Experimental and numerical investigations of factors influencing bone fracture tolerance

影响骨折耐受性因素的实验和数值研究

• 批准号: 402099-2013
• 负责人: Quenneville, Cheryl
• 金额: $ 1.75万
• 依托单位: McMaster University
• 依托单位国家: 加拿大
• 项目类别: Discovery Grants Program - Individual
• 财政年份: 2019
• 资助国家: 加拿大
• 起止时间: 2019-01-01 至 2020-12-31
• 项目状态: 已结题
• 来源: https://www.nserc-crsng.gc.ca/ase-oro/Details-Detailles_eng.asp?id=679717
• 关键词: Experimental; numerical; investigations; factors; influencing

This research is concerned with the development of comprehensive injury criteria and injury-predicting finite element (FE) models, with a focus on the lower leg. Injury criteria are used by a variety of industries (e.g., automotive, defence) to evaluate protective systems, but have historically been oversimplified. Furthermore, computer models are commonly used to evaluate fracture risk, but little work has been done to ensure that bone is properly modeled. Lower leg injuries are frequent in accidents and can have significant long-term effects on quality of life. As such, there is a need for improved injury criteria and enhanced numerical models to better understand these injuries and assess the potential of novel protective technologies.The effect of loading rate and lower leg posture are two significant factors that will influence injury risk, but have yet to be investigated. Through experimental testing of cadaveric specimens new injury criteria will be developed that include the effect of load duration, leg angle and ankle position. This will permit more appropriate evaluation of devices such as footrests and energy attenuating materials for their protective capabilities. Corresponding loads measured by 'crash test dummies' will be determined, thus providing guidelines to industry for safety assessments. As well, an instrumented boot will be developed to provide a means to evaluate injury risk to the foot/ankle, a region not yet instrumented. Studies will be conducted to determine the optimal parameters needed to model bone for injury predicting computer studies, and a numerical model of the lower leg will be developed and validated against the aforementioned test data.The factors which influence injury risk are not well understood. By further developing the injury criteria used to evaluate safety measures, the prevalence of debilitating traumatic injuries can be reduced. This will result in a better protected population and reduced long term effects for those involved in traumatic events.

本研究关注的是全面的损伤标准和损伤预测有限元（FE）模型的发展，重点是小腿。 各种行业都使用伤害标准（例如，汽车，国防）来评估保护系统，但在历史上被过于简化。 此外，计算机模型通常用于评估骨折风险，但几乎没有做任何工作来确保骨骼正确建模。 小腿受伤是常见的事故，并可能对生活质量产生重大的长期影响。 因此，有必要改进伤害标准和增强的数值模型，以更好地了解这些伤害和评估新的防护技术的潜力。负荷率和小腿姿势的影响是两个重要的因素，将影响伤害风险，但尚未被调查。 通过对尸体标本的实验测试，将制定新的损伤标准，包括载荷持续时间，腿部角度和踝关节位置的影响。 这将允许更适当地评估诸如脚踏板和能量衰减材料等装置的保护能力。 将确定由“碰撞试验假人”测量的相应载荷，从而为工业安全评估提供指导。 此外，还将开发一种内固定靴子，以提供一种方法来评估足部/踝关节（尚未内固定的区域）的损伤风险。 将进行研究，以确定受伤预测计算机研究所需的骨骼模型的最佳参数，并将开发小腿的数值模型，并根据上述测试数据进行验证。 通过进一步制定用于评估安全措施的伤害标准，可以减少使人衰弱的创伤性伤害的发生率。 这将导致更好地保护人口，并减少对那些参与创伤事件的长期影响。