Intelligent Hydraulic Bumper for Frontal Collision Mitigation

Crashworthiness and Occupant Protection in Transportation Systems Pub Date : 1996-11-17 DOI:10.1115/imece1996-1023

Saad A. W. Jawad

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引用次数: 7

Abstract

A proposal for collision mitigation is investigated in this paper. Two intelligently controlled hvdraulic cylinders is proposed to be extended prior to collision and absorb impact energy upon engagement with the other body. Feasibility and performance of collision mitigation were investigated with a simulation of the collision dynamics. Two phases of control were considered; pre-collision control and collision control. Various collision scenarios have been studied with view of predicting collision and proposing a pre-collision control strategy for activating the proposed hydraulic bumper. A learning digital computer pre-collision control is proposed. For the purpose of this research a 0.5 m stroke hydraulic cylinders is used to act as an effective extension of the crash zone. A specially adapted fast response hydraulic flow control valve is proposed with certain collision control law. The collision control law aims at controlling the collision force at a given level corresponding to occupants acceleration not exceeding 20g. Simulation results revealed a maximum level of 15g deceleration could be achieved in a 30 mph collision.

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用于正面碰撞缓解的智能液压保险杠

本文研究了一种碰撞缓解方案。提出了两个智能控制的液压缸在碰撞前展开，并在与另一个物体接触时吸收冲击能量。通过碰撞动力学仿真研究了碰撞缓解的可行性和性能。考虑了两个控制阶段;碰撞前控制和碰撞控制。研究了各种碰撞情况，以期预测碰撞，并提出了一种激活所提出的液压保险杠的碰撞前控制策略。提出了一种可学习的数字计算机预碰撞控制方法。为了本研究的目的，使用了0.5 m行程的液压缸作为碰撞区域的有效扩展。提出了一种特殊适应的具有一定碰撞控制规律的快速响应液压流量控制阀。碰撞控制律的目的是在乘员加速度不超过20g的情况下，将碰撞力控制在给定水平。模拟结果显示，在时速30英里的碰撞中，最大减速可达到15g。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Crashworthiness and Occupant Protection in Transportation Systems

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