Joint Department of Biomedical Engineering, Marquette University and Medical College of Wisconsin, Milwaukee, WI 53223, USA.
Department of Neurosurgery, Medical College of Wisconsin, Milwaukee, WI 53226, USA.
Mil Med. 2024 Aug 19;189(Suppl 3):517-524. doi: 10.1093/milmed/usae173.
With similar prevalence to injuries from fires, stings, and natural disasters, soft tissue injuries may occur from fireworks, industrial accidents, or other explosives. Surgeons are less familiar with treating high-velocity penetration from small debris, which may increase the chance of infection and subsequent fatality. Penetration risk curves have been developed to predict V50, the velocity with 50% probability of penetration, for various sized projectiles. However, there has been limited research using nonmetallic materials to achieve lower density projectiles less than 1 g cm-2, such as sand or rocks.
To emulate the size and density of these energized particles, 14 ball bearings of stainless steel, silicon nitride, or Delrin acetal plastic ranging from 1.59 mm (1/16") to 9.53 mm (3/8") with sectional densities between 0.3 g cm-2 and 5 g cm-2 were launched toward porcine legs at a range of velocities to determine the penetration thresholds. High-speed videography was captured laterally at 40 kHz and impact velocity was captured using a physics-based tracking software. A generalized linear model with repeated measures and a logit link function was used to predict probability of penetration for each projectile. A total of 600 impacts were conducted to achieve at least 15 penetrating impacts for each projectile over a range of velocities.
Higher impact velocities were required to penetrate the skin as sectional density of the projectile decreased, and the relationship between velocity and sectional density exhibited an exponential relationship (V50, $ = 184.6*S{D^{ - 0.385}}$, R2 = 0.95) with substantial change for nonlinearity in sectional densities ranging from 0.3 g cm-2 to 1 g cm-2. Compared to previous studies, the empirical relationship was consistent in the linear region (2-5 g cm-2), and novel experimentation filled in the gaps for sectional densities less than 1 g cm-2, which expressed more nonlinearity than previously estimated. For low-density projectiles with diameters of 1.59 (1/16") or 3.18 (1/8"), 32 impacts were lodged into the epidermis but did not penetrate through the dermis; however, penetration was defined as displacement into or through the dermis.
These experimental results may be used to develop and validate finite element simulations of low-density projectile impacts to address complex, multivariate loading conditions for the development of protective clothing to reduce wounding and subsequent infection rates.
与火灾、刺伤和自然灾害造成的伤害发生率相似,软组织损伤也可能由烟花、工业事故或其他爆炸物引起。外科医生对高速穿透小碎片造成的损伤不太熟悉,这可能会增加感染和随后死亡的几率。已经开发出穿透风险曲线来预测各种大小弹丸的 V50,即 50%穿透概率的速度。然而,使用非金属材料来实现密度小于 1g/cm2 的低密度弹丸,如沙子或岩石,进行研究的次数有限。
为了模拟这些带电粒子的大小和密度,使用了 14 个不锈钢、氮化硅或 Delrin 乙缩醛塑料制成的滚珠轴承,直径从 1.59mm(1/16")到 9.53mm(3/8")不等,截面积密度在 0.3g/cm2 到 5g/cm2 之间,以不同的速度发射到猪腿上,以确定穿透阈值。使用基于物理的跟踪软件在 40kHz 时从侧面捕获高速录像,并捕获冲击速度。使用具有重复测量和对数链接函数的广义线性模型来预测每个弹丸的穿透概率。对于每种弹丸,在不同的速度范围内进行了总共 600 次冲击,以实现至少 15 次穿透冲击。
随着弹丸截面积密度的降低,穿透皮肤所需的冲击速度更高,速度与截面积密度之间的关系呈指数关系(V50,$=184.6*S{D^{-0.385}}$,R2=0.95),截面积密度在 0.3g/cm2 到 1g/cm2 之间表现出明显的非线性变化。与以前的研究相比,经验关系在线性区域(2-5g/cm2)是一致的,而新的实验填补了截面积密度小于 1g/cm2 的空白,这比以前估计的表现出更多的非线性。对于直径为 1.59(1/16")或 3.18(1/8")的低密度弹丸,32 个弹丸被嵌入表皮但未穿透真皮;然而,穿透被定义为进入或穿过真皮的位移。
这些实验结果可用于开发和验证低密度弹丸冲击的有限元模拟,以解决复杂的、多变量加载条件,为开发减少创伤和随后感染率的防护服提供依据。
