JP2005313184A - Shaft member with flange - Google Patents

Shaft member with flange Download PDF

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JP2005313184A
JP2005313184A JP2004131529A JP2004131529A JP2005313184A JP 2005313184 A JP2005313184 A JP 2005313184A JP 2004131529 A JP2004131529 A JP 2004131529A JP 2004131529 A JP2004131529 A JP 2004131529A JP 2005313184 A JP2005313184 A JP 2005313184A
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flange
hole
shaft member
shaft
flange member
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JP3933645B2 (en
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Yoshihaya Imamura
美速 今村
Seiichi Hashimoto
成一 橋本
Satoshi Futamura
敏 二村
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Kobe Steel Ltd
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Kobe Steel Ltd
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Priority to JP2004131529A priority Critical patent/JP3933645B2/en
Priority to US11/115,353 priority patent/US7658421B2/en
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Publication of JP3933645B2 publication Critical patent/JP3933645B2/en
Priority to US12/650,146 priority patent/US7980615B2/en
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Abstract

<P>PROBLEM TO BE SOLVED: To prevent the relative rotation around a shaft between a flange member and a shaft member in a flanged shaft member which is manufactured by fitting the shaft member into a hole formed on a plate-like flange member, projecting an end part from the hole, enlarging the diameter of the shaft member by electromagnetic forming in the state and joining the flange member and the shaft member. <P>SOLUTION: The shaft member 23 is in close contact with the inner peripheral surface of the hole 28 by enlarging its diameter by the electromagnetic forming and the shaft flange 31 is formed by expanding the projected part to the front side of the hole 28 of the flange member 22, a bulged part 32 is formed by bulging the rear side and the flange member 22 is held between the shaft flange 31 and the bulged part 32. The flange member 22 consists of an extruded material of an aluminum alloy and projected lines 27 are formed on the front surface. The projected lines 27 are in the caulked by being held from both right and left sides with the shaft flange 31. In this way, the relative rotation between both is prevented even if such force as to rotate the flange member 22 around the shaft to the axis X of the shaft member 23a acts. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

本発明は、前面に相手方部材の被取付面に当接する取付面を有し、中央部に穴が形成された板状のフランジ部材と、前記穴に嵌挿され、電磁成形により拡径されて前記穴の内周面に密着し、前記フランジ部材に接合された管状の軸部材からなるフランジ付き軸部材に関する。   The present invention has a plate-like flange member having a mounting surface abutting on a mounting surface of a mating member on the front surface, a hole formed in the center portion, and being inserted into the hole and expanded in diameter by electromagnetic forming. The present invention relates to a flanged shaft member comprising a tubular shaft member that is in close contact with the inner peripheral surface of the hole and joined to the flange member.

管状の軸部材の端部に相手方部材への取付用フランジが形成されたフランジ付き軸部材、例えばバンパーステイ(縦圧壊型)は、軸部材の端部に板状のフランジ部材を溶接接合して製造される。しかし、バンパーステイの溶接部近傍は最も応力が集中する箇所であり、最も高い強度(継ぎ手強度)が必要とされるが、アルミニウム合金の場合、溶接による熱影響により溶接部近傍が軟化し、必然的に継ぎ手強度が低下するという問題がある。この継ぎ手強度の低下を補うため、軸部材及びフランジ部材の肉厚を大きくしたり、熱処理型アルミニウム合金であれば、熱処理(人工時効処理)を行って硬度及び強度を回復させることが考えられるが、前者の場合、アルミニウム合金を使用した軽量化の効果が半減し、後者の場合、溶接後の熱処理による強度の回復には限界があり、また、溶接後に熱処理工程を付加することによるコストアップが避けられない。   A flanged shaft member, for example, a bumper stay (vertical crushing type) in which a flange for attachment to a counterpart member is formed at the end of a tubular shaft member, a plate-like flange member is welded to the end of the shaft member. Manufactured. However, the vicinity of the welded part of the bumper stay is the place where the stress is concentrated most, and the highest strength (joint strength) is required. There is a problem that joint strength is lowered. In order to compensate for this decrease in joint strength, it is conceivable to increase the thickness of the shaft member and flange member, or to recover the hardness and strength by heat treatment (artificial aging treatment) if heat treated aluminum alloy is used. In the former case, the effect of weight reduction using an aluminum alloy is halved. In the latter case, there is a limit to the recovery of strength by heat treatment after welding, and there is an increase in cost by adding a heat treatment step after welding. Unavoidable.

一方、下記特許文献1には、管状の軸部材の周囲を金型で包囲し、金型の端面から前記軸部材の先端部を突出させ、該先端部を電磁成形により瞬間的に拡開して前記金型の端面に打ち付け、軸部材の端部に前記金型の端面に沿った形状のフランジを一体成形することが開示されている。この手段によれば、溶接の熱影響による軟化がなく、むしろ加工硬化により継ぎ手強度が向上するという利点がある。しかし、特に軸部材の径に比べて大径のフランジを形成しようとすれば、アルミニウム合金の種類によってはフランジに割れが入ったり、ボルト締結等に利用されるフランジ周縁部が拡径に伴って薄肉化するという問題が起こり得る。
なお、電磁成形とは、電気エネルギーの投入により、電磁成形用コイルがきわめて短時間の強力な磁場を形成し、この磁場内におかれたワーク(被加工物)が磁場の反発力(フレミングの左手の法則に従ったLorentz力)によって強い拡張力や収縮力を受けて、高速で塑性変形することを利用し、ワークを所定形状に成形する技術であり、下記特許文献2〜5及び非特許文献1等にも記載されているように、それ自体公知技術である。
On the other hand, in Patent Document 1 below, the periphery of a tubular shaft member is surrounded by a mold, the tip end portion of the shaft member is protruded from the end surface of the mold, and the tip end portion is instantaneously expanded by electromagnetic molding. It is disclosed that the end face of the mold is struck and a flange having a shape along the end face of the mold is integrally formed at the end of the shaft member. According to this means, there is an advantage that there is no softening due to the heat effect of welding, but rather the joint strength is improved by work hardening. However, especially when trying to form a flange with a larger diameter than the diameter of the shaft member, the flange is cracked depending on the type of aluminum alloy, and the flange peripheral part used for bolt fastening etc. The problem of thinning can occur.
Electromagnetic forming means that by applying electric energy, the electromagnetic forming coil forms a strong magnetic field for a very short time, and the workpiece (workpiece) placed in this magnetic field repels the magnetic field. This is a technology for forming a workpiece into a predetermined shape using a plastic deformation at a high speed by receiving a strong expansion force or contraction force by a Lorentz force according to the left hand rule). As described in Document 1, etc., it is a known technique per se.

特開2004−42066号公報JP 2004-42066 A 特開昭58−4601号公報Japanese Patent Laid-Open No. 58-4601 特開平6−312226号公報JP-A-6-31226 特開平9−166111号公報JP 9-166111 A 特開2002−86228号公報JP 2002-86228 A 機械技術研究所報告第150号「電磁力を利用する塑性加工の研究」(1990年3月、機械技術研究所発行)Mechanical Technology Research Institute Report No. 150 “Research on Plastic Working Using Electromagnetic Force” (March 1990, published by Mechanical Technology Research Institute)

ところで、前記特許文献4,5には、軸部材を他部材に形成した穴に貫通させ、軸部材を電磁成形により拡径して、他部材と接合する技術が開示されている。この技術を応用すれば、軸部材の先端にフランジ部材が接合したフランジ付き軸部材を製造することが可能である。
例えば、図17,18に示すように、中央に板厚方向に貫通する円形の穴2を形成した板状のフランジ部材1を、図示しない手段により位置決めし、この穴2に仮想線で示す円形断面の素材管3を嵌挿し、かつ素材管3の端部(突出部3a)を前方に突出させ、この状態で図示しない手段により位置決めする。続いて、素材管3の内部に電磁成形用コイル4を装入して、電磁成形を行う。これにより、フランジ部材1の面内では素材管3は拡径して穴2の内周面に密着し、フランジ部材1の前方側では突出部3aが放射方向に拡開して、その背面が穴2の周囲のフランジ面(前面)に当接密着し、フランジ部材1の後方側では素材管3は磁場の反発力による拡張力の大きさに応じて膨出し、素材管3は端部に軸フランジ6とその後方側に張出部7を有する軸部材5となり、フランジ部材1と軸部材5が接合されたフランジ付き軸部材8(図16参照)が成形される。なお、フランジ付き軸部材8の製造にあたり、この例では、電磁成形により素材管3を全長にわたって拡径するのではなく、フランジ部材1の近傍のみを拡径している。従って、図17に示すように、軸部材5にはフランジ部材1の前方側に軸フランジ6と、フランジ部材1の後方側に張出部7が形成されているが、軸部材5の張出部7より後方側の部分は管素材のままの径を保っている。
By the way, the patent documents 4 and 5 disclose a technique in which a shaft member is passed through a hole formed in another member, the shaft member is expanded in diameter by electromagnetic forming, and joined to the other member. If this technique is applied, it is possible to manufacture a flanged shaft member in which a flange member is joined to the tip of the shaft member.
For example, as shown in FIGS. 17 and 18, a plate-like flange member 1 in which a circular hole 2 penetrating in the thickness direction is formed at the center is positioned by means not shown, and a circular shape indicated by a virtual line in this hole 2. The material tube 3 having a cross section is inserted and the end portion (projecting portion 3a) of the material tube 3 is projected forward, and in this state, positioning is performed by means not shown. Subsequently, the electromagnetic forming coil 4 is inserted into the material tube 3 to perform electromagnetic forming. As a result, the diameter of the material tube 3 is increased in the plane of the flange member 1 and is in close contact with the inner peripheral surface of the hole 2, and the protruding portion 3 a is expanded in the radial direction on the front side of the flange member 1. The material pipe 3 bulges in accordance with the magnitude of the expansion force due to the repulsive force of the magnetic field on the rear side of the flange member 1 and is in close contact with the flange surface (front surface) around the hole 2. A shaft member 5 having a shaft flange 6 and a projecting portion 7 on the rear side thereof is formed, and a flanged shaft member 8 (see FIG. 16) in which the flange member 1 and the shaft member 5 are joined is formed. In manufacturing the shaft member 8 with the flange, in this example, the diameter of the material pipe 3 is not expanded over the entire length by electromagnetic forming, but only the vicinity of the flange member 1 is expanded. Therefore, as shown in FIG. 17, the shaft member 5 is formed with a shaft flange 6 on the front side of the flange member 1 and a projecting portion 7 on the rear side of the flange member 1. The portion on the rear side from the portion 7 maintains the diameter of the tube material.

このフランジ付き軸部材8において、軸部材5が穴2の内周面に密着し、かつフランジ部材1は軸フランジ6と内側の張出部7の間に強固に挟まれている。このフランジ付き軸部材8において、フランジ部材1の外側部11が相手方部材(例えばバンパーリインフォース)の被取付面に当接する取付面となる。
なお、以上説明した例では、素材管3の周囲に金型を配置せず、張出部7の成形は自由拡管するにまかせたが、必要に応じて、図17に仮想線で示すように、素材管3の周囲を金型9で取り囲み、フランジ部材1と素材管3の位置決めを行うと同時に、張出部7の形状を規制することもできる。
In this flanged shaft member 8, the shaft member 5 is in close contact with the inner peripheral surface of the hole 2, and the flange member 1 is firmly sandwiched between the shaft flange 6 and the overhanging portion 7 on the inside. In the flanged shaft member 8, the outer portion 11 of the flange member 1 serves as a mounting surface that abuts against a mounted surface of a counterpart member (for example, bumper reinforcement).
In the example described above, the mold is not disposed around the material tube 3 and the overhanging portion 7 is formed by freely expanding the tube. However, if necessary, as shown by a virtual line in FIG. The periphery of the material pipe 3 is surrounded by a mold 9 so that the flange member 1 and the material pipe 3 can be positioned, and at the same time, the shape of the protruding portion 7 can be restricted.

図17に示す方法によれば、任意の大きさの取付面を有するフランジ部材1と素材管3を使用して、フランジ付き軸部材8を電磁成形により成形でき、一方、電磁成形された軸フランジ6の外径は、フランジ部材1と軸部材5との接合を確保するに必要な最小限の大きさで済むため、前記特許文献1の方法において生じ得るフランジの割れや肉厚の減少といった問題は抑えられる。また、素材管3としてアルミニウム合金押出材を用い、さらにフランジ部材1として、アルミニウム合金押出材を用いることができる(押出方向に垂直な面で切断し、穴開けすればよい)ため、低コストで実施できる。   According to the method shown in FIG. 17, the flanged shaft member 8 can be formed by electromagnetic forming using the flange member 1 and the material pipe 3 having an attachment surface of an arbitrary size, while the electromagnetically formed shaft flange Since the outer diameter of 6 is a minimum size necessary to ensure the joining between the flange member 1 and the shaft member 5, there is a problem such as cracking of the flange or reduction in thickness that can occur in the method of Patent Document 1. Is suppressed. Moreover, since an aluminum alloy extruded material can be used as the material tube 3 and an aluminum alloy extruded material can be used as the flange member 1 (simply cut and cut in a plane perpendicular to the extrusion direction), the cost can be reduced. Can be implemented.

一方、図16に示すフランジ付き軸部材8において、フランジ部材1の穴2の内周面に軸部材5が密着し、かつ軸フランジ6と張出部7が前後からフランジ部材1を挟み付けているが、フランジ部材1と軸部材5は軸回りに互いに噛み合う部分がないため、例えば軸部材5が他の部材に固定された状態でフランジ部材1に強い回転力が加わった場合、フランジ部材1が軸部材5の中心(穴2の中心でもある)を通る軸Xに対して軸回りにゆるみを生じて回るおそれがある。
フランジ部材1と軸部材5の間にこのようなゆるみや相対的な回転が生じると、穴2の内周面と軸部材5が摺動し、その接触部でいずれか一方又は双方の部材の摩耗が起こり、ゆるみが促進されていく。これによりフランジ部材1を介して取り付けられる相手方部材をも含めた全体構造(例えばバンパーリインフォースとステイからなるバンパー構造体)の剛性が損なわれるととともに振動を起こす原因になるなど、部材使用上の問題点が生じ得る。
On the other hand, in the flanged shaft member 8 shown in FIG. 16, the shaft member 5 is in close contact with the inner peripheral surface of the hole 2 of the flange member 1, and the shaft flange 6 and the overhanging portion 7 sandwich the flange member 1 from the front and rear. However, since the flange member 1 and the shaft member 5 do not have a portion that meshes with each other around the axis, for example, when a strong rotational force is applied to the flange member 1 with the shaft member 5 fixed to another member, the flange member 1 However, there is a risk that the shaft will loosen around the axis X passing through the center of the shaft member 5 (which is also the center of the hole 2).
When such loosening or relative rotation occurs between the flange member 1 and the shaft member 5, the inner peripheral surface of the hole 2 and the shaft member 5 slide, and either one or both of the members are contacted at the contact portion. Wear occurs and loosening is promoted. Due to this, the rigidity of the entire structure including the counterpart member attached via the flange member 1 (for example, a bumper structure composed of bumper reinforcement and stay) is impaired and causes vibrations. Points can occur.

本発明は、このような問題点に鑑みてなされたもので、軸部材を板状のフランジ部材に形成した穴に嵌挿し、端部を穴から突出させ、その状態で軸部材を電磁成形により拡径し、フランジ部材と軸部材を接合させて製造したフランジ付き軸部材において、フランジ部材と軸部材の相対的な軸回りの回転を防止することを目的とする。   The present invention has been made in view of such problems. The shaft member is inserted into a hole formed in the plate-like flange member, the end portion is protruded from the hole, and the shaft member is electromagnetically molded in that state. An object of the present invention is to prevent relative rotation of the flange member and the shaft member around the axis in the flanged shaft member manufactured by expanding the diameter and joining the flange member and the shaft member.

本発明に係るフランジ付き軸部材は、前面に相手方部材の被取付面に当接する取付面を有し、中央部に穴が形成された板状のフランジ部材と、前記穴に嵌挿され、かつ電磁成形により拡径されて前記穴の内周面に密着し、前記フランジ部材に接合された管状の軸部材からなり、前記軸部材はアルミニウム合金からなり、前記穴から前方側に突出した部分が放射方向外向きに拡開して軸フランジを形成し、その背面が前記フランジ部材の穴の周囲に当接し、前記穴の後方側が放射方向外側に膨出して張出部が形成され、前記軸フランジと張出部の間に前記フランジ部材が挟まれ、前記穴の形状が前記軸部材の軸方向にみたとき円形であり、前記フランジ部材の前面の形状が少なくとも前記穴の周囲の前記軸フランジが当接する領域において前記軸部材の軸に対し軸対称でないことを特徴とする。ここで、軸部材の軸とは、該軸部材の長さ方向に平行で前記穴の中心を通る直線である。
なお、本発明において、板状部材の穴の位置からみて軸フランジの側を前方、反対側を後方とし、前方を向いた面を前面、後方を向いた面を背面とする。
The flanged shaft member according to the present invention has a plate-like flange member having a mounting surface that abuts the mounted surface of the mating member on the front surface, a hole formed in the center, and is inserted into the hole, and It is expanded by electromagnetic forming and is in close contact with the inner peripheral surface of the hole, and is composed of a tubular shaft member joined to the flange member, the shaft member is made of an aluminum alloy, and a portion protruding forward from the hole is A shaft flange is formed by expanding outward in the radial direction, a back surface thereof abuts around a hole of the flange member, a rear side of the hole bulges outward in the radial direction, and an overhang portion is formed. The flange member is sandwiched between a flange and an overhang portion, and the shape of the hole is circular when viewed in the axial direction of the shaft member, and the shape of the front surface of the flange member is at least the shaft flange around the hole In the region where the Wherein the to the axis of the member is not axially symmetrical. Here, the axis of the shaft member is a straight line that passes through the center of the hole in parallel with the length direction of the shaft member.
In addition, in this invention, seeing from the position of the hole of a plate-shaped member, let the shaft flange side be the front, the opposite side is the back, the surface facing the front is the front, and the surface facing the back is the back.

上記発明において、フランジ部材の前面の形状(特に穴の周囲の軸フランジが当接する領域)が軸部材の軸に対し軸対称でないということは、フランジ部材の前面の幾何学的な形状が、軸回りに変化していることを意味する。このような前面形状を有するフランジ部材を用いることにより、電磁成形後の軸フランジとフランジ部材の前面側が互いに掛止し合い、フランジ部材と軸部材の相対的な回転が防止される。これに対し、前記領域においてフランジ部材の前面の形状が軸部材の軸に対して軸対称である場合、軸フランジとフランジ部材の前面側に互いに掛止し合う箇所がなく、強い回転力が掛かったときフランジ部材と軸部材の相対的な回転は防止されない。例えば図16のフランジ付き軸部材8では、穴2が形成されたフランジ部材1の内側部12の前面は軸部材5の軸Xに垂直な平面であり、該内側部12において穴2の周囲の軸フランジ6が当接する領域に着目した場合、当該領域においてフランジ部材の前面の形状は軸Xに対して軸対称ということができる。   In the above invention, the fact that the shape of the front surface of the flange member (particularly the region where the shaft flange around the hole contacts) is not axisymmetric with respect to the axis of the shaft member means that the geometric shape of the front surface of the flange member is It means that it is changing around. By using the flange member having such a front shape, the shaft flange after electromagnetic forming and the front side of the flange member are engaged with each other, and relative rotation of the flange member and the shaft member is prevented. On the other hand, when the shape of the front surface of the flange member is axisymmetric with respect to the axis of the shaft member in the region, there is no place where the shaft flange and the front surface of the flange member are engaged with each other, and a strong rotational force is applied. In this case, the relative rotation of the flange member and the shaft member is not prevented. For example, in the flanged shaft member 8 of FIG. 16, the front surface of the inner portion 12 of the flange member 1 in which the hole 2 is formed is a plane perpendicular to the axis X of the shaft member 5. When attention is paid to the region where the shaft flange 6 abuts, it can be said that the shape of the front surface of the flange member in this region is axisymmetric with respect to the axis X.

また、本発明に係るフランジ付き軸部材は、前面に相手方部材の被取付面に当接する取付面を有し、中央部に穴が形成された板状のフランジ部材と、前記穴に嵌挿され、かつ電磁成形により拡径されて前記穴の内周面に密着し、前記フランジ部材に接合された管状の軸部材からなり、前記軸部材はアルミニウム合金からなり、前記穴から前方側に突出した部分が放射方向外向きに拡開して軸フランジを形成し、その背面が前記フランジ部材の穴の周囲に当接し、前記穴の後方側が放射方向外側に膨出して張出部が形成され、前記軸フランジと張出部の間に前記フランジ部材が挟まれ、前記穴の形状が前記軸部材の軸方向にみたとき非円形であることを特徴とする。
このような形状の穴を有するフランジ部材を用いることにより、電磁成形後の軸部材とフランジ部材の穴の内周面が互いに掛止し合い、フランジ部材と軸部材の相対的な回転が防止される。これに対し、図16のフランジ付き軸部材8では、穴2の形状が軸部材5の軸方向にみたとき円形であるため、軸部材5と穴2の内周面は互いに掛止し合うことはない。
Further, the flanged shaft member according to the present invention has a plate-like flange member having a mounting surface abutting on the mounting surface of the mating member on the front surface and having a hole formed in the center, and is fitted into the hole. And a tubular shaft member that is expanded by electromagnetic forming and is in close contact with the inner peripheral surface of the hole, and is joined to the flange member. The shaft member is made of an aluminum alloy and protrudes forward from the hole. The portion is expanded radially outward to form a shaft flange, the back surface of which is in contact with the periphery of the hole of the flange member, the rear side of the hole bulges radially outward to form an overhang, The flange member is sandwiched between the shaft flange and an overhang portion, and the shape of the hole is non-circular when viewed in the axial direction of the shaft member.
By using the flange member having such a hole shape, the shaft member after electromagnetic forming and the inner peripheral surface of the hole of the flange member are engaged with each other, and relative rotation of the flange member and the shaft member is prevented. The In contrast, in the flanged shaft member 8 of FIG. 16, the shape of the hole 2 is circular when viewed in the axial direction of the shaft member 5, and therefore the shaft member 5 and the inner peripheral surface of the hole 2 are engaged with each other. There is no.

また、本発明に係るフランジ付き軸部材は、前面に相手方部材の被取付面に当接する取付面を有し、中央部に穴が形成された板状のフランジ部材と、前記穴に嵌挿され、かつ電磁成形により拡径されて前記穴の内周面に密着し、前記フランジ部材に接合された管状の軸部材からなり、前記軸部材はアルミニウム合金からなり、前記穴から前方側に突出した部分が放射方向外向きに拡開して軸フランジを形成し、その背面が前記フランジ部材の穴の周囲に当接し、前記穴の後方側が放射方向外側に膨出して張出部が形成され、前記軸フランジと張出部の間に前記フランジ部材が挟まれ、前記穴が前記軸部材の軸方向にみたとき円形であり、前記フランジ部材の背面の形状が少なくとも前記穴の周縁部において前記軸部材の軸に対し軸対称ではないことを特徴とする。
このような背面形状を有するフランジ部材を用いることにより、電磁成形後の張出部とフランジ部材の背面側が互いに掛止し合い、フランジ部材と軸部材の相対的な回転が防止される。これに対し、前記穴の周縁部においてフランジ部材の背面の形状が軸部材の軸に対して軸対称である場合、張出部とフランジ部材の背面側に互いに掛止し合う箇所がなく、強い回転力が掛かったときフランジ部材と軸部材の相対的な回転は防止されない。例えば図16のフランジ付き軸部材8では、穴2が形成されたフランジ部材1の内側部12の背面は軸部材5の軸Xに垂直な平面であり、穴2の周縁部においてフランジ部材の背面の形状は軸Xに対して軸対称ということができる。
Further, the flanged shaft member according to the present invention has a plate-like flange member having a mounting surface abutting on the mounting surface of the mating member on the front surface and having a hole formed in the center, and is fitted into the hole. And a tubular shaft member that is expanded by electromagnetic forming and is in close contact with the inner peripheral surface of the hole, and is joined to the flange member. The shaft member is made of an aluminum alloy and protrudes forward from the hole. The portion is expanded radially outward to form a shaft flange, the back surface of which is in contact with the periphery of the hole of the flange member, the rear side of the hole bulges radially outward to form an overhang, The flange member is sandwiched between the shaft flange and the overhang portion, and the hole is circular when viewed in the axial direction of the shaft member, and the shape of the back surface of the flange member is at least at the periphery of the hole. Not axisymmetric with respect to the axis of the member It is characterized in.
By using the flange member having such a back surface shape, the overhang portion after electromagnetic forming and the back surface side of the flange member are engaged with each other, and relative rotation of the flange member and the shaft member is prevented. On the other hand, when the shape of the back surface of the flange member is axisymmetric with respect to the axis of the shaft member at the peripheral edge portion of the hole, there is no place where the overhanging portion and the back surface side of the flange member are engaged with each other, which is strong. When a rotational force is applied, the relative rotation of the flange member and the shaft member is not prevented. For example, in the flanged shaft member 8 of FIG. 16, the back surface of the inner portion 12 of the flange member 1 in which the hole 2 is formed is a plane perpendicular to the axis X of the shaft member 5. This shape can be said to be axially symmetric with respect to the axis X.

本発明によれば、任意の大きさのフランジ部材を使用して、フランジ部材と軸部材が接合されたフランジ付き軸部材を電磁成形により成形でき、かつ、前記特許文献1の方法において生じ得るフランジの割れや肉厚の減少といった問題が生じない。また、フランジ部材と軸部材をともにアルミニウム合金押出材で形成することもでき、低コストで軽量なフランジ付き軸部材を得ることができる。
そして、フランジ部材の前面側又は背面側あるいは穴の内周面のいずれかの形状を、先に述べた特定の形状とすることにより、電磁成形後のフランジ部材と軸部材が互いに掛止し合い、両者の相対的な回転を防止することができる。
According to the present invention, a flange member having an arbitrary size can be formed by electromagnetic forming of a flanged shaft member in which the flange member and the shaft member are joined, and the flange that can be generated in the method of Patent Document 1 above. There is no problem of cracking or thickness reduction. Further, both the flange member and the shaft member can be formed of an aluminum alloy extruded material, so that a low-cost and lightweight flanged shaft member can be obtained.
Then, the flange member and the shaft member after electromagnetic forming are latched to each other by making the shape of either the front side or the back side of the flange member or the inner peripheral surface of the hole the specific shape described above. The relative rotation of the two can be prevented.

以下、図1〜図15を参照して、本発明に係るフランジ付き軸部材について具体的に説明する。
図1〜図6は、フランジ部材の前面の形状(特に穴の周囲の軸フランジが当接する領域)が軸部材の軸に対し軸対称でないタイプのフランジ付き軸部材を示す。
図1に示すフランジ付き軸部材21は、板状のフランジ部材22と、該フランジ部材22が端部に接合された管状の軸部材23からなる。フランジ部材22はアルミニウム合金押出材からなり、図4に示すように、該押出材を押出方向に垂直な面内で所定長さに切断したもので(切断線を仮想線で示す)、左右の外側部24と内側部25及び両者を接続する傾斜した左右の段差部26からなる。外側部24と内側部25は互いに平行な板であり、外側部24の前面は内側部25の前面より前方側に位置し、外側部24の前面が図示しない相手方部材の被取付面(平面)に当接する取付面となっている。軸部材23は内側部25に対して垂直に接合している。
Hereinafter, with reference to FIGS. 1-15, the shaft member with a flange which concerns on this invention is demonstrated concretely.
1 to 6 show a shaft member with a flange of a type in which the shape of the front surface of the flange member (particularly, the region where the shaft flange around the hole abuts) is not axisymmetric with respect to the shaft of the shaft member.
A flanged shaft member 21 shown in FIG. 1 includes a plate-like flange member 22 and a tubular shaft member 23 in which the flange member 22 is joined to an end portion. The flange member 22 is made of an aluminum alloy extruded material, and as shown in FIG. 4, the extruded material is cut to a predetermined length in a plane perpendicular to the extrusion direction (the cutting line is indicated by a virtual line). It comprises an outer part 24, an inner part 25, and left and right stepped parts 26 that connect the two. The outer portion 24 and the inner portion 25 are plates parallel to each other, the front surface of the outer portion 24 is located on the front side of the front surface of the inner portion 25, and the front surface of the outer portion 24 is a surface to be attached (planar) of a mating member (not shown). It is a mounting surface that comes into contact with. The shaft member 23 is joined perpendicularly to the inner portion 25.

フランジ部材22は全体としてほぼ均一な厚さの板状部材であるが、内側部24の前面側中央部に断面矩形状の突条27が形成され、ここでは厚肉となっている。また、フランジ部材22は、内側部25の中央部に円形の穴28が形成され、該穴28はその周方向の一部が前記突条27を通って板厚方向に貫通している。従って、穴28の内周面の高さは突条27の箇所において高く、その他の箇所において低くなっている。
軸部材23は円形断面のアルミニウム合金押出材からなり、素材管は押出方向に垂直な面内で所定長さに切断されている。
なお、フランジ部材22の材質としては、強度が高く導電率が低いものが望ましく、JIS5000系や、JIS6000,7000系のT5調質材が好適である。また、軸部材の材質は、成形しやすく導電率が高いものが望ましく、例えば6063等のJIS6000系が好適である。軸部材としては、アルミニウム合金押出材が好適であるが、例えばアルミニウム合金板を曲げ加工したものを用いることもできる。
The flange member 22 is a plate-like member having a substantially uniform thickness as a whole, but a protrusion 27 having a rectangular cross section is formed at the front side central portion of the inner portion 24, and is thick here. Further, the flange member 22 has a circular hole 28 formed at the center of the inner portion 25, and a part of the hole 28 in the circumferential direction passes through the protrusion 27 in the plate thickness direction. Therefore, the height of the inner peripheral surface of the hole 28 is high at the location of the ridge 27 and is low at other locations.
The shaft member 23 is made of an aluminum alloy extruded material having a circular cross section, and the material pipe is cut to a predetermined length in a plane perpendicular to the extrusion direction.
The flange member 22 is preferably made of a material having high strength and low electrical conductivity, and a JIS 5000 series or JIS 6000,7000 series T5 tempered material is suitable. Further, the material of the shaft member is preferably a material that is easy to mold and has high electrical conductivity, and for example, JIS6000 series such as 6063 is suitable. As the shaft member, an aluminum alloy extruded material is suitable. For example, a bent aluminum alloy plate can also be used.

フランジ付き軸部材21の製造にあたっては、図2,3に示すように、フランジ部材22の穴28に素材管29を嵌挿し、その前端部を穴28から前方側に突出させた状態とし、図示しない手段によりフランジ部材22及び素材管29を位置決めする。
続いて、図17において説明したと同じ要領で、素材管29の内部に図示しない電磁成形用コイルを装入して、電磁成形を行う。これにより、図1〜図3に示すように、穴28の内側では、素材管29は拡径して穴28の内周面に密着し、穴22から前方側に突出していた突出部29aが放射方向外向きに拡開して軸フランジ31を形成し、その背面31aが穴28の周囲の内側部25の前面(突条27の前面を含む)に打ち当たって密着当接し、さらに、穴28の後方側では、素材管29は磁場の反発力による拡張力の大きさに応じて半径方向外側に膨出し張出部32が形成される。
In manufacturing the shaft member 21 with flange, as shown in FIGS. 2 and 3, the material pipe 29 is fitted into the hole 28 of the flange member 22, and the front end portion thereof is projected forward from the hole 28. The flange member 22 and the material pipe 29 are positioned by means that does not.
Subsequently, in the same manner as described with reference to FIG. 17, an electromagnetic forming coil (not shown) is inserted into the material tube 29 to perform electromagnetic forming. As a result, as shown in FIGS. 1 to 3, inside the hole 28, the material tube 29 is expanded in diameter and is in close contact with the inner peripheral surface of the hole 28, and a protruding portion 29 a that protrudes forward from the hole 22 is formed. The shaft flange 31 is formed by expanding outward in the radial direction, and the back surface 31a abuts against the front surface of the inner portion 25 around the hole 28 (including the front surface of the protrusion 27) and comes into close contact with the hole. On the rear side of 28, the material tube 29 bulges outwardly in the radial direction in accordance with the magnitude of the expansion force due to the repulsive force of the magnetic field, and an overhang portion 32 is formed.

このフランジ付き軸部材21では、穴28の内周面に拡径した軸部材23(成形後のものを軸部材23という)が密着し、フランジ部材22が穴28の周囲において前後から軸フランジ31と張出部32により挟まれ、さらに突条27が軸フランジ31により左右両側から挟まれてカシメ止めされた形になっている。突条27と軸フランジ31が互いに噛み合っているため、仮にフランジ部材22を軸部材23の軸Xに対して軸回りに回転させようとする力が作用しても、両者の相対的な回転は防止される。
フランジ部材22の前面の形状について、特に穴28の周囲の軸フランジ31が当接する領域に着目すると、該領域におけるフランジ部材22の前面は、突条27の部分を除いて軸部材23の軸Xに垂直な1つの平面内にあるが、突条27があることにより前記軸Xに対し軸対称な形状ではなく、さらに軸対称でないことにより軸フランジ31とフランジ部材22(突条27)の噛み合いが生じている。なお、このフランジ部材22は押出材であるため、突条27は穴28の周囲の軸フランジ31が当接する領域外にも存在するが、当然そこでは軸フランジ31とフランジ部材22(突条27)の噛み合いがなく、従って、当該領域外に突条27が存在するかしないかは、本発明の課題を達成するうえで問題にならない。
フランジ部材22において、前面に突条27の代わりに凹溝を形成しても、同様の作用を得ることができる。
In this flanged shaft member 21, the shaft member 23 (the molded member is referred to as the shaft member 23) whose diameter has been expanded is in close contact with the inner peripheral surface of the hole 28, and the flange member 22 is shaft flange 31 from the front and rear around the hole 28. Further, the protrusion 27 is sandwiched from the left and right sides by the shaft flange 31 and is crimped. Since the protrusion 27 and the shaft flange 31 are engaged with each other, even if a force is applied to rotate the flange member 22 about the axis X with respect to the shaft X of the shaft member 23, the relative rotation of the two is not caused. Is prevented.
With regard to the shape of the front surface of the flange member 22, particularly focusing on the region where the shaft flange 31 around the hole 28 abuts, the front surface of the flange member 22 in this region is the axis X of the shaft member 23 except for the protrusion 27. However, since the protrusion 27 is present, the shape of the shaft flange 31 and the flange member 22 (protrusion 27) is not symmetrical. Has occurred. Since the flange member 22 is an extruded material, the protrusion 27 exists outside the region where the shaft flange 31 around the hole 28 abuts, but naturally the shaft flange 31 and the flange member 22 (the protrusion 27). Therefore, whether or not the protrusion 27 exists outside the region does not matter in achieving the object of the present invention.
In the flange member 22, even if a concave groove is formed on the front surface instead of the protrusion 27, the same effect can be obtained.

図5に示すフランジ付き軸部材41は、板状のフランジ部材42と、該フランジ部材42が端部に接合された管状の軸部材43からなる。フランジ部材42はアルミニウム合金押出材からなり、該押出材を押出方向に垂直な面内で所定長さに切断したもので、左右の外側部44と内側部45及び両者を接続する傾斜した左右の段差部46からなり、内側部45に板厚方向に円形の穴48が形成されている。ちょうど図4に示すフランジ部材22において突条27をなくして内側部25の前面を完全な平面にした形状と考えればよく、全体がほぼ均一な厚さの板状部材である。同じく外側部44の前面が図示しない他部材の被取付面に当接する取付面となっている。軸部材43は内側部45に対して垂直に接合している。
軸部材43はアルミニウム合金押出材からなり、図6に示すように、素材管49は押出方向に垂直な面内で所定長さに切断されている。
A flanged shaft member 41 shown in FIG. 5 includes a plate-like flange member 42 and a tubular shaft member 43 in which the flange member 42 is joined to an end portion. The flange member 42 is made of an aluminum alloy extruded material, and the extruded material is cut to a predetermined length in a plane perpendicular to the extrusion direction. A circular hole 48 is formed in the inner portion 45 in the thickness direction. It can be considered that the flange member 22 shown in FIG. 4 has a shape in which the protrusions 27 are eliminated and the front surface of the inner portion 25 is made a complete plane, and the whole is a plate-like member having a substantially uniform thickness. Similarly, the front surface of the outer portion 44 is a mounting surface that comes into contact with a mounting surface of another member (not shown). The shaft member 43 is joined perpendicularly to the inner portion 45.
The shaft member 43 is made of an aluminum alloy extruded material. As shown in FIG. 6, the material tube 49 is cut to a predetermined length in a plane perpendicular to the extrusion direction.

フランジ付き軸部材41の製造は、フランジ付き軸部材21の製造と同様の要領で行われる。フランジ付き軸部材41は、図5,6に示すように、穴48の内側では、素材管49は拡径して穴48の内周面に密着し、穴48から前方側に突出していた突出部49aが放射方向外向きに拡開して軸フランジ51を形成し、その背面が穴48の周囲において内側部24の前面及び一部が傾斜した段差部46に打ち当たって密着当接し、さらに、穴48の後方側では、素材管49は磁場の反発力による拡張力の大きさに応じて半径方向外側に膨出し張出部52が形成される。   The flanged shaft member 41 is manufactured in the same manner as the flanged shaft member 21 is manufactured. As shown in FIGS. 5 and 6, the flanged shaft member 41 protrudes from the hole 48 to the front side by expanding the diameter of the material tube 49 in close contact with the inner peripheral surface of the hole 48 inside the hole 48. The portion 49a expands outward in the radial direction to form the shaft flange 51, and the rear surface of the portion 49a hits the front surface of the inner portion 24 and a stepped portion 46 that is inclined at the periphery of the hole 48, On the rear side of the hole 48, the material tube 49 bulges outward in the radial direction according to the magnitude of the expansion force due to the repulsive force of the magnetic field, and the overhanging portion 52 is formed.

このフランジ付き軸部材41では、穴48の内周面に拡径した軸部材43(成形後のものを軸部材43という)が密着し、フランジ部材42が穴28の周囲において前後から軸フランジ51と張出部52により挟まれている。そして、軸フランジ51がフランジ部材42の内側部45及び傾斜した段差部46にまたがって当接している。軸フランジ51の段差部46に当接した部分と該段差部46とが、フランジ部材42と軸部材43の相対的な回転に関して互いに掛止し合った形になるため、仮にフランジ部材42を軸部材43の軸Xに対して軸回りに回転させようとする力が作用しても、両者の相対的な回転は防止される。
フランジ部材42の前面の形状について、特に穴48の周囲の軸フランジ51が当接する領域に着目すると、内側部45の前面は軸部材43の軸Xに垂直な平面であるが、段差部46が前記領域に含まれることから、前記領域におけるフランジ部材42の前面形状は軸部材43の軸Xに対し軸対称ではなく、さらに軸対称でないことにより軸フランジ51とフランジ部材42(段差部46)の噛み合いが生じている。
In this flanged shaft member 41, the shaft member 43 (the molded member is referred to as the shaft member 43) whose diameter has been expanded is in close contact with the inner peripheral surface of the hole 48, and the flange member 42 has a shaft flange 51 from the front and rear around the hole 28. And the overhanging portion 52. The shaft flange 51 is in contact with the inner portion 45 of the flange member 42 and the inclined stepped portion 46. Since the portion of the shaft flange 51 that is in contact with the stepped portion 46 and the stepped portion 46 are engaged with each other with respect to the relative rotation of the flange member 42 and the shaft member 43, the flange member 42 is temporarily connected to the shaft. Even if a force to rotate around the axis X of the member 43 acts, relative rotation of both is prevented.
As for the shape of the front surface of the flange member 42, particularly focusing on the region where the shaft flange 51 around the hole 48 abuts, the front surface of the inner portion 45 is a plane perpendicular to the axis X of the shaft member 43. Since it is included in the region, the front shape of the flange member 42 in the region is not axially symmetric with respect to the axis X of the shaft member 43, and further is not axially symmetric, so that the shaft flange 51 and the flange member 42 (stepped portion 46). Engagement has occurred.

図7,8は、フランジ部材に形成した穴の形状が軸部材の軸方向にみたとき非円形となっているタイプのフランジ付き軸部材の具体的な形態を示す。
図7に示すフランジ付き軸部材61は、板状のフランジ部材62と、該フランジ部材62が端部に接合された管状の軸部材63からなる。フランジ部材62は、図8に示すように、フランジ部材42と同じ断面のアルミニウム合金押出材を、押出方向に垂直な面内で所定長さに切断したもので、左右の外側部64と内側部65及び両者を接続する傾斜した左右の段差部66からなり、全体がほぼ均一な厚さの板状部材であり、外側部64の前面が図示しない他部材の被取付面に当接する取付面となっている。内側部65に板厚方向に開けられた穴68は、円形の周の一部が半径方向外側に円弧状に張り出した形状(張出部68a)を有する。軸部材63は内側部65に対して垂直に接合している。
7 and 8 show a specific form of a shaft member with a flange of a type in which the shape of the hole formed in the flange member is non-circular when viewed in the axial direction of the shaft member.
A flanged shaft member 61 shown in FIG. 7 includes a plate-shaped flange member 62 and a tubular shaft member 63 in which the flange member 62 is joined to an end portion. As shown in FIG. 8, the flange member 62 is obtained by cutting an aluminum alloy extruded material having the same cross section as the flange member 42 into a predetermined length in a plane perpendicular to the extrusion direction. 65 and an inclined left and right stepped portion 66 that connects both, and is a plate-like member having a substantially uniform thickness as a whole, and a mounting surface in which the front surface of the outer portion 64 abuts against a mounting surface of another member (not shown) It has become. The hole 68 formed in the inner portion 65 in the plate thickness direction has a shape (a protruding portion 68a) in which a part of a circular circumference protrudes in an arc shape outward in the radial direction. The shaft member 63 is joined perpendicularly to the inner portion 65.

フランジ付き軸部材61は、フランジ付き軸部材21と同じ要領で製造される。フランジ付き軸部材61は、フランジ付き軸部材21と同様に、穴68の内周面(張出部68aの内周面を含む)に拡径した軸部材63が密着し、フランジ部材62が穴68の周囲において前後から軸フランジ71と張出部72により挟まれている。そして、軸部材62の一部が穴68の張出部68a内に膨出し、これにより当該部分においてフランジ部材62と軸部材63が互いに掛止し合った形になっているため、仮にフランジ部材42を軸部材43の軸Xに対して軸回りに回転させようとする力が作用しても、両者の相対的な回転は防止される。
なお、非円形な穴の形状として、上記穴68のように円形の周の一部が半径方向外側に張り出した形状だけでなく、円形の周の一部が半径方向内側に張り出した形状の穴、円形の周の一部が直線になった穴(例えばレーストラックに似た形状)、全体が楕円形の穴など、種々のものが考えられる。
The flanged shaft member 61 is manufactured in the same manner as the flanged shaft member 21. As with the flanged shaft member 21, the flanged shaft member 61 is in close contact with the shaft member 63 whose diameter is increased on the inner peripheral surface of the hole 68 (including the inner peripheral surface of the overhanging portion 68 a), and the flange member 62 is the hole. 68 is sandwiched between the shaft flange 71 and the overhanging portion 72 from the front and rear around the periphery of 68. Then, a part of the shaft member 62 bulges into the overhanging portion 68a of the hole 68, so that the flange member 62 and the shaft member 63 are hooked to each other at that portion. Even if a force is applied to rotate the shaft 42 about the axis X of the shaft member 43, relative rotation of both is prevented.
In addition, as a shape of the non-circular hole, not only a shape in which a part of the circular circumference projects outward in the radial direction like the hole 68, but also a hole in a shape in which a part of the circular circumference projects inward in the radial direction. Various types of holes such as a hole (for example, a shape resembling a racetrack) in which a part of a circular circumference is a straight line and a hole having an overall oval shape are conceivable.

図9,10は、フランジ部材の背面の形状(特に穴の周縁部)が軸部材の軸に対し軸対称でないタイプのフランジ付き軸部材を示す。
図9に示すフランジ付き軸部材81は、板状のフランジ部材82と、該フランジ部材82が端部に接合された管状の軸部材83からなる。フランジ部材82はアルミニウム合金押出材からなり、該押出材を押出方向に垂直な面内で所定長さに切断したもので、図10に示すように、左右の外側部84と内側部85及び両者を接続する傾斜した左右の段差部86からなり、外側部84の前面が図示しない他部材の被取付面に当接する取付面となっている。内側部85の背面側中央部に断面矩形状の突条87が形成され、ここでは厚肉となり、また、内側部85には中央部に円形の穴88が形成され、該穴88はその周方向の一部が前記突条87を通って板厚方向に貫通している。このフランジ部材82は、ちょうど図4に示すフランジ部材22において前面に形成された突条27をなくして、その代わりに背面に突条87を形成した形状と考えてよい。軸部材83はアルミニウム合金押出材からなり、内側部85に対して垂直に接合している。
9 and 10 show a shaft member with a flange of a type in which the shape of the back surface of the flange member (particularly the peripheral edge of the hole) is not axially symmetric with respect to the shaft of the shaft member.
A flanged shaft member 81 shown in FIG. 9 includes a plate-like flange member 82 and a tubular shaft member 83 in which the flange member 82 is joined to an end portion. The flange member 82 is made of an aluminum alloy extruded material, and the extruded material is cut into a predetermined length in a plane perpendicular to the extrusion direction. As shown in FIG. 10, the left and right outer portions 84 and inner portions 85 and both The front surface of the outer portion 84 is a mounting surface that comes into contact with a mounting surface of another member (not shown). A protrusion 87 having a rectangular cross section is formed in the central portion on the back side of the inner portion 85, and is thick here, and a circular hole 88 is formed in the central portion in the inner portion 85. Part of the direction passes through the protrusion 87 in the plate thickness direction. This flange member 82 may be considered to have a shape in which the protrusion 27 formed on the front surface in the flange member 22 shown in FIG. 4 is eliminated and a protrusion 87 is formed on the rear surface instead. The shaft member 83 is made of an aluminum alloy extruded material, and is joined perpendicularly to the inner portion 85.

フランジ付き軸部材81は、フランジ付き軸部材21と同じ要領で製造される。フランジ付き軸部材81は、フランジ付き軸部材21と同様に、穴88の内周面に拡径した軸部材83が密着し、フランジ部材82が穴88の周囲において前後から、図示されていない軸フランジと張出部92により挟まれ、さらに、張出部92は突条87の箇所とその他の箇所では膨出の起点が異なるため(膨出の起点は前者より後者が前方となる)、突条87が張出部92により左右両側から挟まれてカシメ止めされた形になっている。このように突条87と張出部92が互いに噛み合い互いに掛止し合っているため、仮にフランジ部材82を軸部材83の軸Xに対して軸回りに回転させようとする力が作用しても、両者の相対的な回転は防止される。   The flanged shaft member 81 is manufactured in the same manner as the flanged shaft member 21. As with the flanged shaft member 21, the flanged shaft member 81 is in close contact with the shaft member 83 having an enlarged diameter on the inner peripheral surface of the hole 88, and the flange member 82 is a shaft (not shown) from the front and rear around the hole 88. Since the protruding portion 92 is sandwiched between the flange and the protruding portion 92, and the protruding point of the protruding portion 92 is different from that of the other portion of the protruding portion 87 (the latter is more forward than the former). The strip 87 is sandwiched from the left and right sides by the overhanging portion 92 and is crimped. As described above, since the protrusion 87 and the overhanging portion 92 are engaged with each other and are engaged with each other, a force is applied to rotate the flange member 82 about the axis X of the shaft member 83. However, the relative rotation of the two is prevented.

フランジ部材82の背面の形状について、特に穴88の周縁部に着目すると、外周縁部におけるフランジ部材82の背面形状は、突条87の部分を除いて軸部材83の軸Xに垂直な1つの平面内にあるが、突条87があることにより軸部材83の軸Xに対し軸対称ではなく、さらに軸対称でないことにより張出部92とフランジ部材82(突条87)の噛み合いが生じている。なお、このフランジ部材82は押出材であるため、突条87は穴88の周縁部外にも存在するが、当然そこでは張出部92とフランジ部材82(突条87)の噛み合いがなく、従って、当該周縁部外に突条87が存在するかしないかは、本発明の課題を達成するうえで問題にならない。
フランジ部材82において、背面に突条87の代わりに凹溝を形成しても、同様の作用を得ることができる。
With regard to the shape of the back surface of the flange member 82, particularly focusing on the peripheral edge portion of the hole 88, the back surface shape of the flange member 82 at the outer peripheral edge portion is one perpendicular to the axis X of the shaft member 83 except for the protrusion 87 portion. Although it is in the plane, the protrusion 87 is not axially symmetric with respect to the axis X of the shaft member 83, and further, the protrusion 92 and the flange member 82 (protrusion 87) are engaged with each other because it is not axially symmetric. Yes. In addition, since this flange member 82 is an extrusion material, the protrusion 87 exists also outside the peripheral part of the hole 88, but naturally there is no meshing of the overhang part 92 and the flange member 82 (projection 87), Therefore, whether or not the protrusion 87 exists outside the peripheral edge does not matter in achieving the object of the present invention.
In the flange member 82, even if a concave groove is formed on the back surface instead of the protrusion 87, the same effect can be obtained.

図11〜図15は、フランジ部材の前面の形状(特に穴の周囲の軸フランジが当接する領域)が軸部材の軸に対し軸対称でなく、かつフランジ部材の背面の形状(特に穴の周縁部)が軸部材の軸に対し軸対称でないタイプのフランジ付き軸部材を示す。
図11に示すフランジ付き軸部材101は、板状のフランジ部材102と、該フランジ部材102が端部に接合された管状の軸部材103からなる。フランジ部材102はアルミニウム合金押出材からなり、該押出材を押出方向に垂直な面内で所定長さに切断したもので、図13に示すように、左右の外側部104と内側部105及び両者を接続する傾斜した左右の段差部106からなり、外側部104の前面が図示しない他部材の被取付面に当接する取付面となっている。フランジ部材102は全体としてほぼ均一な肉厚であるが、内側部105の中央部に前方側に台形状に突出する突条107(背面側からみると凹溝109)が形成され、また、内側部105には中央部に円形の穴108が形成され、該穴108はその周方向の一部が前記突条107を通って板厚方向に貫通している。この例では、突条107の前面の高さは、外側部104の前面の高さと等しく設定されている。軸部材103はアルミニウム合金押出材からなり、内側部105に対して垂直に接合している。
11 to 15 show that the shape of the front surface of the flange member (particularly the region where the shaft flange around the hole abuts) is not axisymmetric with respect to the axis of the shaft member, and the shape of the rear surface of the flange member (particularly the periphery of the hole). (Part) shows the shaft member with a flange of the type which is not axisymmetric with respect to the axis | shaft of a shaft member.
A flanged shaft member 101 shown in FIG. 11 includes a plate-like flange member 102 and a tubular shaft member 103 in which the flange member 102 is joined to an end portion. The flange member 102 is made of an aluminum alloy extruded material, and the extruded material is cut into a predetermined length in a plane perpendicular to the extrusion direction. As shown in FIG. 13, the left and right outer portions 104 and inner portions 105 and both The front surface of the outer portion 104 is a mounting surface that comes into contact with a mounting surface of another member (not shown). The flange member 102 has a substantially uniform thickness as a whole, but a protrusion 107 (a concave groove 109 when viewed from the back side) is formed in the center portion of the inner portion 105 and protrudes in a trapezoidal shape on the front side. A circular hole 108 is formed in the center part of the part 105, and a part of the hole 108 penetrates in the plate thickness direction through the protrusion 107. In this example, the height of the front surface of the protrusion 107 is set equal to the height of the front surface of the outer portion 104. The shaft member 103 is made of an aluminum alloy extruded material, and is joined perpendicularly to the inner portion 105.

フランジ付き軸部材101は、フランジ付き軸部材21と同じ要領で製造される。ただし、この例では、図示しない素材管はその前端が突条107の前面と一致するように位置決めされる。フランジ付き軸部材101は、フランジ付き軸部材21と同様に、穴108の内周面に拡径した軸部材103が密着し、フランジ部材102が穴108の周囲において前後から軸フランジ111と張出部112により挟まれている。さらに、フランジ部材102の前面側では、突条107が軸フランジ111により左右両側から挟まれてカシメ止めされた形になり、一方、フランジ部材102の背面側では、張出部112は凹溝109の箇所とその他の箇所では膨出の起点が異なるため(膨出の起点は前者が後者より前方となる)、凹溝109内に張出部112が膨出する。このように、フランジ部材102の前面側では突条107と軸フランジ111が互いに噛み合い、背面側では凹溝109と張出部112が互いに噛み合い掛止し合っているため、仮にフランジ部材102を軸部材103の軸Xに対して軸回りに回転させようとする力が作用しても、両者の相対的な回転は防止される。   The flanged shaft member 101 is manufactured in the same manner as the flanged shaft member 21. However, in this example, the material pipe (not shown) is positioned so that the front end thereof coincides with the front surface of the protrusion 107. As with the flanged shaft member 21, the flanged shaft member 101 is in close contact with the shaft member 103 whose diameter has been increased on the inner peripheral surface of the hole 108, and the flange member 102 projects from the front and rear around the hole 108 from the shaft flange 111. It is sandwiched between the portions 112. Further, on the front side of the flange member 102, the protrusion 107 is sandwiched from both the left and right sides by the shaft flange 111 and is crimped. On the other hand, on the back side of the flange member 102, the projecting portion 112 has a concave groove 109. Since the starting point of bulging is different between this part and the other parts (the bulging starting point is the former being ahead of the latter), the overhanging portion 112 bulges in the concave groove 109. In this way, the protrusion 107 and the shaft flange 111 are engaged with each other on the front side of the flange member 102, and the concave groove 109 and the overhanging portion 112 are engaged with each other and locked on the back side. Even if a force to rotate the member 103 about the axis X acts, the relative rotation of both is prevented.

フランジ部材102の前面の形状について、特に穴108の周囲の軸フランジ111が当接する領域に着目すると、該領域におけるフランジ部材102の前面形状は、突条107の部分を除いて軸部材103の軸Xに垂直な1つの平面内にあるが、突条107があることにより軸部材103の軸Xに対し軸対称ではなく、さらに軸対称でないことにより軸フランジ111とフランジ部材102(突条107)の噛み合いが生じている。また、フランジ部材102の背面の形状について、特に穴108の周縁部に着目すると、該周縁部におけるフランジ部材102の背面形状は、凹溝109があることにより軸部材103の軸Xに対し軸対称ではなく、さらに軸対称でないことにより張出部112とフランジ部材102(凹溝109)の噛み合いが生じている。   Focusing on the shape of the front surface of the flange member 102, particularly in the region where the shaft flange 111 around the hole 108 abuts, the front surface shape of the flange member 102 in this region is the axis of the shaft member 103 except for the portion of the protrusion 107. Although it is in one plane perpendicular to X, it is not axially symmetric with respect to the axis X of the shaft member 103 due to the presence of the ridge 107, and is further not symmetric with respect to the axis flange 111 and the flange member 102 (ridge 107). The meshing has occurred. Further, with regard to the shape of the back surface of the flange member 102, particularly focusing on the peripheral portion of the hole 108, the back surface shape of the flange member 102 at the peripheral portion is axisymmetric with respect to the axis X of the shaft member 103 due to the presence of the concave groove 109. However, the overhanging portion 112 and the flange member 102 (concave groove 109) are meshed with each other because they are not axially symmetric.

図14に示すフランジ付き軸部材121は、板状のフランジ部材122と、該フランジ部材122が端部に接合された管状の軸部材123からなる。フランジ部材122はフランジ部材42と同じ断面のアルミニウム合金押出材を、押出方向に垂直な面内で所定長さに切断したもので、左右の外側部124と内側部125及び両者を接続する傾斜した左右の段差部126からなり、外側部124の前面が図示しない他部材の被取付面に当接する取付面となっている。軸部材123は、内側部125に対し傾斜して接合している。
軸部材123は円形断面のアルミニウム合金押出材からなり、図15に示すように、素材管129の前端は押出方向に垂直な面に対して傾斜した面内で切断され、後端は押出方向に垂直な面内で切断されている。
A flanged shaft member 121 shown in FIG. 14 includes a plate-like flange member 122 and a tubular shaft member 123 in which the flange member 122 is joined to an end portion. The flange member 122 is obtained by cutting an aluminum alloy extruded material having the same cross section as the flange member 42 into a predetermined length in a plane perpendicular to the extrusion direction, and is inclined to connect the left and right outer portions 124 and the inner portion 125 and both. It consists of left and right stepped portions 126, and the front surface of the outer portion 124 is a mounting surface that comes into contact with a mounting surface of another member (not shown). The shaft member 123 is joined to the inner portion 125 while being inclined.
The shaft member 123 is made of an aluminum alloy extruded material having a circular cross section. As shown in FIG. 15, the front end of the material tube 129 is cut in a plane inclined with respect to a plane perpendicular to the extrusion direction, and the rear end is in the extrusion direction. Cut in a vertical plane.

フランジ付き軸部材121の製造は、フランジ付き軸部材21の製造とほぼ同様の要領で行われる。ただし、図15に示すように、フランジ部材122は素材管129(又は軸部材123)の軸Xに垂直な面に対し傾斜して位置決めされ、その傾斜は内側部125の前面と突出させた素材管129の前端が平行になるように設定される。また、内側部125に形成された穴128は、前記軸Xの方向からみたときに円形とされている。
フランジ付き軸部材121は、図14,15に示すように、穴128の内側では、素材管129は拡径して穴128の内周面に密着し、穴128から前方側に突出していた突出部128aが放射方向外向きに拡開して軸フランジ131を形成し、穴128の後方側では、素材管129は磁場の反発力による拡張力の大きさに応じて半径方向外側に膨出し張出部132が形成される。
The flanged shaft member 121 is manufactured in substantially the same manner as the flanged shaft member 21 is manufactured. However, as shown in FIG. 15, the flange member 122 is positioned to be inclined with respect to a surface perpendicular to the axis X of the material tube 129 (or the shaft member 123), and the inclination protrudes from the front surface of the inner portion 125. The front end of the tube 129 is set to be parallel. The hole 128 formed in the inner portion 125 is circular when viewed from the direction of the axis X.
As shown in FIGS. 14 and 15, the flanged shaft member 121 protrudes from the hole 128 to the front side by expanding the diameter of the material tube 129 and closely contacting the inner peripheral surface of the hole 128 inside the hole 128. The portion 128a expands outward in the radial direction to form the shaft flange 131. On the rear side of the hole 128, the material tube 129 bulges outward in the radial direction according to the magnitude of the expansion force due to the repulsive force of the magnetic field. A protruding portion 132 is formed.

このフランジ付き軸部材121では、穴128の内周面に拡径した軸部材123(成形後のものを軸部材123という)が密着し、フランジ部材122が穴128の周囲において前後から軸フランジ131と張出部132により挟まれている。そして、軸部材121において、フランジ部材122(内側部125)が軸部材123の軸Xに垂直な面に対して傾斜しているため、フランジ部材122と軸部材123が両者の相対的な回転に関して互いに掛止し合った形になっている。そのため、仮にフランジ部材122を軸部材123の軸Xに対して軸回りに回転させようとする力が作用しても、両者の相対的な回転は防止される。   In this flanged shaft member 121, a shaft member 123 (the molded member is referred to as a shaft member 123) whose diameter has been enlarged is in close contact with the inner peripheral surface of the hole 128, and the flange member 122 is shaft flange 131 from the front and rear around the hole 128. And the overhang portion 132. In the shaft member 121, the flange member 122 (inner portion 125) is inclined with respect to the surface perpendicular to the axis X of the shaft member 123. It is in the form of hanging on each other. For this reason, even if a force is applied to rotate the flange member 122 about the axis X of the shaft member 123, relative rotation between the two is prevented.

フランジ部材122の前面の形状について、特に穴128の周囲の軸フランジ131が当接する領域に着目すると、当該領域は平面であるが該平面が軸部材123の軸Xに対して傾斜しているため、前記前面形状は軸部材123の軸Xに対し軸対称ではなく、さらに軸対称でないことにより、軸フランジ131とフランジ部材122の相互の掛止が生じている。また、フランジ部材122の背面の形状について、特に穴128の周縁部に着目すると、該周縁部は前面側と平行な1つの平面内にあるが、該平面が軸部材123の軸Xに対して傾斜しているため、前記背面形状は軸部材123の軸Xに対し軸対称ではなく、さらに軸対称でないことにより、張出部132とフランジ部材122の相互の掛止が生じている。   Regarding the shape of the front surface of the flange member 122, particularly when attention is paid to a region where the shaft flange 131 around the hole 128 contacts, the region is a plane, but the plane is inclined with respect to the axis X of the shaft member 123. The front face shape is not axially symmetric with respect to the axis X of the shaft member 123 and is not further axially symmetric, so that the shaft flange 131 and the flange member 122 are engaged with each other. Further, with regard to the shape of the back surface of the flange member 122, particularly focusing on the peripheral portion of the hole 128, the peripheral portion is in one plane parallel to the front side, but the plane is relative to the axis X of the shaft member 123. Since it is inclined, the back surface shape is not axially symmetric with respect to the axis X of the shaft member 123 and is not further axially symmetric, so that the protruding portion 132 and the flange member 122 are engaged with each other.

なお、以上の例では、素材管(軸部材)について、円形断面としたが、楕円、多角形等、円形とは異なる回転対称な断面形状にすることもできる。
また、以上の例では、軸部材の一方の端部にのみフランジ部材を接合したが、必要に応じて、両端にフランジ部材を接合することができる。
In the above example, the material pipe (shaft member) has a circular cross section, but may have a cross-sectional shape that is rotationally symmetric, such as an ellipse or a polygon.
In the above example, the flange member is joined only to one end of the shaft member. However, the flange member can be joined to both ends as necessary.

本発明に係るフランジ付き軸部材は、バンパーステイに好適に適用することができる。その場合、必要に応じて、軸部材の両端にバンパーリインフォース用とサイドメンバ用の2つのフランジ部材を接合する。
また、本発明に係るフランジ付き軸部材は、他のフランジ付き軸部材、例えば車両のインストルメントパネル用リインフォース、クロスメンバー、タワーバー、インストルメントパネル用付属パイプ(一端がインストルメントパネル用リインフォースに取り付けられてインストルメントパネルやダクトなどを支持するパイプ)、ピラー、シートフレーム、インテークマニホールド、マフラー、プロペラシャフト、ステアリングコラム、二輪車(自転車を含む)用スイングアームのほか、航空機用のシートフレーム、いす用のフレーム、その他、各種用途の継ぎ手類等、相手方部材に取り付けられるフランジ付き軸部材一般に適用できる。
The shaft member with a flange according to the present invention can be suitably applied to a bumper stay. In that case, if necessary, two flange members for bumper reinforcement and side members are joined to both ends of the shaft member.
Further, the flanged shaft member according to the present invention is another flanged shaft member such as a vehicle instrument panel reinforce, a cross member, a tower bar, an instrument panel accessory pipe (one end is attached to the instrument panel reinforce Pipes that support instrument panels and ducts), pillars, seat frames, intake manifolds, mufflers, propeller shafts, steering columns, swing arms for motorcycles (including bicycles), seat frames for aircraft, and chairs It is applicable to a shaft member with a flange that is attached to a counterpart member, such as a frame, and other joints for various purposes.

本発明に係るフランジ付き軸部材の斜視図である。It is a perspective view of the shaft member with a flange concerning the present invention. 図1のA−A断面図である。It is AA sectional drawing of FIG. 図1のB−B断面図である。It is BB sectional drawing of FIG. 図1に示すフランジ付き軸部材のフランジ部材の斜視図である。It is a perspective view of the flange member of the shaft member with a flange shown in FIG. 本発明に係る他の形態のフランジ付き軸部材の斜視図である。It is a perspective view of the shaft member with a flange of other forms concerning the present invention. 図5のC−C断面図である。It is CC sectional drawing of FIG. 本発明に係る他の形態のフランジ付き軸部材の斜視図である。It is a perspective view of the shaft member with a flange of other forms concerning the present invention. 図7に示すフランジ付き軸部材のフランジ部材の斜視図である。It is a perspective view of the flange member of the shaft member with a flange shown in FIG. 本発明に係る他の形態のフランジ付き軸部材の斜視図(背面側)である。It is a perspective view (back side) of the shaft member with a flange of other forms concerning the present invention. 図7に示すフランジ付き軸部材のフランジ部材の斜視図(背面側)である。It is a perspective view (back side) of the flange member of the shaft member with a flange shown in FIG. 本発明に係る他の形態のフランジ付き軸部材の斜視図である。It is a perspective view of the shaft member with a flange of other forms concerning the present invention. 図11のD−D断面図である。It is DD sectional drawing of FIG. 図11に示すフランジ付き軸部材のフランジ部材の斜視図である。It is a perspective view of the flange member of the shaft member with a flange shown in FIG. 本発明に係る他の形態のフランジ付き軸部材の斜視図である。It is a perspective view of the shaft member with a flange of other forms concerning the present invention. 図14のE−E断面図である。It is EE sectional drawing of FIG. 比較のために示すフランジ付き軸部材の斜視図である。It is a perspective view of the shaft member with a flange shown for a comparison. 図16のF−F断面図である。It is FF sectional drawing of FIG. 図16のフランジ付き軸部材のフランジ部材の斜視図である。It is a perspective view of the flange member of the shaft member with a flange of FIG.

符号の説明Explanation of symbols

21,41,61、81、101,121 フランジ付き軸部材
22,42,62,82,102,122 フランジ部材
23,43,63,83,103,123 軸部材
24,44,64,84,104,124 外側部
25,45,65,85,105,125 内側部
26,46,66,86,106,126 段差部
27,87,107 突条
28,48,68,88,108,128 穴
31,51,71,91,111,131 軸フランジ
32,52,72,92,112,132 張出部
109 凹溝
21, 41, 61, 81, 101, 121 Flange shaft member 22, 42, 62, 82, 102, 122 Flange member 23, 43, 63, 83, 103, 123 Shaft member 24, 44, 64, 84, 104 , 124 Outer portion 25, 45, 65, 85, 105, 125 Inner portion 26, 46, 66, 86, 106, 126 Stepped portion 27, 87, 107 Projection 28, 48, 68, 88, 108, 128 Hole 31 , 51, 71, 91, 111, 131 Shaft flange 32, 52, 72, 92, 112, 132 Overhanging portion 109 Concave groove

Claims (12)

前面に相手方部材の被取付面に当接する取付面を有し、中央部に穴が形成された板状のフランジ部材と、前記穴に嵌挿され、かつ電磁成形により拡径されて前記穴の内周面に密着し、前記フランジ部材に接合された管状の軸部材からなり、前記軸部材はアルミニウム合金からなり、前記穴から前方側に突出した部分が放射方向外向きに拡開して軸フランジを形成し、その背面が前記フランジ部材の穴の周囲に当接し、前記穴の後方側が放射方向外側に膨出して張出部が形成され、前記軸フランジと張出部の間に前記フランジ部材が挟まれ、前記穴の形状が前記軸部材の軸方向にみたとき円形であり、前記フランジ部材の前面の形状が少なくとも前記穴の周囲の前記軸フランジが当接する領域において前記軸部材の軸に対し軸対称でないことを特徴とするフランジ付き軸部材。 A plate-like flange member having a mounting surface abutting on the mounting surface of the counterpart member on the front surface and having a hole formed in the center, and being inserted into the hole and expanded in diameter by electromagnetic forming, It consists of a tubular shaft member that is in close contact with the inner peripheral surface and is joined to the flange member. The shaft member is made of an aluminum alloy, and the portion protruding forward from the hole expands radially outward. A flange is formed, a back surface of the flange member is in contact with the periphery of the hole of the flange member, a rear side of the hole bulges radially outward to form an overhang portion, and the flange is formed between the shaft flange and the overhang portion. When the member is sandwiched and the shape of the hole is circular when viewed in the axial direction of the shaft member, the shape of the front surface of the flange member is at least in the region where the shaft flange around the hole contacts the shaft of the shaft member Is not axially symmetric Flanged shaft member according to symptoms. 前記フランジ部材がアルミニウム合金押出材からなり、その前面側に突条又は凹溝が形成され、前記穴はその周方向の一部が前記突条又は凹溝を通って板厚方向に貫通していることを特徴とする請求項1に記載されたフランジ付き軸部材。 The flange member is made of an aluminum alloy extruded material, and a protrusion or a groove is formed on the front side thereof, and a part of the hole in the circumferential direction passes through the protrusion or the groove and penetrates in the plate thickness direction. The flanged shaft member according to claim 1, wherein the shaft member has a flange. 前記フランジ部材がアルミニウム合金押出材からなり、前記フランジ部材が段差のある外側部と内側部及び両者を接続する段差部からなり、前記穴が前記内側部に形成され、前記軸フランジが前記内側部及び段差部に当接していることを特徴とする請求項1に記載されたフランジ付き軸部材。 The flange member is formed of an aluminum alloy extruded material, the flange member is formed of a stepped outer portion, an inner portion, and a step portion connecting both, the hole is formed in the inner portion, and the shaft flange is formed in the inner portion. The shaft member with a flange according to claim 1, wherein the shaft member is in contact with the step portion. 前記フランジ部材は、その前面が前記穴の周囲の少なくとも前記軸フランジが当接する領域において1つの平面内にあり、該平面が前記軸部材の軸に垂直な面に対して傾斜していることを特徴とする請求項1に記載されたフランジ付き軸部材。 The flange member has a front surface in one plane in a region where the shaft flange abuts at least around the hole, and the plane is inclined with respect to a plane perpendicular to the axis of the shaft member. The shaft member with a flange according to claim 1 characterized by things. 前記フランジ部材がアルミニウム合金押出材からなることを特徴とする請求項4に記載されたフランジ付き軸部材。 The flanged shaft member according to claim 4, wherein the flange member is made of an aluminum alloy extruded material. 前面に相手方部材の被取付面に当接する取付面を有し、中央部に穴が形成された板状のフランジ部材と、前記穴に嵌挿され、かつ電磁成形により拡径されて前記穴の内周面に密着し、前記フランジ部材に接合された管状の軸部材からなり、前記軸部材はアルミニウム合金からなり、前記穴から前方側に突出した部分が放射方向外向きに拡開して軸フランジを形成し、その背面が前記フランジ部材の穴の周囲に当接し、前記穴の後方側が放射方向外側に膨出して張出部が形成され、前記軸フランジと張出部の間に前記フランジ部材が挟まれ、前記穴の形状が前記軸部材の軸方向にみたとき非円形であることを特徴とするフランジ付き軸部材。 A plate-like flange member having a mounting surface abutting on the mounting surface of the counterpart member on the front surface and having a hole formed in the center, and being inserted into the hole and expanded in diameter by electromagnetic forming, It consists of a tubular shaft member that is in close contact with the inner peripheral surface and is joined to the flange member. The shaft member is made of an aluminum alloy, and the portion protruding forward from the hole expands radially outward. A flange is formed, a back surface of the flange member is in contact with the periphery of the hole of the flange member, a rear side of the hole bulges radially outward to form an overhang portion, and the flange is formed between the shaft flange and the overhang portion. A flanged shaft member, wherein a member is sandwiched and the shape of the hole is non-circular when viewed in the axial direction of the shaft member. 前記穴は、円形の周の一部が半径方向外側に張り出した形状を有することを特徴とする請求項6に記載されたフランジ付き軸部材。 The flanged shaft member according to claim 6, wherein the hole has a shape in which a part of a circular circumference projects outward in the radial direction. 前面に相手方部材の被取付面に当接する取付面を有し、中央部に穴が形成された板状のフランジ部材と、前記穴に嵌挿され、かつ電磁成形により拡径されて前記穴の内周面に密着し、前記フランジ部材に接合された管状の軸部材からなり、前記軸部材はアルミニウム合金からなり、前記穴から前方側に突出した部分が放射方向外向きに拡開して軸フランジを形成し、その背面が前記フランジ部材の穴の周囲に当接し、前記穴の後方側が放射方向外側に膨出して張出部が形成され、前記軸フランジと張出部の間に前記フランジ部材が挟まれ、前記穴が前記軸部材の軸方向にみたとき円形であり、前記フランジ部材の背面の形状が少なくとも前記穴の周縁部において前記軸部材の軸に対し軸対称ではないことを特徴とするフランジ付き軸部材。 A plate-like flange member having a mounting surface abutting on the mounting surface of the counterpart member on the front surface and having a hole formed in the center, and being inserted into the hole and expanded in diameter by electromagnetic forming, It consists of a tubular shaft member that is in close contact with the inner peripheral surface and is joined to the flange member. The shaft member is made of an aluminum alloy, and the portion protruding forward from the hole expands radially outward. A flange is formed, a back surface of the flange member is in contact with the periphery of the hole of the flange member, a rear side of the hole bulges radially outward to form an overhang portion, and the flange is formed between the shaft flange and the overhang portion. A member is sandwiched, and the hole is circular when viewed in the axial direction of the shaft member, and the shape of the back surface of the flange member is not axisymmetric with respect to the axis of the shaft member at least at the peripheral edge of the hole. A flanged shaft member. 前記フランジ部材がアルミニウム合金押出材からなり、その背面側に突条又は凹溝が形成され、前記穴はその周方向の一部が前記突条又は凹溝を通って板厚方向に貫通していることを特徴とする請求項8に記載されたフランジ付き軸部材。 The flange member is made of an aluminum alloy extruded material, and a ridge or a groove is formed on the back side thereof, and a part of the circumferential direction of the hole passes through the ridge or the groove and penetrates in the plate thickness direction. The flanged shaft member according to claim 8, wherein the shaft member has a flange. 前記フランジ部材は、その背面が少なくとも前記穴の周縁部において1つの平面内にあり、該平面が前記軸部材の軸に垂直な面に対して傾斜していることを特徴とする請求項8に記載されたフランジ付き軸部材。 9. The flange member according to claim 8, wherein a back surface of the flange member is in one plane at least at a peripheral edge of the hole, and the plane is inclined with respect to a plane perpendicular to the axis of the shaft member. The flanged shaft member described. 前記フランジ部材がアルミニウム合金押出材からなることを特徴とする請求項10に記載されたフランジ付き軸部材。 The flanged shaft member according to claim 10, wherein the flange member is made of an aluminum alloy extruded material. 前記フランジ付き軸部材が自動車のバンパーステイであることを特徴とする請求項1〜11のいずれかに記載されたフランジ付き軸部材。 The flanged shaft member according to claim 1, wherein the flanged shaft member is a bumper stay of an automobile.
JP2004131529A 2004-04-27 2004-04-27 Flanged shaft member Expired - Lifetime JP3933645B2 (en)

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JP2004131529A JP3933645B2 (en) 2004-04-27 2004-04-27 Flanged shaft member
US11/115,353 US7658421B2 (en) 2004-04-27 2005-04-27 Axial member with flange, connection member and production methods thereof
US12/650,146 US7980615B2 (en) 2004-04-27 2009-12-30 Axial member with flange, connection member and production methods thereof

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Cited By (5)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
JP2010116129A (en) * 2008-11-14 2010-05-27 Kobe Steel Ltd Bumper structure and method of manufacturing the same
CN101947604A (en) * 2010-08-17 2011-01-19 湖北三环锻压设备有限公司 Pendulum-type bidirectional expanding machine
US7900741B2 (en) 2007-09-11 2011-03-08 Toyota Jidosha Kabushiki Kaisha Torque tube
JP2019018608A (en) * 2017-07-12 2019-02-07 トヨタ自動車株式会社 Instrument panel reinforcement fixing structure
JP2020066034A (en) * 2018-10-25 2020-04-30 株式会社神戸製鋼所 Dissimilar material joining method, dissimilar material joining joint, tubular member with dissimilar material joining auxiliary member, and method of manufacturing the same

Cited By (6)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US7900741B2 (en) 2007-09-11 2011-03-08 Toyota Jidosha Kabushiki Kaisha Torque tube
JP2010116129A (en) * 2008-11-14 2010-05-27 Kobe Steel Ltd Bumper structure and method of manufacturing the same
CN101947604A (en) * 2010-08-17 2011-01-19 湖北三环锻压设备有限公司 Pendulum-type bidirectional expanding machine
JP2019018608A (en) * 2017-07-12 2019-02-07 トヨタ自動車株式会社 Instrument panel reinforcement fixing structure
JP2020066034A (en) * 2018-10-25 2020-04-30 株式会社神戸製鋼所 Dissimilar material joining method, dissimilar material joining joint, tubular member with dissimilar material joining auxiliary member, and method of manufacturing the same
JP6993312B2 (en) 2018-10-25 2022-01-13 株式会社神戸製鋼所 Dissimilar material joining method, dissimilar material joining joint, tubular member with auxiliary member for dissimilar material joining, and its manufacturing method

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