-fit joining mechanism provided with an upper electrode 70 for supporting the shaft body 4 particularly when the shaft body 4 is long. The upper electrode 70 has a substantially frame shape formed entirely of chrome copper. The upper electrode electrode 71, the left and right support electrode portions 72 and 73, and the lower portions of the support electrode portions 72 and 73, respectively. It has left and right electrode pieces 74 and 75 formed facing each other. The shape of the sandwiching portion 76 of these electrode pieces 74 and 75 is also formed partly or entirely the same as the shape of the side surface portion (half portion) of the shaft body 4, similarly to the electrode pieces 9 and 22. . The support electrode portions 72 and 73 are formed to have a length corresponding to the length of the shaft body 4 in order to ensure a space between the pressing electrode portion and each electrode piece. By providing the support electrode portions 72 and 73 on both sides in this way, current can be supplied in a well-balanced manner, and the shaft body can be stably supported.

この上部電極70は中央部に軸体4を支持する形態であり、この軸体4の下部近傍は上記電極片74,75で狭持される一方、この軸体4の上部は、押圧電極部71との間に絶縁体77を介在させて保持されている。上記電極片74,75は、例えばエアーシリンダの圧力或いはバネ圧を利用して軸体4を狭持する。また、上記押圧電極部71の上部には板状の押圧電極78が配置され、この押圧電極78はプレス機構により押圧される。   The upper electrode 70 has a configuration in which the shaft body 4 is supported at the central portion, and the vicinity of the lower portion of the shaft body 4 is held between the electrode pieces 74 and 75, while the upper portion of the shaft body 4 is a pressing electrode portion. 71 is held with an insulator 77 interposed therebetween. The electrode pieces 74 and 75 hold the shaft body 4 by using, for example, air cylinder pressure or spring pressure. A plate-like pressing electrode 78 is disposed above the pressing electrode portion 71, and the pressing electrode 78 is pressed by a pressing mechanism.

上記絶縁体77は、軸体4の上部を絶縁して軸体4自体に電流を流さないようにしている。社内試験においても、絶縁体77を設けないで軸体4に上部から電流を流すと、軸体4とプレート2との接合部の発熱量が低減し、接合が十分に行えないことが確認されている。特に、軸体4が長尺であり、軸体4の材料が電気抵抗の高いステンレス鋼等の場合には、この軸体4に電流を流すと軸体4自体が発熱し又接合部の発熱量が低減して好ましくない。これは、最短経路を流れるという電流の性質及び軸体4と電極との電気抵抗の差などが影響し、全体的に電流の流れが規制され接合部への供給に不都合をきたすものと推測される。社内実施によれば、軸体4が鋼製でその直径が10mm、全長が略40mm〜130mmのもの、及び軸体4がステンレス鋼製でその直径が略10mm、全長が略30mm以上のものについては、上記絶縁体77の効果が見られ、この絶縁体の介在により圧入接合が良好に行われている。   The insulator 77 insulates the upper portion of the shaft body 4 so that no current flows through the shaft body 4 itself. Even in the in-house test, it was confirmed that if current is passed through the shaft body 4 from above without providing the insulator 77, the amount of heat generated at the joint between the shaft body 4 and the plate 2 is reduced, and the joining cannot be performed sufficiently. ing. In particular, when the shaft body 4 is long and the material of the shaft body 4 is stainless steel or the like having a high electrical resistance, the shaft body 4 itself generates heat when the current flows through the shaft body 4, and heat is generated at the joint. The amount is undesirably reduced. This is presumed to be caused by inconvenience in the supply to the junction because the current flow and the difference in electrical resistance between the shaft body 4 and the electrode affect the current flow and the current flow is restricted. The According to in-house implementation, the shaft body 4 is made of steel and the diameter is 10 mm, the total length is about 40 mm to 130 mm, and the shaft body 4 is made of stainless steel, the diameter is about 10 mm, and the total length is about 30 mm or more. In this case, the effect of the insulator 77 is observed, and the press-fitting is favorably performed by the interposition of the insulator.

この上部電極70では、押圧電極部71の上部の押圧電極78がプレス機構により押圧される一方、電源から押圧電極78に引加された電流が押圧電極部71を介して支持電極部72,73に供給され、この電流は支持電極部72,73を通過して電極片74,75に至り、軸体4に供給される。この上部電極によれば、長尺の軸体であってもこれを正確かつ安定して支持することができて実用的であり、また軸体における接合部の近傍から電流が供給できて軸体自体の電気抵抗の影響を受けることがなく、加えて電極と軸体との接触抵抗も低減され、また軸体の押圧も効率的に行える。   In this upper electrode 70, the pressing electrode 78 on the upper side of the pressing electrode portion 71 is pressed by the pressing mechanism, while the current applied to the pressing electrode 78 from the power source is supported by the supporting electrode portions 72 and 73 via the pressing electrode portion 71. The current passes through the support electrode portions 72 and 73 to reach the electrode pieces 74 and 75 and is supplied to the shaft body 4. According to this upper electrode, even a long shaft body can be supported accurately and stably, and it is practical, and a current can be supplied from the vicinity of the joint portion of the shaft body so that the shaft body can be supplied. In addition, the contact resistance between the electrode and the shaft body is reduced, and the shaft body can be pressed efficiently.

図11は、下部電極6に配置されるプレート2の位置決めについて好適な圧入接合の機構を示したものである。これは、下部電極6に設けた穴部80内にスプリング82を配置し、このスプリング82の上部に位置決部材84を配置したものである。この位置決部材84は合成樹脂或いはセラミックス等の絶縁材料からなり、基部部86から円柱状に突起した係合部87が形成されこれらの間に段差部88が設けられている。また、上記穴部80の上部は内径が縮径した係止孔部81が形成されている。上記係合部87の外径は、上記プレート2の孔部3よりも若干小さく形成され、またこの係止孔部81の内径は上記軸体4の径よりも少し大きく形成されている。   FIG. 11 shows a press-fit joining mechanism suitable for positioning the plate 2 disposed on the lower electrode 6. In this configuration, a spring 82 is disposed in a hole 80 provided in the lower electrode 6, and a positioning member 84 is disposed above the spring 82. The positioning member 84 is made of an insulating material such as a synthetic resin or ceramics, and an engaging portion 87 protruding in a cylindrical shape from the base portion 86 is formed, and a step portion 88 is provided therebetween. Further, the upper portion of the hole 80 is formed with a locking hole 81 having a reduced inner diameter. The outer diameter of the engaging portion 87 is slightly smaller than the hole portion 3 of the plate 2, and the inner diameter of the locking hole portion 81 is slightly larger than the diameter of the shaft body 4.

ここで、上記位置決部材84は、下部電極6の穴部80の係止穴部81に段差部88が係止した状態で、係合部87が下部電極6の表面部7から突出している。この状態で、上記プレート2の孔部3を、上記係合部87に嵌入して配置することで、プレート2の位置決めが正確に行える。軸体4の圧入の際には、軸体4の降下に伴って位置決部材84はスプリング82に抗して下方に移動し、接合品を除去すれば復帰する。この穴部80に設けた位置決部材により、プレート2の位置決めが簡単かつ正確に行え、加えて係止穴部81は、上記穴部15と同様にプレートの逃がし及びスパーク防止などの効果が得られる。   Here, in the positioning member 84, the engaging portion 87 protrudes from the surface portion 7 of the lower electrode 6 in a state where the step portion 88 is locked to the locking hole portion 81 of the hole portion 80 of the lower electrode 6. . In this state, by positioning the hole 3 of the plate 2 so as to fit into the engaging portion 87, the plate 2 can be positioned accurately. When the shaft body 4 is press-fitted, the positioning member 84 moves downward against the spring 82 as the shaft body 4 is lowered, and returns when the joined product is removed. The positioning member provided in the hole 80 allows the positioning of the plate 2 to be performed easily and accurately. In addition, the locking hole 81 has effects such as escape of the plate and prevention of sparks as with the hole 15. It is done.

上記プレート、軸体等のワークの材料としては、一般加工用鋼材、自動車用高張力鋼材、その他の金属材料、SUS(ステンレス鋼)、SUSと炭素鋼とを組み合わせたもの、機械構造用炭素鋼、機械構造用合金鋼、耐熱鋼、工具鋼、バネ鋼、鋳鉄、快削鋼、軸受鋼、一般加工用鋼材、圧力容器用鋼材、チタン、アルミニウム、マグネシウムなどの軽金属、軽金属合金等が適用可能である。   Materials for workpieces such as plates and shafts include steel materials for general processing, high-tensile steel materials for automobiles, other metal materials, SUS (stainless steel), a combination of SUS and carbon steel, carbon steel for machine structures Alloy steel for machine structure, heat-resistant steel, tool steel, spring steel, cast iron, free-cutting steel, bearing steel, steel for general processing, steel for pressure vessels, light metals such as titanium, aluminum, magnesium, light metal alloys, etc. are applicable It is.

上記圧入接合装置には図示しないプレス機構が装備され、このプレス機構は、軸体4の上部に配置される押圧電極10を押圧可能に構成され、軸体4を加圧降下する。一方、上記プレス機構とともに搬送装置としてのロボットが配置され、このロボットは腕部(マニュピレータ等)でプレート2及び軸体4を掴むことができ、これらプレート2及び軸体4を所定位置まで搬送することができる。   The press-fitting and bonding apparatus is equipped with a press mechanism (not shown). The press mechanism is configured to be able to press the pressing electrode 10 arranged on the upper portion of the shaft body 4 and pressurizes and lowers the shaft body 4. On the other hand, a robot as a transfer device is arranged together with the press mechanism, and this robot can hold the plate 2 and the shaft body 4 with an arm (manipulator or the like), and transports the plate 2 and the shaft body 4 to a predetermined position. be able to.

ここで、上記圧入接合装置を用い、上記図1に示すように、ワークとして上記プレート2に上記軸体4を圧入接合するときの工程について説明する。
(1)ロボットを用いて、上記下部電極6の表面部7まで上記プレート2を搬送し所定位置に載置する。このプレート2は、例えば両側から狭持部材を押し当てて上記所定位置に保持固定するようにしてもよい。
(2)ロボットを用いて、上記軸体4をプレート2の孔部3の上部まで搬送し、この位置に仮置きする。
(3)上記軸体4を上部電極8の電極片9,9により所定の押圧力で狭持し、併せて軸体の位置を調整してプレート2の孔部3の中心同一上に位置決めし十分な位置精度を確保する。
(4)上記プレス機構により、軸体4の上部を押圧電極10を介して押圧し、軸体4に一定の加圧力を付勢する。
(5)上部電極8(および押圧電極10)と、下部電極6との間に通電する。すると、軸体4とプレート2の孔部3との接合部に電流が流れ、接触抵抗による電気抵抗熱により発熱しこの接合部が軟化する。
(6)この接合部の軟化により、加圧付勢された軸体4がプレート2の孔部3内に圧入される。このとき、圧入代により両部材の接合部にしごきの作用が生じて清浄な接合界面が形成され圧入接合が行われる。ここでの圧入接合は、圧入による塑性変形(熱塑性)を伴った固相接合である。そして、軸体4はプレート2の孔部3内に必要な深さまで圧入される。
Here, a process when the shaft body 4 is press-fitted and joined to the plate 2 as a workpiece as shown in FIG. 1 using the press-fitting device will be described.
(1) Using a robot, the plate 2 is transported to the surface portion 7 of the lower electrode 6 and placed at a predetermined position. For example, the plate 2 may be held and fixed at the predetermined position by pressing a pinching member from both sides.
(2) The shaft body 4 is transported to the upper part of the hole 3 of the plate 2 using a robot and temporarily placed at this position.
(3) The shaft body 4 is held by the electrode pieces 9 and 9 of the upper electrode 8 with a predetermined pressing force, and the position of the shaft body is adjusted and positioned at the same center of the hole 3 of the plate 2. Ensure sufficient positional accuracy.
(4) The upper part of the shaft body 4 is pressed through the pressing electrode 10 by the press mechanism, and a constant pressure is applied to the shaft body 4.
(5) Energization is performed between the upper electrode 8 (and the pressing electrode 10) and the lower electrode 6. Then, a current flows through a joint portion between the shaft body 4 and the hole 3 of the plate 2, and heat is generated by electric resistance heat due to contact resistance, and the joint portion is softened.
(6) Due to the softening of the joint, the pressure-biased shaft body 4 is press-fitted into the hole 3 of the plate 2. At this time, due to the press-fitting allowance, a squeezing action is produced at the joint between the two members, and a clean joint interface is formed and press-fit joining is performed. The press-fit joining here is solid-phase joining accompanied by plastic deformation (thermoplasticity) by press-fit. The shaft body 4 is press-fitted into the hole 3 of the plate 2 to a required depth.

上記圧入方法では、ワークをロボットで搬送し、その後別途に上部電極で軸体を狭持してプレートに圧入接合する。この方法では、上部電極の構造のシンプル化が図れ、また上部電極を接合装置本体としての下部電極等に直接取り付けて正確かつ強固に装備できるので、位置決め精度或いは繰り返し精度が良好である。また同方法では、圧入接合中にロボットが次のワークを取得し所定位置まで搬送する作業、及び接合した後のワークを次の工程に移動する作業が、接合作業と同時に進められ大量生産が行える。   In the press-fitting method, the workpiece is transported by a robot, and then the shaft is separately clamped by the upper electrode and press-fitted to the plate. In this method, the structure of the upper electrode can be simplified, and the upper electrode can be directly attached to the lower electrode or the like as the main body of the bonding apparatus so that it can be mounted accurately and firmly. Therefore, the positioning accuracy or repeatability is good. In this method, the robot acquires the next workpiece during press-fit welding, transports it to a predetermined position, and moves the workpiece after joining to the next process. .

他の圧入方法として、ロボットに電極を装備させ、このロボットが軸体を狭持した状態で接合位置まで搬送し、かつこの位置で軸体を位置決めし保持しそのままプレートに圧入接合することもできる。この方法では、例えば同一のプレートに複数の軸体を接合するような形態では、フレキシブルな対応が可能となる。また、接合装置自体の構造が簡略化でき、ワークの種類が多い場合等には好適である。   As another press-fitting method, the robot can be equipped with electrodes, and the robot can transport the shaft body to the joining position while holding the shaft body, and can position and hold the shaft body at this position and press-fit to the plate as it is. . In this method, for example, in a form in which a plurality of shaft bodies are joined to the same plate, a flexible response is possible. In addition, the structure of the joining apparatus itself can be simplified, which is suitable when there are many types of workpieces.

上記圧入の工程において、接合界面には滑り方向の動きが生まれ、これにより表面の不純物質層、酸化被膜等が削り取られかつ除去され、この作用により固相接合に必須の清浄な接合表面が形成されて、両者の接合が強固に行われる。そして、通電が終了した後、プレス機構の加圧力を除荷して押圧電極10を引き上げる。併せて、上部電極8に狭持される軸体4から各電極片9,9を引き離し、軸体4を開放脱着し、圧入工程を終える。   In the above press-fitting process, a sliding direction motion is generated at the bonding interface, which removes and removes the surface impurity layer, oxide film, etc., and this action forms a clean bonding surface essential for solid phase bonding. As a result, the two are firmly joined. Then, after energization is completed, the pressure applied by the press mechanism is unloaded and the pressing electrode 10 is pulled up. At the same time, the electrode pieces 9, 9 are pulled away from the shaft body 4 sandwiched by the upper electrode 8, the shaft body 4 is opened and detached, and the press-fitting process is completed.

図12は、他の実施の形態として、軸体と筒体との圧入接合の機構を示したものである。これは、圧入接合装置を用いワークとして筒体52と軸体54とを用い、この筒体52の孔部53内に軸体54を圧入接合する形態を示している。この軸体54は、棒状(中実)又は筒状(中空)のものがある。   FIG. 12 shows a mechanism for press-fitting and joining a shaft body and a cylindrical body as another embodiment. This shows a form in which a cylindrical body 52 and a shaft body 54 are used as a workpiece using a press-fit joining apparatus, and the shaft body 54 is press-fitted and joined into a hole 53 of the cylindrical body 52. The shaft body 54 may be rod-shaped (solid) or cylindrical (hollow).

この圧入接合装置についても、通電のための電極を有する圧入機構、位置決め移動のための移動機構、及びプレス機構を有する。この圧入機構は、上記筒体52を支持する支持盤56、筒体52を狭持する2個の電極片59,59に分割された下部電極58、及び上記軸体54を狭持する2個の電極片62,63に分割された上部電極64を有し、各電極は何れも材質はクローム銅製である。上記支持盤56は、クローム銅製からなり下部電極58の一部の電極としても機能する。   This press-fit joining apparatus also has a press-fit mechanism having an electrode for energization, a moving mechanism for positioning movement, and a press mechanism. The press-fitting mechanism includes a support plate 56 that supports the cylindrical body 52, a lower electrode 58 that is divided into two electrode pieces 59 and 59 that sandwich the cylindrical body 52, and two that sandwich the shaft body 54. The upper electrode 64 is divided into electrode pieces 62 and 63, and each electrode is made of chrome copper. The support plate 56 is made of chrome copper and also functions as a part of the lower electrode 58.

上記上部電極64の電極片62には、軸体54を狭持する狭持部66が形成され、また電極片63には、下部側に電極片62と同様に軸体54を狭持する狭持部66が形成され、上部側にこの狭持部66からL形に屈曲形成され軸体54の上部を被う押圧部67が設けられている。このため、電極片63は、軸体54を狭持する機能に加えて、軸体54を押圧する機能を有する。   The electrode piece 62 of the upper electrode 64 is formed with a holding portion 66 for holding the shaft body 54, and the electrode piece 63 is narrow to hold the shaft body 54 on the lower side like the electrode piece 62. A holding portion 66 is formed, and a pressing portion 67 that is bent in an L shape from the holding portion 66 and covers the upper portion of the shaft body 54 is provided on the upper side. For this reason, the electrode piece 63 has a function of pressing the shaft body 54 in addition to a function of holding the shaft body 54.

上記下部電極58は、筒体52を狭持する電極として、上記上部電極64と同様に2つの電極片59,59を有している。これらの電極片59,59は、所定の肉厚の板片であり、筒体52を狭持する部位には筒体52の側面部の断面形状と同一形状の狭持部が形成されている。また、上記上部電極64は移動機構により保持され、この移動機構は、上記軸体54の側面部を2個の電極片62,63により所定の押圧力とともに機械的に狭持する。軸体54は、上部電極64に狭持された状態で、移動機構により筒体52の孔部53の上部に搬送して位置決めされ保持固定される。   The lower electrode 58 has two electrode pieces 59 and 59 as the upper electrode 64 as an electrode for sandwiching the cylindrical body 52. These electrode pieces 59, 59 are plate pieces having a predetermined thickness, and a holding portion having the same shape as the cross-sectional shape of the side surface portion of the cylinder body 52 is formed in a portion where the cylinder body 52 is held. . The upper electrode 64 is held by a moving mechanism, and the moving mechanism mechanically holds the side surface portion of the shaft body 54 with two electrode pieces 62 and 63 together with a predetermined pressing force. The shaft body 54 is transported to the upper portion of the hole 53 of the cylindrical body 52 by the moving mechanism while being held by the upper electrode 64, and is positioned, held, and fixed.

軸体54の圧入接合の際には、上記プレス機構は電極片63を介して軸体54を押圧し、移動機構の上下移動機能により上部電極64は降下可能である。圧入接合の工程は上記工程と同様であり、上部電極と下部電極との間に通電すると、電気抵抗熱により接合部が発熱し、加圧付勢された軸体が筒体内に圧入される。   When the shaft body 54 is press-fitted and joined, the pressing mechanism presses the shaft body 54 via the electrode piece 63, and the upper electrode 64 can be lowered by the vertical movement function of the moving mechanism. The press-fitting process is the same as the above process. When a current is passed between the upper electrode and the lower electrode, the joined part generates heat due to electric resistance heat, and the pressure-biased shaft body is press-fitted into the cylinder.

このように、2個の電極片(3個以上も可能)でワークとしての軸体及び筒体を狭持することで、両者の接触部及びワーク自体の電気抵抗の影響を低減でき、さらに電極片の狭持部の形状をワークの側面部の形状と同一にすることで、両者の接触面積が広く確保できて電気抵抗の低減が図れる。   In this way, by sandwiching the shaft and cylinder as a workpiece with two electrode pieces (3 or more are also possible), the influence of the electrical resistance of the contact portion between them and the workpiece itself can be reduced. By making the shape of the holding portion of the piece the same as the shape of the side surface portion of the workpiece, it is possible to secure a wide contact area between them and reduce the electric resistance.

次に、実施の形態として、ワークとしての上記軸体、プレート、筒体及び軸体に表面処理としてメッキが施されている場合について説明する。一般に、部材を組み立て加工する場合、先ず各パーツ毎にメッキを施し、これらパーツを用いて組立て及び接合等の工程を行うのが作業の省力化が図れ好適である。このため、表面にメッキが施されたワークを用いた場合の、上記圧入接合について説明する。   Next, as an embodiment, the case where the shaft body, the plate, the cylinder body, and the shaft body as a workpiece are plated as a surface treatment will be described. In general, when assembling a member, it is preferable to first perform plating on each part and perform processes such as assembly and joining using these parts in order to save labor. For this reason, the said press-fit joining at the time of using the workpiece | work with which the surface was plated is demonstrated.

上記メッキの種類及びメッキが施された材料としては、溶融亜鉛メッキ鋼板、合金化溶融亜鉛メッキ鋼板、電気亜鉛メッキ鋼板、合金亜鉛メッキ鋼板、その他のメッキ鋼板等があり、このうち合金亜鉛メッキは、過熱しても錆び難く、また塗料が良く馴染むことから特に自動車部品には多く採用されている。他に、上記メッキ等の表面処理として、ニッケルメッキ、ニッケル複合メッキ、銅メッキ、錫メッキ、クロメート処理、及びリン酸処理などがある。   The types of plating and the plated materials include hot dip galvanized steel sheet, alloyed hot dip galvanized steel sheet, electrogalvanized steel sheet, alloy galvanized steel sheet, and other galvanized steel sheets. It is not easily rusted even when overheated, and the paint is well adapted to it. Other surface treatments such as plating include nickel plating, nickel composite plating, copper plating, tin plating, chromate treatment, and phosphoric acid treatment.

ここで、上記実施の形態に係る圧入接合では、形態的に発熱箇所である接合部と電極の取付け箇所とが異なっているため、また電極と軸体、プレート等のワークとの接触部分の面積を大きく設定できることから、電極とワークとの接触部分の発熱が少なくまた固相接合から接合部の温度も一般のプロジェクション溶接に比べて低い。このため、電極と当接するメッキ材とが高熱によって合金化学反応を起こすことがなく、電極の劣化、圧潰等が防止され電極の耐久性に優れ、またワークの表面のメッキ処理の損傷、破損も殆どない。これに対して、一般のプロジェクション溶接では、重ね合わせた板材同士の接合部の両表面部に電極が配置され、かつこの電極の近くの上記接合部が抵抗発熱により溶融するため、この高熱の影響で板材の表面部が高温にさらされて電極とメッキ材が合金化学反応を起こし、電極の耐久性が低下する。   Here, in the press-fit joining according to the above-described embodiment, since the joining portion, which is a heat generation place, is different from the attachment location of the electrode, the area of the contact portion between the electrode and the workpiece such as the shaft body, plate, etc. Can be set large, heat generation at the contact portion between the electrode and the workpiece is small, and the temperature from the solid phase bonding to the bonding portion is lower than that of general projection welding. For this reason, the plating material in contact with the electrode does not cause an alloy chemical reaction due to high heat, the electrode is prevented from being deteriorated and crushed, and the durability of the electrode is excellent. Almost no. On the other hand, in general projection welding, electrodes are arranged on both surface portions of the joint portion between the overlapped plate materials, and the joint portion near the electrode melts due to resistance heat generation. Thus, the surface portion of the plate material is exposed to a high temperature, causing an alloy chemical reaction between the electrode and the plating material, and the durability of the electrode is lowered.

また上記圧入接合においては、プレート及び軸体等の鋼材にメッキを施してない裸材を用いた場合と、合金化溶融亜鉛メッキ等のメッキを施した表面加工材を用いた場合とを比べると、電流量、或いは接合強度等について両者に差が生じない。これは、接合する部材の各面部同士を接合する一般のプロジェクション溶接に対して、上記圧入接合では、孔の部分に部材を圧入接合する構造上、メッキ処理による電気抵抗の影響を受ける要素がないためである。   Further, in the above press-fit joining, when using a bare material that is not plated on a steel material such as a plate and a shaft body, and a case using a surface-treated material plated with alloying hot dip galvanizing or the like, There is no difference between the current amount or the bonding strength. This is because, with respect to general projection welding in which the respective surface portions of the members to be joined are joined together, in the above press-fit joining, there is no element that is affected by the electrical resistance due to the plating process due to the structure in which the members are press-fit into the hole portions. Because.

このように、一般のプロジェクション溶接(スポット溶接)は部材の表面部同士を接触させ、この部位を発熱溶融させて溶接することからメッキの影響を受け易い一方、上記圧入接合構造は、圧入により接合部の表面はしごかれて表面の不純物質層が削り取られた状態で接合されるため、例え軸体及びプレートの孔の内部にメッキが施されていても、圧入のしごきの際にメッキが削り取られ、メッキによる圧入接合への影響が無視できる。   Thus, in general projection welding (spot welding), the surface portions of members are brought into contact with each other, and this portion is heated and melted to be easily welded. On the other hand, the press-fit joint structure is joined by press-fitting. Since the surface of the part is squeezed and joined in a state in which the impurity layer on the surface is scraped off, even if the inside of the hole of the shaft body and the plate is plated, the plating is scraped off during the press fitting The influence on the press-fit joint by plating can be ignored.

また、プロジェクション溶接においては、ナゲット等の溶融金属或いはメッキが要因となってスパッターが発生し易いが、上記圧入接合は固相接合の為部材の溶融がなく、このためスパッターが非常に発生し易いメッキが施されている場合であってもスパッターは発生しない。さらに、亜鉛メッキ鋼板に対するスポット溶接においては、裸材に比べて大電流を必要とするが、上記固相接合は裸材、メッキ材に係わらず接合時の電流は大差なく、工程管理も容易である。   In projection welding, spatter is likely to occur due to a molten metal such as nugget or plating, but the press-fit joining does not melt the member because of solid phase joining, and therefore spatter is very likely to occur. Sputtering does not occur even when plating is applied. Furthermore, spot welding on galvanized steel sheets requires a larger current than that of bare materials, but the solid-phase joining does not differ greatly regardless of whether it is bare or plated, and process management is easy. is there.

上記圧入接合方法は、自動車の要素部品等の製造に用いることができ、例えばトランスミッションのコントロールレバーコンポーネント、シフトレバーコンポーネント等、プレート部に筒体を接合した形態の部品、或いはエンジン部品等の製造に好適である。   The press-fit joining method can be used for the production of automobile component parts, for example, the production of parts such as transmission control lever components, shift lever components, etc., in which a cylinder is joined to a plate part, or engine parts. Is preferred.

従って上記実施の形態に係る圧入接合によれば、2個又は複数の電極片により所定の押圧力で軸体を狭持し通電することから、電極と軸体との接触部の電気抵抗が低減されるとともに、電極を軸体の側面部に設けたから軸体自体の抵抗の影響が低減されて通電が良好に行えて接合部に好適な電気抵抗熱が確保される。またこの圧入接合では、圧入時には軸体の位置決めが正確に行えかつ安定して保持されるため、接合精度にも優れ、また固相接合により接合部の熱的劣化がなく仕上り精度が良く、加えてスパッターの発生がなく良好な作業環境が得られるという効果がある。   Therefore, according to the press-fit joining according to the above-described embodiment, the shaft body is held and energized with a predetermined pressing force by two or a plurality of electrode pieces, so that the electrical resistance of the contact portion between the electrode and the shaft body is reduced. In addition, since the electrode is provided on the side surface portion of the shaft body, the influence of the resistance of the shaft body itself is reduced, current can be satisfactorily performed, and electrical resistance heat suitable for the joint portion is ensured. Also, in this press-fitting, since the shaft body can be accurately positioned and stably held during press-fitting, the joining accuracy is excellent, and solid-phase joining does not cause thermal deterioration of the joined portion, resulting in good finishing accuracy. Thus, there is an effect that a good working environment can be obtained without generation of spatter.

さらに、接合界面が清浄化されて接合が良好に行われて強度的にも優れ、加えて固相接合としたことから、部材(母材)に与える熱影響範囲が少ないことから、高精度な接合が確保され仕上り精度が良く、後加工が殆ど不要なものとなる等の効果がある。圧入と通電のみの簡単な工程で、しかも迅速に接合が行えて製造が容易に行えて製造コストが安価で経済性に優れる。   Furthermore, since the bonding interface is cleaned and the bonding is performed well, the strength is excellent, and in addition, since the solid-phase bonding is used, the heat influence range on the member (base material) is small, so the high accuracy Bonding is ensured, finishing accuracy is good, and post-processing is almost unnecessary. It is a simple process with only press-fitting and energization, and it can be joined quickly and manufactured easily, with a low manufacturing cost and excellent economy.

本発明の実施の形態に係る圧入接合を示す図である。It is a figure which shows the press fit joining which concerns on embodiment of this invention. 実施の形態に係る軸体と電極片の狭持部との関係を示す図である。It is a figure which shows the relationship between the shaft body which concerns on embodiment, and the clamping part of an electrode piece. 電極片の種々の狭持部の形状(a)(b)(c)(d)を示す図である。It is a figure which shows the shape (a) (b) (c) (d) of the various clamping parts of an electrode piece. 電極として3個の電極片を有する形態を示す図である。It is a figure which shows the form which has three electrode pieces as an electrode. 軸体と電極片の形態に係り、(a)は軸体の側面部が断面楕円形の形態を、(b)は断面が筒状の楕円形の形態を、(c)は軸体の側面部が略四角形の形態を、(d)は軸体の側面部が断面小判状の形態を示す図である。It relates to the form of the shaft body and the electrode piece. (A) shows the shape of the elliptical shape of the side surface of the shaft body, (b) shows the shape of the elliptical shape of the cylindrical section, and (c) shows the side surface of the shaft body. (D) is a figure which shows the side surface part of a shaft body in the shape of a cross-sectional oval shape. 軸体と電極片の形態に係り、(a)は電極片の狭持部の形状がV字状の形態を、(b)は電極片の狭持部に複数の突起が設けられた形態を示す図である。In relation to the shape of the shaft body and the electrode piece, (a) shows a shape in which the holding part of the electrode piece is V-shaped, and (b) shows a form in which a plurality of protrusions are provided on the holding part of the electrode piece. FIG. 実施の形態に係り、(a)は他の形態の電極を有する圧入接合を示す図、(b)は3個の電極片を有する電極を示す図である。(A) is a figure which shows the press-fit joining which has an electrode of another form, and (b) is a figure which shows the electrode which has three electrode pieces concerning embodiment. 実施の形態に係り、締め付け具を用いて位置決めする圧入接合の機構を示す図である。It is a figure which shows the mechanism of the press injection joining which concerns on embodiment and positions using a clamp. 実施の形態に係り、更に他の形態の電極を有する圧入接合の機構を示す図である。It is a figure which shows the mechanism of the press-fit joining which concerns on embodiment and has an electrode of another form. 実施の形態に係り、長尺の軸体の圧入に好適な電極を有する圧入接合の形態を示す図である。It is a figure which shows the form of the press-fit joining which concerns on embodiment and has an electrode suitable for press-fit of a long shaft body. 実施の形態に係り、プレートの位置決めに好適な電極を有する圧入接合の形態を示す図である。It is a figure which shows the form of the press injection joining which concerns on embodiment and has an electrode suitable for positioning of a plate. 本発明の他の実施の形態に係る圧入接合を示す図である。It is a figure which shows the press-fit joining which concerns on other embodiment of this invention. 従来例に係る圧入接合を示す図である。It is a figure which shows the press-fit joining which concerns on a prior art example.

符号の説明Explanation of symbols

2,52 第一の部材(プレート、筒体)
3,53 孔部
4,54 第二の部材(軸体)
6,58 第一の電極(下部電極)
8,64 第二の電極(上部電極)
9,59,62,63 電極片
10 第三の電極(押圧電極)
15 穴部
46 押圧部
71 押圧電極部
72,73 支持電極部
84 位置決部材
2,52 First member (plate, cylinder)
3,53 hole 4,54 second member (shaft)
6,58 First electrode (lower electrode)
8,64 Second electrode (upper electrode)
9, 59, 62, 63 Electrode piece 10 Third electrode (pressing electrode)
15 hole portion 46 pressing portion 71 pressing electrode portion 72, 73 supporting electrode portion 84 positioning member

Claims (13)

圧入部分の断面が同一の内壁面部が形成された孔部を有する第一の部材と、
上記孔部との間に所定の圧入代が設けられ、軸方向に向かう接合面部が形成される軸状の第二の部材とを用い、
上記第一の部材を第一の電極の表面部に配置する一方、上記第二の部材の側面部を複数の電極片からなる第二の電極で機械的に挟持し、
上記第一の部材の孔部内に向けて上記狭持された第二の部材を所定の圧力で押圧するとともに、これら両部材間に通電して両者の接合部に電気抵抗熱を発生させ、上記第二の部材を上記孔部に圧入し、上記第二の部材の接合面部と上記孔部の内壁面部との接合部に接合界面を形成させ、かつこの接合を固相状態の接合としたことを特徴とする圧入接合方法。
A first member having a hole in which an inner wall surface portion having the same cross-section of the press-fit portion is formed;
A predetermined press-fitting allowance is provided between the hole and the shaft-shaped second member in which a joint surface portion directed in the axial direction is formed.
While the first member is disposed on the surface portion of the first electrode, the side surface portion of the second member is mechanically sandwiched by the second electrode composed of a plurality of electrode pieces,
While pressing the sandwiched second member toward the inside of the hole of the first member with a predetermined pressure, energizing between the two members to generate electrical resistance heat at the joint, The second member is press-fitted into the hole, a bonding interface is formed at the bonding portion between the bonding surface of the second member and the inner wall surface of the hole, and the bonding is a solid-phase bonding. A press-fit joining method characterized by
上記第一の電極の表面部に、上記第一の部材の孔部と連通しこの孔部よりも大きな口径の穴部を設けたことを特徴とする請求項1記載の圧入接合方法。   2. The press-fitting method according to claim 1, wherein a hole having a diameter larger than that of the hole is provided on the surface of the first electrode so as to communicate with the hole of the first member. 上記第一の電極の穴部内に上下移動可能な絶縁性の位置決部材を配置し、この位置決部材に上記第一の部材の孔部を係合させて位置決めすることを特徴とする請求項2記載の圧入接合方法。   An insulating positioning member capable of moving up and down is disposed in the hole of the first electrode, and the positioning member is positioned by engaging the hole of the first member with the positioning member. 2. The press-fit joining method according to 2. 圧入部分の断面が同一の内壁面部が形成された孔部を有する筒状の第一の部材と、
上記孔部との間に所定の圧入代が設けられ、軸方向に向かう接合面部が形成される軸状の第二の部材とを用い、
上記第一の部材の側面部を複数の電極片からなる第一の電極で機械的に挟持する一方、上記第二の部材の側面部を複数の電極片からなる第二の電極で機械的に挟持し、
上記第一の部材の孔部内に向けて上記狭持された第二の部材を所定の圧力で押圧するとともに、これら両部材間に通電して両者の接合部に電気抵抗熱を発生させ、上記第二の部材を上記孔部に圧入し、上記第二の部材の接合面部と上記孔部の内壁面部との接合部に接合界面を形成させ、かつこの接合を固相状態の接合としたことを特徴とする圧入接合方法。
A cylindrical first member having a hole in which an inner wall surface portion having the same cross-section of the press-fit portion is formed;
A predetermined press-fitting allowance is provided between the hole and the shaft-shaped second member in which a joint surface portion directed in the axial direction is formed.
The side surface portion of the first member is mechanically clamped by a first electrode made of a plurality of electrode pieces, while the side surface portion of the second member is mechanically held by a second electrode made of a plurality of electrode pieces. Pinching,
While pressing the sandwiched second member toward the inside of the hole of the first member with a predetermined pressure, energizing between the two members to generate electrical resistance heat at the joint, The second member is press-fitted into the hole, a bonding interface is formed at the bonding portion between the bonding surface of the second member and the inner wall surface of the hole, and the bonding is a solid-phase bonding. A press-fit joining method characterized by
上記第二の電極における電極片の狭持部の形状を、上記第二の部材の側面部の形状と同一に形成し、狭持したときにこの第二の部材の側面部に上記電極片の狭持部の全体又は一部が当接するようにしたことを特徴とする請求項1乃至4の何れかに記載の圧入接合方法。   The shape of the sandwiching portion of the electrode piece in the second electrode is formed to be the same as the shape of the side surface portion of the second member, and when sandwiched, the electrode piece is placed on the side surface portion of the second member. The press-fit joining method according to any one of claims 1 to 4, wherein the whole or a part of the holding portion is in contact. 上記第二の部材を狭持した状態で上記第二の電極を移動可能に、かつこの第二の部材を所定位置に位置決め保持できるように構成したことを特徴とする請求項1乃至5の何れかに記載の圧入接合方法。   6. The device according to claim 1, wherein the second electrode can be moved in a state where the second member is held, and the second member can be positioned and held at a predetermined position. The press-fit joining method according to the above. 上記第二の電極の電極片に、上記第二の部材の端面部を軸方向に押圧可能な押圧部を設けたことを特徴とする請求項1乃至6の何れかに記載の圧入接合方法。   The press-fitting method according to any one of claims 1 to 6, wherein a pressing portion capable of pressing an end surface portion of the second member in an axial direction is provided on the electrode piece of the second electrode. 上記第二の電極の電極片の数を2個又は3個とし、かつ上記第二の部材の軸方向の端面部に上記第二の電極の一部である第三の電極を設けたことを特徴とする請求項1乃至6の何れかに記載の圧入接合方法。   The number of electrode pieces of the second electrode is two or three, and a third electrode that is a part of the second electrode is provided on the axial end surface of the second member. The press-fit joining method according to any one of claims 1 to 6. 上記第二の電極の電極片の上方に押圧電極部を設け、この押圧電極部と上記各電極片との間に所定の間隔を維持しかつ上記電極片に電流を供給するための支持電極部を設け、上記第二の部材の上部を上記押圧電極部で押圧可能に保持する一方、上記電極片によりこの第二の部材の下部近傍を狭持することを特徴とする請求項1乃至6の何れかに記載の圧入接合方法。   A supporting electrode portion for providing a pressing electrode portion above the electrode piece of the second electrode, maintaining a predetermined interval between the pressing electrode portion and each electrode piece, and supplying a current to the electrode piece The upper part of said 2nd member is hold | maintained so that it can press with the said press electrode part, On the other hand, the lower part vicinity of this 2nd member is clamped by the said electrode piece. The press-fit joining method according to any one of the above. 上記押圧電極部と上記第二の部材の上部との間を電気的に遮断したことを特徴とする請求項9記載の圧入接合方法。   The press-fit joining method according to claim 9, wherein the press electrode part and the upper part of the second member are electrically cut off. 上記第一の部材又は上記第二の部材の表面にメッキが施されていることを特徴とする請求項1乃至10の何れかに記載の圧入接合方法。   The press-fit joining method according to any one of claims 1 to 10, wherein the surface of the first member or the second member is plated. 上記メッキとして、溶融亜鉛メッキ、合金化溶融亜鉛メッキ、電気亜鉛メッキ又は合金亜鉛メッキを施したことを特徴とする請求項11記載の圧入接合方法。   12. The press-fit joining method according to claim 11, wherein the plating is performed by hot dip galvanization, alloyed hot dip galvanization, electrogalvanization or alloy galvanization. 請求項1乃至請求項12の何れかに記載の圧入接合方法により製造され、上記第一の部材の孔部に上記第二の部材が接合されたことを特徴とする圧入接合部品。   A press-fit joining component manufactured by the press-fit joining method according to any one of claims 1 to 12, wherein the second member is joined to a hole of the first member.
JP2005110290A 2005-04-06 2005-04-06 Press-fit joining method and press-fit joined parts Expired - Fee Related JP4694873B2 (en)

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WO2012026205A1 (en) * 2010-08-24 2012-03-01 株式会社オーハシテクニカ Joining method for joining parts with high fatigue strength
JP2013535335A (en) * 2010-06-30 2013-09-12 ゼネラル・エレクトリック・カンパニイ Solid phase resistance welding to repair and fabricate airfoils
KR20140053784A (en) * 2012-10-26 2014-05-08 엔지케이 인슐레이터 엘티디 Member for semiconductor manufacturing apparatus and method for manufacturing the same
JP2017070987A (en) * 2015-10-08 2017-04-13 マツダ株式会社 Joining device for metal member
JP2017135173A (en) * 2016-01-25 2017-08-03 武延 本郷 Manufacturing method of coil-like member and manufacturing apparatus for coil-like member
JP2018199165A (en) * 2018-09-26 2018-12-20 マツダ株式会社 Joining device and joining method of metal member
JP2021020246A (en) * 2019-07-30 2021-02-18 トヨタ自動車株式会社 Resistance welding device
US11161196B2 (en) 2016-08-26 2021-11-02 Mazda Motor Corporation Metallic member bonding device for pressing rod-shaped or cylindrical first metallic member into hole portion of annular second metallic member to bond the same and bonding method therefor
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JP2013535335A (en) * 2010-06-30 2013-09-12 ゼネラル・エレクトリック・カンパニイ Solid phase resistance welding to repair and fabricate airfoils
WO2012026205A1 (en) * 2010-08-24 2012-03-01 株式会社オーハシテクニカ Joining method for joining parts with high fatigue strength
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KR20140053784A (en) * 2012-10-26 2014-05-08 엔지케이 인슐레이터 엘티디 Member for semiconductor manufacturing apparatus and method for manufacturing the same
KR102043916B1 (en) * 2012-10-26 2019-11-13 엔지케이 인슐레이터 엘티디 Member for semiconductor manufacturing apparatus and method for manufacturing the same
JP2017070987A (en) * 2015-10-08 2017-04-13 マツダ株式会社 Joining device for metal member
JP2017135173A (en) * 2016-01-25 2017-08-03 武延 本郷 Manufacturing method of coil-like member and manufacturing apparatus for coil-like member
US11161196B2 (en) 2016-08-26 2021-11-02 Mazda Motor Corporation Metallic member bonding device for pressing rod-shaped or cylindrical first metallic member into hole portion of annular second metallic member to bond the same and bonding method therefor
JP2018199165A (en) * 2018-09-26 2018-12-20 マツダ株式会社 Joining device and joining method of metal member
JP2021020246A (en) * 2019-07-30 2021-02-18 トヨタ自動車株式会社 Resistance welding device
JP7111076B2 (en) 2019-07-30 2022-08-02 トヨタ自動車株式会社 resistance welding equipment
CN118544097A (en) * 2024-08-01 2024-08-27 佛山市元粒宝智能电器科技有限公司 Shell assembly production line of air purification and adjustment equipment

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