JP4045846B2 - Impact energy absorbing member - Google Patents
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- JP4045846B2 JP4045846B2 JP2002121642A JP2002121642A JP4045846B2 JP 4045846 B2 JP4045846 B2 JP 4045846B2 JP 2002121642 A JP2002121642 A JP 2002121642A JP 2002121642 A JP2002121642 A JP 2002121642A JP 4045846 B2 JP4045846 B2 JP 4045846B2
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Description
【0001】
【発明の属する技術分野】
本発明は、衝突エネルギー吸収部材に関し、詳しくは、金属材料で構成された自動車の車体フレーム構造の一部をなして自動車衝突時の衝突エネルギーを部材軸方向の座屈によって吸収する衝突エネルギー吸収部材に関する。
【0002】
【従来の技術】
自動車車体のフレーム構造部品のなかで、図5に示すようなフロントサイドフレーム1や、車両後部に配置されるリヤサイドフレーム(図示省略)などは、自動車の衝突時のエネルギー吸収部材として重要な役割を果たしている。自動車が衝突した際に、前記サイドフレームが適度に潰れることにより衝突時のエネルギーを吸収し、キャビン内の乗員生存空間を確保するような構造とするのが一般的である。例えば図5に示したフロントサイドフレーム1では前方での衝突時に矢示方向に入力される荷重(衝突荷重)2がバンパを介してフロントサイドフレーム1へと伝達され、このときにフロントサイドフレーム1が適切に潰れずエネルギーを吸収できなかった場合には、衝突時の荷重2がさらに後方のキャビンに伝達され、乗員に損傷を与えることになる。それゆえ、フロントサイドフレーム等の衝突エネルギー吸収部材には、エネルギー吸収能の高い部材が望まれている。
【0003】
このような要望に対し、例えば、特開平4-310477号公報には、軽金属により閉断面構造に押し出し成形された基本メンバとこの基本メンバ内に嵌合し略同じ長さの、少なくとも先端に圧縮変形促進部、好ましくは切欠を設けた補強メンバとで2重構造を形成した部材が提案されている。また、特開平11-29064号、特開平11-208519 号公報には、同じく軽金属材料の押し出し加工により、中空材の中心軸を通る面上に、中空材の内面に接するリブを設けたことを特徴とする自動車車体のフレーム構造が提案されている。
【0004】
【発明が解決しようとする課題】
衝突時のエネルギー吸収量を大きくするためには、部材を構成する材料の板厚を厚くすることが有効である。しかしながら、部材の板厚を厚くすることは車体重量を増加させ燃費の悪化に直接結びつくことになり、地球環境保全の観点から全世界規模で展開されているCO2 排出量削減活動すなわち自動車の軽量化の観点からは好ましくない。
【0005】
エネルギー吸収量を増加させるもう一つの方法として、部材の断面形状を最適化する方法がある。断面形状の最適化は、部材の板厚を増加させることなく、部材の単位重量当りのエネルギー吸収量を増加させることができる点で有効である。
このような背景のもと、従来は前記したようなアルミニウムに代表される軽金属材料の押し出し加工によるフロントサイドフレームなどが提案されてきた。これによれば、押し出し加工により成形された隔壁を有する閉断面構造の部材は、それ以前の隔壁のない単純な閉断面構造の部材に比べエネルギー吸収量が増加するとともに、座屈形状が安定することによりエネルギー吸収量および変形時の座屈荷重も安定するという利点を有する。
【0006】
しかしながら、アルミニウムに代表される軽金属材料の押し出し加工部品では、被加工材料および製造コストが高く、生産性が悪いことから、部品自体が高価であるという問題点や、隣接する部品との締結方法も煩雑になるという問題点があった。
また、自動車車体用フレーム材として最も一般的に使用されている鉄鋼材料などでは、公知の方法(例えば板金加工等)により隔壁を有する断面構造部材を製造することは可能であるが、加工が煩雑であり、複数の工程を必要とするなどの理由から、製造技術的にもコスト的にも問題点があった。
【0007】
本発明は、これらの問題点を解決し、小型軽量でかつ部材軸方向の座屈による衝撃吸収エネルギー量が大きく、しかも安価で生産性に優れた自動車用衝突エネルギー吸収部材を提供することを目的とする。
【0008】
【課題を解決するための手段】
本発明者らは上記課題を解決するために、容易にかつ安価に製造可能な隔壁を有する閉断面形状の構造部材について検討を重ね、以下の要旨になる本発明をなすに至った。
(1)金属材料で構成される自動車の車体フレーム構造部材のうち、部材軸方向の座屈によって自動車衝突時の衝突エネルギーを吸収する衝突エネルギー吸収部材において、プレス加工された薄鋼板を閉断面形状に組合わせ溶接してなる外枠部材内に、円管または角管からなる第1種の内挿部材を圧入することにより複数個充填挿入し、該内挿部材からなる隔壁を形成してなることを特徴とする衝突エネルギー吸収部材。
(2)前記円管または角管からなる第1種に代えて、プレス加工された薄鋼板を閉断面形状に組合わせ溶接してなる第2種としたことを特徴とする(1)記載の衝突エネルギー吸収部材。
【0009】
【発明の実施の形態】
本発明の衝突エネルギー吸収部材(本発明部材)は、自動車衝突時の衝突エネルギーを部材軸方向の座屈によって吸収するものであって、例えば図1に示すように、薄鋼板を断面ハット形状(図1:a-f、ただし a は参考例)または断面半円形状(図1:g,h)にプレス加工してなるプレス成形品3を複数個(この例では2個)、閉断面形状となるように組合わせ、好ましくはフランジ部4のところで、溶接9して外枠部材5となし、同部材内に、円管6または角管7からなる第1種の内挿部材を複数個充填挿入し、該内挿部材からなる隔壁(内部隔壁)8を形成してなる部材である。
【0010】
本発明でいうところの充填挿入とは、複数個の内挿部材を外枠部材内へ挿入するにあたり、内挿部材が外枠部材に内接および/または同外枠部材内の他の内挿部材に外接して挿入方向以外の方向の平行移動を阻止された状態となるように挿入することを意味する。プレス成形品3同士を溶接9する方法は、スポット溶接、レーザ溶接、アーク溶接など、どのような溶接方法でもよい。
【0011】
これにより、薄鋼板をプレス加工後溶接してなる外枠部材内に円管または角管の管壁からなる隔壁が形成されるから、従来の押し出し加工や煩雑な加工方法を用いることなく、容易に内部隔壁を有する部材を製造することができる。これらの部材は、内部隔壁により横方向の曲げ剛性が強くなっているから、衝突荷重入力時に横方向にオイラー座屈が発生し難く、軸方向に安定的に座屈させうるという利点も併せ持っている。
【0012】
また、上記のように部材の横方向の曲げ剛性が強くなることから、自動車の側面衝突時または正面衝突時に曲げ変形を生じるような、サイドシル、センターピラー、フロントピラー、ルーフレールなどの自動車部品に本発明を適用しても、フロントサイドフレームの場合と同じく、衝突時のエネルギーを良好に吸収することができ、衝突時の乗員安全性を向上させる効果が得られる。
【0013】
さらに、外枠部材内に円管または角管を充填挿入して内部隔壁を形成することにより、当該部材を上記のように軸方向に安定的に座屈させうるのみならず、図2に示すように、衝突時に部材が圧潰されて潰れていく間のエネルギー吸収量を増大させうることが本発明者らの実験で判明した。
図2は、本発明例(#1)および比較例(#2),(#3),(#4)を部材軸方向に圧潰した際の荷重- 変位曲線を示す特性図である。ここで、本発明例(#1)は図1(c) と同一形態のもの、比較例(#2)は通常の断面ハット形状のプレス成形品3を組合わせ溶接9したもの、比較例(#3)は比較例(#2)に通常の断面ハット形状のプレス成形品からなる補強材10を組合わせて溶接9したもの、比較例(#4)は比較例(#2)に円管6を単に挿入(非充填挿入)して溶接9したものである。なお、ここで用いた被圧潰部材の構成要素(外枠部材、補強材、円管)の厚みはいずれも同じとし、各例はいずれも同一重量となるようそれぞれの構成要素の周長(部材軸方向に垂直な断面内での肉厚中心線長)を設定した。
【0014】
図2に示されるように、軸方向圧潰時の荷重特性は、本発明例、比較例とも、衝突直後に初期ピーク荷重Pまで上昇した荷重が、座屈変形の開始とともに低下したのち、座屈変形の蛇腹状進展に伴い微小な増減を繰返す様相を呈し、初期ピーク荷重Pはいずれの例でも略同等レベルになる。しかし、本発明例では、座屈変形の蛇腹状進展に伴い微小な増減を繰返す時期に比較例よりも高い荷重レベルが得られ、荷重の変位積分で評価される変形時のエネルギー吸収量が大きいことがわかる。
【0015】
この理由は次のように考えられる。すなわち、本発明例では円管等の内挿部材を充填挿入してなる内部隔壁の個々が部材軸方向に蛇腹状に座屈変形する際に相互に干渉し合うのに対し、比較例(#2)では内部隔壁がないからそのような相互干渉は起こらず、また、比較例(#3),(#4) では隔壁相当部材はあるが他の要素部材との接触箇所が少ないため、相互干渉が起こったにしても本発明例ほど大きなものにはならない。また(#4)のように内挿部材が外枠部材の片側に寄っている場合は、断面形状の対称性が悪く安定して圧潰されず、横方向に折れ曲がりやすい。それゆえ本発明例では座屈変形の蛇腹状進展段階において比較例よりも高い荷重レベルに到達する。
【0016】
また、本発明では、例えば図3に示すように、円管または角管からなる第1種の内挿部材の代わりに、プレス加工された薄鋼板(プレス成形品)を閉断面形状に組合わせ溶接9してなる第2種の内挿部材5Aを用いても同様の効果が得られる。
なお、第2種の内挿部材は、四角形状の場合、溶接フランジが挿入時に外枠部材または内挿部材と干渉することになるため、図3に示すように断面円形状に構成したものが好ましい。またプレス成形品の組合わせ個数は、複数であれば特に限定されないが、プレス工数や溶接工数を節減する観点からは2個が好ましい。この点に関しては外枠部材でも同様である。
【0017】
一方、外枠部材の断面形状は、図1に示したような、ハット状を合わせた略四角形状や、半円弧状を合わせた略円形状に限定されるものではなく、他の形状(例えば多角形状、楕円形状など)であっても同様の効果が得られる。内挿部材は、外枠部材とレーザ溶接などにより溶接してもよいが、本発明では圧入することにより固定する(種別によらない)。
【0018】
また、内挿部材の充填挿入個数が1個の場合、衝突時にこの1個と外枠部材とで変形同士の干渉が起こるが、複数個の場合、これら内挿部材の変形同士、すなわち各隔壁の座屈変形同士の干渉も加わるため、エネルギー吸収量がさらに大きくなる。したがって、本発明では内挿部材の充填挿入個数は複数個とする(種別によらない)。
【0019】
また、本発明は、内挿部材の種別、個数、断面形状および外枠部材の断面形状等の組合わせに左右されるものではなく、図1、図3に例示されない組合わせであっても、同様の効果が期待できる。どのような組合わせとするかは、必要とするエネルギー吸収量や部材重量などを考慮して適宜決定すればよい。
【0020】
【実施例】
1.2mm 厚で引張強さ440MPaの熱延鋼板を素材として図4に部材軸方向に垂直な断面形状を示す部材A〜Dを作製した。各部材の軸方向長さは300mm とした。
部材Aは、前記素材を断面ハット状にプレス成形したものを2個閉断面形状に組合わせてスポット溶接した部材であって、内部隔壁のない比較例である。この部材Aの断面寸法は、矩形部縦横各120mm 、溶接用フランジ部長さ20mmに設定した。
【0021】
部材B〜Dは、素材を断面ハット状にプレス成形したものを2個閉断面形状に組合わせ、スポット溶接して外枠部材となし、該外枠部材内に前記素材を電縫溶接造管法にて造管してなる円管からなる第1種の内挿部材を充填挿入し、該内挿部材により隔壁を形成してなる本発明例(ただし部材Bは参考例)である。内挿部材の外枠部材への挿入は圧入によって行い、両者の溶接は行っていない。部材B〜Dをなす断面ハット状部材および挿入管の周長は、部材B〜Dがそれぞれ部材Aと同一重量となるように計算して設定した。
【0022】
これらの部材の軸方向の一端面に錘を時速50kmの速さで正面衝突させ、発生する荷重をロードセルで計測するとともに衝突端の変位をレーザ変位計で計測して荷重- 変位曲線を求め、該曲線を用いて変位0〜150mm の範囲の荷重を変位で積分することにより、変形(軸方向の圧潰長さ)が150mm に達するまでに部材に吸収されたエネルギー量を算出した。
【0023】
図4に、部材Aに対する各部材のエネルギー吸収量比を示す。A<B<C<Dの順にエネルギー吸収量が大きくなっており、本発明部材のエネルギー吸収能が高いことが検証された。
次に、前述と同じ1.2mm 厚で引張強さ440MPaの熱延鋼板を素材として、図6に部材軸方向に垂直な断面形状を示す部材E〜Gを作製した。各部材の軸方向長さは300mm とした。
【0024】
部材Eは、図4で説明した部材Aと同じく前記素材を断面ハット状にプレス成形したものを2個閉断面形状に組合わせてスポット溶接した部材であって、内部隔壁のない比較例である。この部材Eの断面寸法は、図4の部材Aと同じく矩形部縦横各120mm 、溶接用フランジ部長さ20mmに設定した。
部材F,Gは、素材を断面ハット状にプレス成形したものを2個閉断面形状に組合わせ、スポット溶接して外枠部材となし、該外枠部材内に、前記素材を断面半円形状にプレス成形したものを2個閉断面形状に組合わせてスポット溶接してなる第2種の内挿部材を充填挿入し、該内挿部材により隔壁を形成してなる本発明例(ただし部材Fは参考例)である。内挿部材の外枠部材への挿入は圧入によって行い、両者の溶接は行っていない。部材F,Gをなす断面ハット状部材および挿入部材の周長は、部材F,Gがそれぞれ部材Eと同一重量となるように計算して設定した。
【0025】
これら部材の軸方向の一端面に錘を時速50kmの速さで正面衝突させ、前述の方法で荷重- 変位曲線を求め、変形が150mm に達するまでに部材が吸収したエネルギー量を算出した。
図6に、部材Eに対する各部材のエネルギー吸収量比を示す。E<F<Gの順にエネルギー吸収量が大きくなっており、本発明部材のエネルギー吸収能が高いことが検証された。
【0026】
【発明の効果】
かくして本発明によれば、容易にかつ低コストで自動車衝突時のエネルギー吸収能が高い部材を製造することができて、乗員の安全性の確保はもとより、さらなる車両軽量化を図ることができるという優れた効果を奏する。
【図面の簡単な説明】
【図1】 第1種の内挿部材からなる隔壁を有する本発明例(ただし (a) は参考例)を示す断面図である。
【図2】 本発明例(#1)および比較例(#2,#3,#4)を部材軸方向に圧潰した際の荷重- 変位曲線を示す特性図である。
【図3】 第2種の内挿部材からなる隔壁を有する本発明例(a) および参考例 (b)を示す断面図である。
【図4】 参考例B, 本発明例C, Dおよび比較例Aの衝突時エネルギー吸収量比を示すグラフである。
【図5】 フロントサイドフレームの1例を示す説明図である。
【図6】 参考例F,本発明例Gおよび比較例Eの衝突時エネルギー吸収量比を示すグラフである。
【符号の説明】
1 フロントサイドフレーム
2 荷重(衝突荷重)
3 プレス成形品(プレス加工された薄鋼板)
4 フランジ部
5 外枠部材
5A 第2種の内挿部材
6 円管(第1種の内挿部材)
7 角管(第1種の内挿部材)
8 隔壁(内部隔壁)
9 溶接
10 補強材[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a collision energy absorbing member, and more specifically, a collision energy absorbing member that forms a part of a vehicle body frame structure made of a metal material and absorbs collision energy at the time of automobile collision by buckling in a member axial direction. About.
[0002]
[Prior art]
Among the frame structural parts of the automobile body, the
[0003]
In response to such a request, for example, Japanese Patent Application Laid-Open No. 4-310477 discloses a basic member extruded into a closed cross-sectional structure with a light metal, and is fitted into the basic member and compressed to at least the tip of substantially the same length. A member in which a double structure is formed by a deformation promoting portion, preferably a reinforcing member provided with a notch has been proposed. Also, in JP-A-11-29064 and JP-A-11-208519, ribs that are in contact with the inner surface of the hollow material are provided on the surface passing through the central axis of the hollow material by the extrusion process of the light metal material. A frame structure of a car body has been proposed.
[0004]
[Problems to be solved by the invention]
In order to increase the energy absorption amount at the time of collision, it is effective to increase the thickness of the material constituting the member. However, increasing the thickness of the components increases the weight of the vehicle and directly leads to a deterioration in fuel consumption. From the viewpoint of global environmental conservation, CO 2 emission reduction activities that are being deployed worldwide, that is, lighter automobiles. It is not preferable from the viewpoint of conversion.
[0005]
As another method for increasing the energy absorption amount, there is a method for optimizing the cross-sectional shape of the member. Optimization of the cross-sectional shape is effective in that the amount of energy absorption per unit weight of the member can be increased without increasing the plate thickness of the member.
Against this background, a front side frame by extruding a light metal material typified by aluminum as described above has been proposed. According to this, a member having a closed cross-sectional structure having a partition wall formed by extrusion processing has an increased amount of energy absorption and a stable buckling shape compared to a member having a simple closed cross-section structure without a previous partition wall. This has the advantage that the amount of energy absorption and the buckling load during deformation are also stabilized.
[0006]
However, in extruded parts of light metal materials represented by aluminum, the material to be processed and the manufacturing cost are high, and the productivity is poor. Therefore, there is a problem that the parts themselves are expensive, and there are also methods for fastening with adjacent parts. There was a problem of becoming complicated.
In addition, for steel materials and the like that are most commonly used as frame materials for automobile bodies, it is possible to manufacture cross-sectional structural members having partition walls by a known method (for example, sheet metal processing), but the processing is complicated. In view of the necessity of a plurality of processes, there are problems in terms of manufacturing technology and cost.
[0007]
An object of the present invention is to solve these problems, and to provide a collision energy absorbing member for automobiles which is small and light, has a large amount of impact absorbed energy due to buckling in the axial direction of the member , and is inexpensive and excellent in productivity. And
[0008]
[Means for Solving the Problems]
In order to solve the above-described problems, the present inventors have repeatedly studied a structural member having a closed cross-sectional shape having a partition wall that can be manufactured easily and inexpensively, and have reached the present invention as described below.
(1) Among the body frame structural members of automobiles made of metal materials, a pressed steel sheet is closed in a cross-sectional shape in a collision energy absorbing member that absorbs collision energy during automobile collision by buckling in the member axial direction A plurality of first-type insertion members made of a circular tube or a square tube are press-fitted into an outer frame member that is welded in combination to form a partition made of the insertion member. The collision energy absorption member characterized by the above-mentioned.
(2) Instead of the first type consisting of the circular tube or the square tube, the second type formed by welding a pressed steel sheet in combination with a closed cross-sectional shape is used. Impact energy absorbing member.
[0009]
DETAILED DESCRIPTION OF THE INVENTION
The collision energy absorbing member of the present invention (member of the present invention) absorbs collision energy at the time of automobile collision by buckling in the member axial direction . For example, as shown in FIG. Fig. 1: af , where a is a reference example ) or a plurality of press-formed products 3 (two in this example) formed by pressing into a semicircular cross section (Fig. 1: g, h), resulting in a closed cross-sectional shape as combined, preferably at the
[0010]
The filling insertion referred to in the present invention, several inner insertion member multiple Upon insertion into the outer frame member, among the inner insertion member is other in an inscribed and / or Dosotowaku member to the outer frame member means inserts that as circumscribes the insertion member in the state of being blocked translation direction other than the insertion direction. Any welding method such as spot welding, laser welding, arc welding, or the like may be used as the method for welding 9 the press-formed
[0011]
As a result, a partition wall made of a circular tube or a square tube is formed in the outer frame member formed by welding a thin steel plate after press working, so it is easy to use without using conventional extrusion processing or complicated processing methods. A member having an internal partition can be manufactured. These members have the advantage of being able to buckle stably in the axial direction because Euler buckling hardly occurs in the lateral direction when a collision load is input because the lateral bending rigidity is strengthened by the internal partition. Yes.
[0012]
In addition, since the lateral bending rigidity of the members is increased as described above, the present invention is applied to automobile parts such as side sills, center pillars, front pillars, and roof rails that cause bending deformation at the time of side collision or frontal collision. Even when the invention is applied, as in the case of the front side frame, the energy at the time of the collision can be absorbed well, and the effect of improving the occupant safety at the time of the collision can be obtained.
[0013]
Furthermore, by filling and inserting a circular tube or a square tube into the outer frame member to form an internal partition wall, the member can be stably buckled in the axial direction as described above, as shown in FIG. As described above, it has been found in the experiments by the present inventors that the amount of energy absorption during the collision can be increased while the member is crushed and crushed.
FIG. 2 is a characteristic diagram showing a load-displacement curve when the present invention example (# 1) and the comparative examples (# 2), (# 3), and (# 4) are crushed in the member axial direction. Here, Example (# 1) of the present invention has the same form as FIG. 1 (c), Comparative Example (# 2) is a combination of a press-formed
[0014]
As shown in FIG. 2, the load characteristics at the time of axial crushing are shown in both the examples of the present invention and the comparative example. After the load that has increased to the initial peak load P immediately after the collision decreases with the start of buckling deformation, the buckling is performed. Along with the accordion-like progress of deformation, it appears to repeat a slight increase / decrease, and the initial peak load P is approximately the same level in any example. However, in the example of the present invention, a load level higher than that of the comparative example is obtained at a time when the minute increase / decrease is repeated with the bellows-like progress of the buckling deformation, and the energy absorption amount at the time of deformation evaluated by load displacement integration is large. I understand that.
[0015]
The reason is considered as follows. That is, in the present invention example, each of the internal partition walls formed by inserting and inserting an insertion member such as a circular tube interferes with each other when buckling deformed in a bellows shape in the member axial direction, whereas the comparative example (# In 2), there is no internal partition, so such mutual interference does not occur.In Comparative Examples (# 3) and (# 4), there are partition equivalent members but there are few contact points with other element members. Even if interference occurs, it will not be as large as the present invention. Further, when the insertion member is close to one side of the outer frame member as in (# 4), the cross-sectional shape is not symmetrical and is not stably crushed and easily bends in the lateral direction. Therefore, in the example of the present invention, the load level higher than that of the comparative example is reached in the bellows-like progress stage of buckling deformation.
[0016]
Further, in the present invention, for example, as shown in FIG. 3, a pressed steel sheet (press-formed product) is combined into a closed cross-sectional shape in place of the first type of insertion member formed of a circular tube or a square tube. The same effect can be obtained even if the second type of
In the case of the second type of insertion member having a quadrangular shape, the welding flange interferes with the outer frame member or the insertion member at the time of insertion. preferable. Further, the number of combinations of the press-formed products is not particularly limited as long as it is plural, but two is preferable from the viewpoint of reducing the press man-hour and the welding man-hour. This also applies to the outer frame member.
[0017]
On the other hand, the cross-sectional shape of the outer frame member is not limited to a substantially square shape combined with a hat shape or a substantially circular shape combined with a semicircular arc shape as shown in FIG. The same effect can be obtained even when the shape is polygonal or elliptical. The insertion member may be welded to the outer frame member by laser welding or the like, but in the present invention, it is fixed by press-fitting (regardless of type).
[0018]
Further, when the number of inserted insertion members is one, there is interference between deformations between this one and the outer frame member at the time of a collision. Because of the interference between the buckling deformations, the amount of energy absorption is further increased. Therefore, the filling insert number of the inner insertion member in the present invention shall be the plurality (not according to the type).
[0019]
Further, the present invention does not depend on the combination of the type, number, cross-sectional shape, and cross-sectional shape of the outer frame member of the insertion member, etc., even if the combination is not illustrated in FIGS. Similar effects can be expected. What kind of combination should be determined may be determined appropriately in consideration of the required energy absorption amount, member weight, and the like.
[0020]
【Example】
Members A to D having a cross-sectional shape perpendicular to the member axial direction in FIG. 4 were produced using a hot-rolled steel sheet having a thickness of 1.2 mm and a tensile strength of 440 MPa as a raw material. The axial length of each member was 300 mm.
The member A is a comparative example having no internal partition wall, which is a member obtained by spot-welding two of the above-mentioned raw materials press-molded in a cross-sectional hat shape into a closed cross-sectional shape. The cross-sectional dimensions of the member A were set to 120 mm each for the length and width of the rectangular portion and the length of the welding flange portion of 20 mm.
[0021]
The members B to D are formed by combining the two press-formed materials into a closed cross-sectional shape into a closed cross-sectional shape and spot-welded to form an outer frame member. The material is electro-welded in the outer frame member. This is an example of the present invention (member B is a reference example) in which a first type of insertion member composed of a circular pipe formed by the method is filled and inserted, and a partition is formed by the insertion member . The insertion of the insertion member into the outer frame member is performed by press fitting, and the two are not welded. The cross-sectional hat-shaped member forming the members B to D and the circumference of the insertion tube were calculated and set so that the members B to D had the same weight as the member A, respectively.
[0022]
A weight is caused to collide head-on at one end face in the axial direction of these members at a speed of 50 km / h, the generated load is measured with a load cell and the displacement of the collision end is measured with a laser displacement meter to obtain a load-displacement curve, The amount of energy absorbed by the member until the deformation (crush length in the axial direction) reached 150 mm was calculated by integrating the load in the range of 0 to 150 mm using the curve.
[0023]
FIG. 4 shows the energy absorption ratio of each member to member A. The amount of energy absorption increased in the order of A <B <C <D, and it was verified that the energy absorption capacity of the member of the present invention was high.
Next, members EG having a cross-sectional shape perpendicular to the member axial direction in FIG. 6 were produced using the same hot rolled steel sheet having a thickness of 1.2 mm and a tensile strength of 440 MPa as described above. The axial length of each member was 300 mm.
[0024]
The member E is a member that is spot welded by combining two pieces of the above-mentioned raw material pressed into a cross-sectional hat shape in the shape of a cross-sectional hat as in the case of the member A described in FIG. . The cross-sectional dimensions of the member E were set to 120 mm each for the length and width of the rectangular portion and the length of the welding flange portion 20 mm, as with the member A of FIG.
The members F and G are formed by combining two press-molded materials into a closed cross-sectional shape and spot-welded to form an outer frame member. The material is semicircular in cross-section within the outer frame member. Example of the present invention in which a second type of insertion member formed by combining two press-molded products into a closed cross-sectional shape and spot-welding is inserted and a partition wall is formed by the insertion member (however, the member F) Is a reference example) . The insertion of the insertion member into the outer frame member is performed by press fitting, and the two are not welded. The circumferential lengths of the cross-sectional hat-shaped member and the insertion member forming the members F and G were calculated and set so that the members F and G had the same weight as the member E, respectively.
[0025]
The weights were collided with one end face in the axial direction of these members at a speed of 50 km / h, the load-displacement curve was obtained by the method described above, and the amount of energy absorbed by the members until the deformation reached 150 mm was calculated.
FIG. 6 shows the ratio of energy absorption of each member to member E. The energy absorption amount increased in the order of E <F <G, and it was verified that the energy absorption capacity of the member of the present invention was high.
[0026]
【The invention's effect】
Thus, according to the present invention, it is possible to easily and inexpensively manufacture a member having high energy absorption capability at the time of a car collision, and it is possible to further reduce the weight of the vehicle as well as ensuring the safety of the passenger. Excellent effect.
[Brief description of the drawings]
FIG. 1 is a cross-sectional view showing an example of the present invention (where (a) is a reference example) having a partition wall made of a first type of insertion member.
FIG. 2 is a characteristic diagram showing a load-displacement curve when the invention example (# 1) and the comparative examples (# 2, # 3, # 4) are crushed in the member axial direction.
FIG. 3 is a cross-sectional view showing an example of the present invention (a) and a reference example (b) having a partition wall made of a second type of insertion member.
4 is a graph showing the energy absorption ratio at the time of collision in Reference Example B, Invention Examples C and D, and Comparative Example A. FIG.
FIG. 5 is an explanatory diagram showing an example of a front side frame.
6 is a graph showing the energy absorption ratio at the time of collision in Reference Example F, Invention Example G and Comparative Example E. FIG.
[Explanation of symbols]
1
3 Press-formed product (Pressed thin steel plate)
4
7 Square tube (1st type insertion member)
8 Bulkhead (Internal Bulkhead)
9 Welding
10 Reinforcing material
Claims (2)
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JP2002121642A JP4045846B2 (en) | 2002-04-24 | 2002-04-24 | Impact energy absorbing member |
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JP2002121642A JP4045846B2 (en) | 2002-04-24 | 2002-04-24 | Impact energy absorbing member |
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Cited By (1)
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CN108016502A (en) * | 2016-10-28 | 2018-05-11 | 长城汽车股份有限公司 | Automobile door sill strengthens girder construction |
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JP4543778B2 (en) * | 2004-06-24 | 2010-09-15 | 住友金属工業株式会社 | Shock absorbing member |
JP2006168594A (en) * | 2004-12-17 | 2006-06-29 | Nissan Motor Co Ltd | Reinforcing structure for vehicle body skeleton frame |
JP4766422B2 (en) * | 2005-07-28 | 2011-09-07 | 関東自動車工業株式会社 | Crash box |
JP2008012996A (en) * | 2006-07-04 | 2008-01-24 | Toyota Auto Body Co Ltd | Vehicle body side portion structure |
JP5032853B2 (en) * | 2007-01-19 | 2012-09-26 | 本田技研工業株式会社 | Car body rear structure |
JP5316935B2 (en) * | 2008-09-26 | 2013-10-16 | 新日鐵住金株式会社 | Steel pipe for impact energy absorption for automobile and method for manufacturing the same |
JP5298910B2 (en) * | 2009-02-10 | 2013-09-25 | トヨタ自動車株式会社 | Shock absorption structure |
JP5439957B2 (en) * | 2009-06-05 | 2014-03-12 | マツダ株式会社 | Shock absorbing structure for vehicle |
DE102013004852A1 (en) * | 2013-03-21 | 2014-09-25 | Thyssenkrupp Steel Europe Ag | Sills for a vehicle body |
JP2015077610A (en) * | 2013-10-16 | 2015-04-23 | トヨタ自動車株式会社 | Laser joining structure and laser joining method |
JP6245040B2 (en) * | 2014-04-01 | 2017-12-13 | 株式会社豊田中央研究所 | Frame structure and frame device |
CN108953450B (en) * | 2018-05-29 | 2020-02-07 | 北京理工大学 | Impact-resistant energy absorption structure |
CN115009363B (en) * | 2022-06-24 | 2023-10-13 | 厦门金龙联合汽车工业有限公司 | Frame, slide chassis and electric automobile |
CN116792008B (en) * | 2023-08-02 | 2024-05-14 | 常州华东人防设备有限公司 | Protective door and manufacturing method thereof |
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Cited By (1)
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CN108016502A (en) * | 2016-10-28 | 2018-05-11 | 长城汽车股份有限公司 | Automobile door sill strengthens girder construction |
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