Your search keyword '"Load-bearing"' showing total 3 results

1. 陶瓷混杂点阵夹芯超结构的承载与抗多点侵彻性能.

Author

郑冰倩, 强鹭升, 宋萧彤, 倪长也, and 张 瑞

Subjects

*MILITARY supplies, *BRITTLE fractures, *DEFENSIVE (Military science), *HONEYCOMB structures, *DEBONDING

Abstract

Lightweight, load-bearing, and penetration-resistant integrated meta-structures have significant potential in military equipment and defense facilities, as they can effectively reduce weight and improve space utilization compared to traditional load-bearing structures and armors. Based on hybrid sandwich meta-structures the load-deflection curves of the meta-structure and the traditional corrugated sandwich under 3-point bending loads were compared. The protective performance and energy absorption mechanism of the meta-structure under multiple ballistic impacts were experimentally studied. The research results indicate that, the hybrid sandwich meta-structure mainly experiences brittle fracture of ceramic, plastic fracture of face-sheets, and debonding of the adhesive layer under bending loads. Its load-bearing capacity is higher than those of traditional corтиgated sandwiches. Furthermore, the study also reveals that the impact location and the lattice core type influence the multi-impact resistance of the meta-structure, with the honeycomb core demonstrating superior multi impact resistance compared to the corrugated core. The corrugated sandwich lacks longitudinal constraints on the ceramic, while the honeycomb core provides stronger constraints on the ceramic, limiting the area of ceramic damage. As a result, the penetration-resistant performance remains relatively consistent as the number of impacts increases. [ABSTRACT FROM AUTHOR]

Published

2024

2. Tribological properties of zwitterionic-anionic dual-crosslinked P(AAm-co-AAc-co-SBMA-co-AMPS)/Fe3+ hydrogel

Author

LI Ziheng, WANG Binbin, YOU Deqiang, LI Wei, and WANG Xiaojian

Subjects

hydrogel, lubrication, load-bearing, friction, cartilage repair, Materials of engineering and construction. Mechanics of materials, TA401-492

Abstract

Hydrogel is an ideal material for cartilage repair, but it is difficult for artificial materials to achieve ultra-low friction coefficient of cartilage at present. The amphoteric ion anionic double crosslinked P(AAm-co-AAc-co-SBMA-co-AMPS)/Fe3+hydrogel was synthesized by using the amphoteric monomer [2-(methacryloxy) ethyl] dimethyl-(3-sulfopropyl)(SBMA) and the anionic monomer 2-acrylamido-2-methylpropane sulfonic acid (AMPS). The frictional tests were conducted in water and PBS to evaluate the effects of zwitterionic and anionic groups on the coefficient of friction (CoF). The results show that the physical crosslinking point introduced by SBMA and AMPS can improve the compressive strength of hydrogel, and achieve a low CoF (0.04) in water, In addition, it is observed that CoF further decreases to 0.015 in PBS, and the decrease of CoF is caused by the highly hydrated upper layer of hydrogel produced during PBS soaking.

Published

2024

3. 两性离子-阴离子双交联P（AAm-co-AAc-co-SBMA-co-AMPS）/Fe3+水凝胶的摩擦学性能研究.

Author

李子恒, 王斌斌, 尤德强, 李 卫, and 王小健

Abstract

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Published

2024