Philipps Joseph C, Gahl John M, Salim Hani A, Brockman John D, Newberry Michael C
Department of Civil and Environmental Engineering, University of Missouri, Columbia, MO 65211, USA.
Department of Electrical Engineering and Computer Science, MU Research Reactor, University of Missouri, Columbia, MO 65211, USA.
Polymers (Basel). 2023 Mar 28;15(7):1672. doi: 10.3390/polym15071672.
Polymer interlayer materials are utilized in laminated glass systems to provide increased resilience from blast incidents. The polymer chains within the interlayer material can benefit from material modifications that increase the crosslinking between adjacent chains. One theorized method of targeted crosslinking is made possible through a boron neutron capture process. This process utilizes neutron radiation that bombards boron material, thus producing emissions of highly energetic particles into the polymer. The method has been experimentally utilized for bulk material processing as well as surface treatment. The surface treatment process has been extensively investigated in this study to manipulate polymers commonly used as interlayer material. Comparison evaluation tests have been completed to show the material behavior change through static tensile loading, dynamic tensile loading, indentation testing, and scratch resistance testing. Results present the specific material behavior changes, effects on different interlayer material, and optimizations for the treatment processes. Data resulting from these tests will expand the understanding of the material behavior changes from treatment techniques and show evidence of the expected crosslinking. This understanding will lead to a quantifiable application of system capacities to improve the future designs of the window and building systems and lead to a safer, more secure, and resilient infrastructure. Polymer treatment by boron neutron capture radiation has produced polymer interlayers with the potential of increased resilience to blast. The research to date has evaluated treated polymers and shown that the hardening and increased elasticity of the material can be initiated through treatment, thus indicating crosslinking behavior. These results show distinct changes in the material behavior, particularly with the EVA interlayer material. The harder surface of the interlayer may resist the cutting of the interlayer surface by glass shards. Scratch resistance was 30% higher and the measured hardness was 100% on treated surfaces. Treated EVA exhibited a 40% higher stress capacity, a 35% higher toughness, and a 40% increase in the elasticity of the material. The overall toughness increase of the treated polymer material allows for a higher energy absorption, and an overall improvement of window performance in blast conditions. The treatment technique can be applied to a variety of window interlayer products for optimal material performance in blast conditions.
聚合物夹层材料用于夹层玻璃系统,以提高在爆炸事件中的恢复能力。夹层材料中的聚合物链可受益于增加相邻链之间交联的材料改性。一种理论上的靶向交联方法可通过硼中子俘获过程实现。该过程利用中子辐射轰击硼材料,从而向聚合物中发射高能粒子。该方法已在实验中用于块状材料加工以及表面处理。本研究对表面处理过程进行了广泛研究,以处理常用作夹层材料的聚合物。已完成比较评估测试,以显示通过静态拉伸加载、动态拉伸加载、压痕测试和耐刮性测试引起的材料行为变化。结果呈现了特定的材料行为变化、对不同夹层材料的影响以及处理过程的优化。这些测试产生的数据将扩展对处理技术引起的材料行为变化的理解,并显示预期交联的证据。这种理解将导致系统能力的可量化应用,以改进窗户和建筑系统的未来设计,并带来更安全、更可靠和更具恢复能力的基础设施。通过硼中子俘获辐射对聚合物进行处理,已生产出具有增强抗爆恢复能力潜力的聚合物夹层。迄今为止的研究评估了处理后的聚合物,并表明通过处理可引发材料的硬化和弹性增加,从而表明存在交联行为。这些结果表明材料行为发生了明显变化,特别是对于EVA夹层材料。夹层较硬的表面可能会抵抗玻璃碎片对夹层表面的切割。处理后的表面耐刮性提高了30%,测得的硬度提高了100%。处理后的EVA应力能力提高了40%,韧性提高了35%,材料弹性提高了40%。处理后的聚合物材料整体韧性增加,使其能够吸收更高的能量,并在爆炸条件下全面改善窗户性能。该处理技术可应用于各种窗户夹层产品,以在爆炸条件下实现最佳材料性能。
