Experimental characterization of artificial turf infill mixtures and implementation in smoothed particle hydrodynamics numerical model

B. Watson, M. Bustamante, Aleksander Rycman, Matheus A Correia, D. Cronin
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引用次数: 1

Abstract

Quantifying the response of infill used to construct contemporary artificial turf is critical to the development of computational models and providing insights to reduce sports injury associated with artificial turf. In the current study, confined compression and direct shear tests were performed on typical infill materials (sand, SBR and two mixtures (33%: 67%) by-weight). The experimental tests exhibited a progression from high strength and stiffness (sand) to low strength and stiffness (SBR) with the mixtures having intermediate values. Increasing particle size, particularly sand, tended to increase the resistance of the infill to deformation. The experimental results were implemented into a soil constitutive material model and the experimental tests were simulated using a smoothed particle hydrodynamics (SPH) method to verify the implementation in a commercial explicit finite element solver. The SPH method successfully captured the initial loading up to yield, material flow and post-yield behavior, enabling large-scale particle flow that will be necessary to simulate artificial turf. The simulation results predicted the test force-displacement response well for SBR and mixture infills. The proposed methodology demonstrated the ability to measure properties of contemporary artificial turf infills in both compression and shear for pure sand, pure SBR and mixtures of the two, and use these properties to accurately represent the infill in a computational environment. The resulting model can be extended to large-scale turf models, to investigate athlete performance and injury risk when interacting with artificial turf.
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人造草皮填充混合物的实验表征及其在光滑颗粒流体力学数值模型中的实现
量化用于构建现代人造草坪的填充物的响应对于开发计算模型以及为减少与人造草坪相关的运动损伤提供见解至关重要。在目前的研究中,对典型的填充材料(砂、SBR和两种混合物(33%:67%)进行了侧限压缩和直剪试验。试验结果表明,混合料的强度和刚度从高强度和刚度(砂土)到低强度和刚度(SBR)的变化趋势为中间值。增大颗粒尺寸,特别是砂土,倾向于增加填充物的抗变形能力。将实验结果应用于土壤本构材料模型,并采用光滑颗粒流体力学(SPH)方法对实验结果进行了模拟,以验证在商业显式有限元求解器中的实现。SPH方法成功捕获了初始载荷、屈服、材料流动和屈服后的行为,实现了模拟人造草坪所需的大规模颗粒流动。模拟结果较好地预测了SBR和混合充填体的试验力-位移响应。所提出的方法证明了测量现代人造草坪填充物在纯砂、纯SBR和两者混合物的压缩和剪切特性的能力,并使用这些特性在计算环境中准确地表示填充物。所得到的模型可以扩展到大规模的草皮模型,以研究运动员在与人造草皮相互作用时的表现和受伤风险。
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来源期刊
CiteScore
3.50
自引率
20.00%
发文量
51
审稿时长
>12 weeks
期刊介绍: The Journal of Sports Engineering and Technology covers the development of novel sports apparel, footwear, and equipment; and the materials, instrumentation, and processes that make advances in sports possible.
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