The objective of the present study is to evaluate a development of the conventional seat belt, offering improved control of anti-submarining and chest loads especially for smaller occupants. The seat belt continues to be the prime safety system fitted to automobiles. Crash injury data indicates that performance improvements continue to be required, particularly in the rear seat and with smaller occupants in the areas of anti-submarining, adaptation to smaller occupants (such as children making the transition from using child restraints) and chest loads. World interest in simple low cost, lightweight vehicles for use in developing countries is emphasising this need. The new belt system, the Lifebelt, retains similar belt geometry to current seat belt systems but with an extension of the seat belt webbing in a continuous loop around the upper thighs. It makes use of many available belt system components, and has the potential to allow a simple lightweight seat belt system with acceptable performance, without some of the complex add on systems now being used. The evaluation began with static fit trials and then used dynamic sled testing under frontal crash test conditions similar to regulatory crash tests (50 km/h and 30g pulse). A number of sled tests (n=20) were carried out in front and rear seat configurations and with different seat structures reflecting current production as well as simplified seating. The new system was compared to conventional belt systems in typical seats and belt geometries. HIII 50M and HIII 5F dummies were used to assess the effect of occupant size, with the small female having the greater tendency to submarine. Anti-submarining effectiveness was assessed from video and with belt motion monitored by iliac spine force transducers, as used for Japan NCAP testing. The enhanced system retains similar belt geometry and occupant use to current belt systems, with some changes to the seat structure for installation. The new belt with the extra continuous lap loop was shown to give a high level of anti-submarining performance while at the same time retaining good occupant kinetics and keeping the chest loads within acceptable limits. The system is able to reduce the need for add on components (such as the in seat anti-submarining ramp and pretensioners), which are required to give current, conventional seat belts acceptable performance.
展开▼
机译:本研究的目的是评估传统安全带的开发,提供改善对抗潜艇和胸部载荷的控制,特别是对于较小的乘员。安全带继续成为适合汽车的主要安全系统。崩溃损伤数据表明,效果改进仍然需要,特别是在后排座位和较小的占用者中,在防潜艇的区域内,适应较小的居住者(例如,儿童从使用儿童束缚时转变)和胸部负荷。世界兴趣在简单的低成本中,发展中国家使用的轻量级车辆正在强调这种需求。新的皮带系统,救生带,保留了类似的带几何形状到当前的安全带系统,而是在围绕大腿上部的连续环中延伸安全带织带。它利用了许多可用的皮带系统部件,并且有可能允许具有可接受的性能的简单的轻质安全带系统,而现在正在使用的系统中的一些复杂的添加。评估开始静态拟合试验,然后在正面碰撞试验条件下使用动态SLED测试,类似于调节碰撞试验(50 km / h和30g脉冲)。在前座和后座配置中进行许多滑雪检测(n = 20),并用不同的座椅结构反射电流生产以及简化的座位。将新系统与典型座椅和带几何形状中的传统皮带系统进行比较。 HIII 50M和HIII 5F假人用于评估乘员尺寸的效果,小女性具有潜艇倾向的小女性。从视频和带有髂脊柱力传感器监测的皮带运动,用于日本NCAP测试的腰带运动评估反潜艇的效果。增强系统保留了类似的带几何形状和乘员用途,对当前的皮带系统,有一些改变到安装座椅结构。具有额外连续膝盖环的新带,显示出高水平的防潜艇性能,同时保持良好的乘员动力学并保持胸部载荷在可接受的限度内。该系统能够减少对组件(如座椅防潜艇斜坡和预置旋转器)的需求,这需要提供电流,传统的座带可接受的性能。
展开▼
