汽车工程
汽車工程
기차공정
Automotive Engineering
2015年
11期
1284-1290,1306
,共8页
蒋小晴%杨济匡%王丙雨%张维刚
蔣小晴%楊濟劻%王丙雨%張維剛
장소청%양제광%왕병우%장유강
汽车前碰撞%骨盆骨折%髋关节姿态%乘员下肢%有限元模型
汽車前踫撞%骨盆骨摺%髖關節姿態%乘員下肢%有限元模型
기차전팽당%골분골절%관관절자태%승원하지%유한원모형
vehicle frontal impact%pelvis fracture%hip posture%occupant lower extremity%FE model
本文旨在建立一种在汽车前碰撞中乘员骨盆损伤评价的虚拟试验方法,以便为乘员安全设计提供相关的生物力学参数。基于LS-DYNA和某一50百分位美国男性下肢解剖学结构信息,建立了一个较为精细的乘员下肢有限元模型,并通过骨盆侧向冲击和膝大腿髋部的膝部轴向冲击模拟试验验证了模型的有效性。对该模型进行了虚拟试验,以研究不同屈曲角和外展角的髋关节姿态对骨盆在前碰撞的失效值的影响。结果表明:由于髋臼壁各受力点强度的不同,膝部轴向冲击下的骨盆损伤部位和失效值也随着髋关节姿态的改变而变化。随着髋关节屈曲角和外展角的增大,骨盆损伤部位由髂骨转移到髋臼;骨盆失效值随屈曲角的增加而增大;而随外展角的增加先增大后减小。研究结果为汽车前碰撞安全设计中的乘员骨盆损伤评价提供了参考依据。
本文旨在建立一種在汽車前踫撞中乘員骨盆損傷評價的虛擬試驗方法,以便為乘員安全設計提供相關的生物力學參數。基于LS-DYNA和某一50百分位美國男性下肢解剖學結構信息,建立瞭一箇較為精細的乘員下肢有限元模型,併通過骨盆側嚮遲擊和膝大腿髖部的膝部軸嚮遲擊模擬試驗驗證瞭模型的有效性。對該模型進行瞭虛擬試驗,以研究不同屈麯角和外展角的髖關節姿態對骨盆在前踫撞的失效值的影響。結果錶明:由于髖臼壁各受力點彊度的不同,膝部軸嚮遲擊下的骨盆損傷部位和失效值也隨著髖關節姿態的改變而變化。隨著髖關節屈麯角和外展角的增大,骨盆損傷部位由髂骨轉移到髖臼;骨盆失效值隨屈麯角的增加而增大;而隨外展角的增加先增大後減小。研究結果為汽車前踫撞安全設計中的乘員骨盆損傷評價提供瞭參攷依據。
본문지재건립일충재기차전팽당중승원골분손상평개적허의시험방법,이편위승원안전설계제공상관적생물역학삼수。기우LS-DYNA화모일50백분위미국남성하지해부학결구신식,건립료일개교위정세적승원하지유한원모형,병통과골분측향충격화슬대퇴관부적슬부축향충격모의시험험증료모형적유효성。대해모형진행료허의시험,이연구불동굴곡각화외전각적관관절자태대골분재전팽당적실효치적영향。결과표명:유우관구벽각수력점강도적불동,슬부축향충격하적골분손상부위화실효치야수착관관절자태적개변이변화。수착관관절굴곡각화외전각적증대,골분손상부위유가골전이도관구;골분실효치수굴곡각적증가이증대;이수외전각적증가선증대후감소。연구결과위기차전팽당안전설계중적승원골분손상평개제공료삼고의거。
This paper aims to develop a virtual test method for assessing occupant pelvis injury in vehicle frontal crash, in order to provide relevant biomechanical parameters for occupant safety design. Accordingly, based on the anatomical structure information of a 50th percentile American male and using LS-DYNA code, a relatively refined finite element model for occupant lower extremity is created with its effectiveness verified by the simulation tests of side impact on pelvis and axial impact on knee-thigh-hip complex. Then a series of virtual tests are conduc-ted on the model to investigate the influence of hip posture with different flexion angles and abduction angles on the failure force of pelvis. The results show that the pelvis fracture location and failure force under axial impact on knee depend on hip posture due to the different strength of various loaded points on acetabulum wall. With the increase of thigh flexion and abduction angles, pelvis fracture location shifts from ilium to acetabulum. The failure force of pel-vis goes up with the increase of thigh flexion angle, while it goes up first and then falls down with the rise of thigh abduction angle. The findings of this study provide a reference basis for pelvis injury assessment in vehicle frontal crash safety design.
